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ISOSTATIC PRESSING

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ISOSTATIC PRESSING. ISOSTATIC PRESSING. COLD ISOSTATIC PRESSING (CIP) is a materials processing technique in which high pressure is applied to metal powder in a sealed elastomer container shaped for the application. - PowerPoint PPT Presentation

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Page 1: ISOSTATIC PRESSING

ISOSTATIC PRESSING

ISOSTATIC PRESSINGbull COLD ISOSTATIC PRESSING (CIP) is a materials processing

technique in which high pressure is applied to metal powder in a sealed elastomer container shaped for the application

bull The powder is converted from a loose aggregate into a partially dense compact that has sufficient green strength to permit careful handling and transfer to the following process operation

bull Compacting pressures range from 207 to 414 MPa (30 to 60 ksi) although pressures as high as 758 MPa (110 ksi) have been used

bull Compaction is performed at ambient temperature bull The density of the loose powder poured into the elastomer mold is

increased from 55 to 65 of theoretical a nominal range for uncompacted powder to 75 to 85 of the 100 theoretical density value of the metal being processed

ISOSTATIC PRESSING

bull The metal powder is compacted uniformly in all directions so that the compact becomes an accurate scale down of the mould------- uniform density ------- a homogeneous microstructure

bull For this purpose the powder is sealed in a flexible envelope and the assembly (mould-powder) is immersed in a fluid which is pressurized

bull There are virtually no residual stresses in the compacted material because there is no die wall friction

Why Isostatic Pressing

To get uniform density and compaction

To make intricate shapes

To get objects with great dimensional tolerance

To get homogeneous structure

Figure1 shows the use of formers and use of

containers with holes for support purposes

Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing

Process CharacteristicsUnique aspects of CIP as compared to die compaction for PM parts include

bull Hydrostatic application of pressure over all surfaces of the mold produces uniform powder density for simple and complicated shapes

bull Die-wall friction is not a factor in the densification process because of the elastic behavior of the mold

bull Organic binder or lubricant additions to the metal powders are not required to achieve useful green strength In fact these materials are detrimental because of the adverse influence on metal chemistry and related mechanical properties for many of the reactive metals commonly processed by CIP if all these materials were present

bull Shapes with high ratios (greater than 10) of length to characteristic diameter can be densified and handled

bull Parts with reentrant and three-dimensional curved geometries can be made

bull Elastomer tooling can be combined with metal tooling inserts to exactly control certain part dimensions such as cylinder bores or outside diameters

bull Thin-walled sections and parts can be pressed

bull Elastomer tooling costs are low

Recognized limitations of the process includebull Dimensional control is generally less precise than

with metal die compaction because of the absence of exactly dimensioned reference surfaces and variability of the local poured powder density within the mold

bull Surface finish of cold isostatically pressed parts is rough compared to die-compacted parts except for areas in contact with hard tool inserts in hybrid molds

bull Production rates are low compared to metal die compaction

bull Elastomer molds have a relatively short life because of abrasive wear

bull Leakage of a mold in the CIP vessel due to mold tearing or poor closure and sealing practice results in loss of material due to contamination by the working fluid

bull With reactive fine powders such as aluminum in large molds water leakage into the mold can produce a hazardous exothermic reaction

bull Figure Complex cold isostatically pressed PM part made using internal round and square hard-tooling inserts

Two types of processes

i) Cold Isostatic Pressing

ii) Hot Isostatic Pressing

Cold Isostaic Process ----- two methods are used

(a) free mould or wet bag process is suited for

(i) batch scale production

(ii) the mold is filled and sealed outside the pressure vessel

(iii) After the mold is introduced in to the pressure vessel it is completely immersed in the pressure medium usually water containing lubricating and corrosion-preventive additives

(iv) complex parts

(v) research and prototype work

(vi) several moulds in one run-even with differing shape ie parts of different sizes and shapes that require the same process parameters can be pressed in the same cycle

a) Powder fill by weight or volume b) Filling of the mould from the top

c) Top lid put on the mould container

d) Mould is placed inside the pressure vessel

e) Top lid put on the pressure vessel after necessary evacuation and filling with the pressurizing medium

f) Top lid removed after required isostatic compaction for removal of the mould

(b) fixed mould or dry bag process (Figure 3) which is characterized by

(i) envelope is permanently fixed into the pressure vessel

(ii) After the elastomeric mold is filled with powder pressure is applied by introducing pressurized oil between the fixed mold and the vessel wall

(iii) only one compact at a time is used

(iv) more simple shapes are made and

(v) more suited for mass production and faster production rates

Fig3 Schematic of equipment for dry-bag isostatic pressing

Pressure Generators

bull Pressure is generated in the pressure medium through the use of air-driven and hydraulically driven pumps and pressure intensifiers bull The pressure medium typically is oil for dry bag processes water containing additives (water-soluble oil or rust inhibitors) is used for wet bag processes A filtering system should be included with all systems to protect the pressure-generating equipment from particulate contamination

bullDepressurization Systems Depressurization can be accomplished with a single metering valve

Tooling for Isostatic Compacting

Cold isostatic pressing tooling is composed of two partsmdashthe elastomeric mold or bag and a mandrel

Elastomeric molds are made of a variety of materials some are flexible while others are fairly rigid

An outside fixture to hold the loaded form is required if the mold is exceptionally flexible

A number of factors must be considered in the selection of a mold material

Primarily the mold material must not interact with either the powder or the pressure medium

Materials have a range of durabilities Depending on the size of the production run and the

abrasiveness of the powder a material with the appropriate wear resistance should be selected

Mold materials used include natural rubber neoprene urethane polyvinyl chloride butyl nitrile and silicone

(A)suggestions for mould are

(1) Disposable and reusable mould materials are recommended

Disposable mould materials are polystyrene- polyethylene which provide thin wall envelopes and prevent breakage of the given compact but the mould becomes expensive

Reusable materials are urethane silicone rubber neoprene natural rubber and provide (a) greater wall thickness of the envelope (b) good shape control but complex parts may break upon pressure release

(2) The mould material must be sufficiently flexible (high elastic deformation) with low permanent set to accommodate the volume changes during compaction

(3) It must have a sufficient hardness and high resistance to abrasive wear High hardness also means no penetration of the material between powder particles and hence a good surface finish of the compacted part But in case of too high a hardness compressibility is poor and intricate shapes are difficult to fabricate A hardness between 65 and 95 shore A is used depending on the powder material and part shape

(4) Flexible thin walled envelopes may deform when filled with powder and support must be provided to control the compact shape eg container with holes is used or use of fasteners is made Fig 1

(5) Auxiliary tooling elements are

(a) a vacuum fan behind the support to pull the elastic mould exactly in place during filling For mixed mould processing the same action can be carried out by a reversed pumping action on the pressure medium

(b) a vacuum fan as reversed pumping can also be used to open up the mould for stripping compacted parts

(c) a vacuum connection to the filled area to de-air the filled mould before the compacting operation

(d) sealing support and clamping elements are also used

If internal shapes or cavities are desired in the compacted part a rigid mandrel can be used in the tooling

The mandrel usually is made of hardenable steel It should have a very smooth surface finish to encourage part release Complex shapes with reasonable tolerances can be achieved with the use of a mandrel

B) Suggestions for Equipment are as under1) Direct and indirect compression devices are used2) Pressure vessel material recommended is forged

medium carbon steel alloyed and heat treated3) Pressure vessels which have cover plates both on

top and on the bottom of the mould may be used so that the powder can be introduced at the top and the compact ejected at the bottom

4) Specialized equipment - the ROTOPRESS - 10 to 15 pieces per minute production units presently are being designed with 150 cm dia and maximum pressure 2000-3000 atmospheres or 60 cm dia and maximum pressure 10000 - 25000 atmospheres

5) Through the use of automated equipment it is possible to achieve

(a) careful processing (including particle size control)

(b) avoid contamination of the powders

(c) maintain uniform temperature of the pressurizing liquid and of the powders

(d) control of humidity of powders pressure and compacting time and

(e) ultimate excellent dimensional control

Applications of Cold Isostatic Compaction These include

(i) Titanium eg hydraulic aircraft fittings using Ti powder and Al-V master alloy powder

(ii) High-speed tool steels (eg cutting tools)

(iii) Compacts with interior threads

(iv) Long hollow cylindrical filters (stainless steel and titanium powder)

(v) Large shapes from tungsten powder such as rocket nozzle

(vi) Tungsten and molybdenum blooms or slabs for further forging andor rolling

Cross-section of Molding Bag

Body Armor

Bag and Molding Core Pin

Bag and Pressing Mandrel

A Sample of Bags

Cross-section of Bag

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
  • Slide 3
  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
  • Slide 6
  • Slide 7
  • Slide 8
  • Slide 9
  • Slide 10
  • Slide 11
  • Slide 12
  • Slide 13
  • a) Powder fill by weight or volume b) Filling of the mould from the top
  • Slide 15
  • Slide 16
  • Slide 17
  • Slide 18
  • Slide 19
  • Slide 20
  • Slide 21
  • Slide 22
  • Slide 23
  • Slide 24
  • Slide 25
  • Slide 26
  • Slide 27
  • Slide 28
  • Slide 29
  • Slide 30
  • Slide 31
  • Slide 32
  • Slide 33
  • Slide 34
  • Slide 35
  • Slide 36
  • Slide 37
  • Tubes Made by Isostatic Pressing 1048698Isopressing Mold and Mandrel
  • Slide 39
Page 2: ISOSTATIC PRESSING

ISOSTATIC PRESSINGbull COLD ISOSTATIC PRESSING (CIP) is a materials processing

technique in which high pressure is applied to metal powder in a sealed elastomer container shaped for the application

bull The powder is converted from a loose aggregate into a partially dense compact that has sufficient green strength to permit careful handling and transfer to the following process operation

bull Compacting pressures range from 207 to 414 MPa (30 to 60 ksi) although pressures as high as 758 MPa (110 ksi) have been used

bull Compaction is performed at ambient temperature bull The density of the loose powder poured into the elastomer mold is

increased from 55 to 65 of theoretical a nominal range for uncompacted powder to 75 to 85 of the 100 theoretical density value of the metal being processed

ISOSTATIC PRESSING

bull The metal powder is compacted uniformly in all directions so that the compact becomes an accurate scale down of the mould------- uniform density ------- a homogeneous microstructure

bull For this purpose the powder is sealed in a flexible envelope and the assembly (mould-powder) is immersed in a fluid which is pressurized

bull There are virtually no residual stresses in the compacted material because there is no die wall friction

Why Isostatic Pressing

To get uniform density and compaction

To make intricate shapes

To get objects with great dimensional tolerance

To get homogeneous structure

Figure1 shows the use of formers and use of

containers with holes for support purposes

Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing

Process CharacteristicsUnique aspects of CIP as compared to die compaction for PM parts include

bull Hydrostatic application of pressure over all surfaces of the mold produces uniform powder density for simple and complicated shapes

bull Die-wall friction is not a factor in the densification process because of the elastic behavior of the mold

bull Organic binder or lubricant additions to the metal powders are not required to achieve useful green strength In fact these materials are detrimental because of the adverse influence on metal chemistry and related mechanical properties for many of the reactive metals commonly processed by CIP if all these materials were present

bull Shapes with high ratios (greater than 10) of length to characteristic diameter can be densified and handled

bull Parts with reentrant and three-dimensional curved geometries can be made

bull Elastomer tooling can be combined with metal tooling inserts to exactly control certain part dimensions such as cylinder bores or outside diameters

bull Thin-walled sections and parts can be pressed

bull Elastomer tooling costs are low

Recognized limitations of the process includebull Dimensional control is generally less precise than

with metal die compaction because of the absence of exactly dimensioned reference surfaces and variability of the local poured powder density within the mold

bull Surface finish of cold isostatically pressed parts is rough compared to die-compacted parts except for areas in contact with hard tool inserts in hybrid molds

bull Production rates are low compared to metal die compaction

bull Elastomer molds have a relatively short life because of abrasive wear

bull Leakage of a mold in the CIP vessel due to mold tearing or poor closure and sealing practice results in loss of material due to contamination by the working fluid

bull With reactive fine powders such as aluminum in large molds water leakage into the mold can produce a hazardous exothermic reaction

bull Figure Complex cold isostatically pressed PM part made using internal round and square hard-tooling inserts

Two types of processes

i) Cold Isostatic Pressing

ii) Hot Isostatic Pressing

Cold Isostaic Process ----- two methods are used

(a) free mould or wet bag process is suited for

(i) batch scale production

(ii) the mold is filled and sealed outside the pressure vessel

(iii) After the mold is introduced in to the pressure vessel it is completely immersed in the pressure medium usually water containing lubricating and corrosion-preventive additives

(iv) complex parts

(v) research and prototype work

(vi) several moulds in one run-even with differing shape ie parts of different sizes and shapes that require the same process parameters can be pressed in the same cycle

a) Powder fill by weight or volume b) Filling of the mould from the top

c) Top lid put on the mould container

d) Mould is placed inside the pressure vessel

e) Top lid put on the pressure vessel after necessary evacuation and filling with the pressurizing medium

f) Top lid removed after required isostatic compaction for removal of the mould

(b) fixed mould or dry bag process (Figure 3) which is characterized by

(i) envelope is permanently fixed into the pressure vessel

(ii) After the elastomeric mold is filled with powder pressure is applied by introducing pressurized oil between the fixed mold and the vessel wall

(iii) only one compact at a time is used

(iv) more simple shapes are made and

(v) more suited for mass production and faster production rates

Fig3 Schematic of equipment for dry-bag isostatic pressing

Pressure Generators

bull Pressure is generated in the pressure medium through the use of air-driven and hydraulically driven pumps and pressure intensifiers bull The pressure medium typically is oil for dry bag processes water containing additives (water-soluble oil or rust inhibitors) is used for wet bag processes A filtering system should be included with all systems to protect the pressure-generating equipment from particulate contamination

bullDepressurization Systems Depressurization can be accomplished with a single metering valve

Tooling for Isostatic Compacting

Cold isostatic pressing tooling is composed of two partsmdashthe elastomeric mold or bag and a mandrel

Elastomeric molds are made of a variety of materials some are flexible while others are fairly rigid

An outside fixture to hold the loaded form is required if the mold is exceptionally flexible

A number of factors must be considered in the selection of a mold material

Primarily the mold material must not interact with either the powder or the pressure medium

Materials have a range of durabilities Depending on the size of the production run and the

abrasiveness of the powder a material with the appropriate wear resistance should be selected

Mold materials used include natural rubber neoprene urethane polyvinyl chloride butyl nitrile and silicone

(A)suggestions for mould are

(1) Disposable and reusable mould materials are recommended

Disposable mould materials are polystyrene- polyethylene which provide thin wall envelopes and prevent breakage of the given compact but the mould becomes expensive

Reusable materials are urethane silicone rubber neoprene natural rubber and provide (a) greater wall thickness of the envelope (b) good shape control but complex parts may break upon pressure release

(2) The mould material must be sufficiently flexible (high elastic deformation) with low permanent set to accommodate the volume changes during compaction

(3) It must have a sufficient hardness and high resistance to abrasive wear High hardness also means no penetration of the material between powder particles and hence a good surface finish of the compacted part But in case of too high a hardness compressibility is poor and intricate shapes are difficult to fabricate A hardness between 65 and 95 shore A is used depending on the powder material and part shape

(4) Flexible thin walled envelopes may deform when filled with powder and support must be provided to control the compact shape eg container with holes is used or use of fasteners is made Fig 1

(5) Auxiliary tooling elements are

(a) a vacuum fan behind the support to pull the elastic mould exactly in place during filling For mixed mould processing the same action can be carried out by a reversed pumping action on the pressure medium

(b) a vacuum fan as reversed pumping can also be used to open up the mould for stripping compacted parts

(c) a vacuum connection to the filled area to de-air the filled mould before the compacting operation

(d) sealing support and clamping elements are also used

If internal shapes or cavities are desired in the compacted part a rigid mandrel can be used in the tooling

The mandrel usually is made of hardenable steel It should have a very smooth surface finish to encourage part release Complex shapes with reasonable tolerances can be achieved with the use of a mandrel

B) Suggestions for Equipment are as under1) Direct and indirect compression devices are used2) Pressure vessel material recommended is forged

medium carbon steel alloyed and heat treated3) Pressure vessels which have cover plates both on

top and on the bottom of the mould may be used so that the powder can be introduced at the top and the compact ejected at the bottom

4) Specialized equipment - the ROTOPRESS - 10 to 15 pieces per minute production units presently are being designed with 150 cm dia and maximum pressure 2000-3000 atmospheres or 60 cm dia and maximum pressure 10000 - 25000 atmospheres

5) Through the use of automated equipment it is possible to achieve

(a) careful processing (including particle size control)

(b) avoid contamination of the powders

(c) maintain uniform temperature of the pressurizing liquid and of the powders

(d) control of humidity of powders pressure and compacting time and

(e) ultimate excellent dimensional control

Applications of Cold Isostatic Compaction These include

(i) Titanium eg hydraulic aircraft fittings using Ti powder and Al-V master alloy powder

(ii) High-speed tool steels (eg cutting tools)

(iii) Compacts with interior threads

(iv) Long hollow cylindrical filters (stainless steel and titanium powder)

(v) Large shapes from tungsten powder such as rocket nozzle

(vi) Tungsten and molybdenum blooms or slabs for further forging andor rolling

Cross-section of Molding Bag

Body Armor

Bag and Molding Core Pin

Bag and Pressing Mandrel

A Sample of Bags

Cross-section of Bag

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
  • Slide 3
  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
  • Slide 6
  • Slide 7
  • Slide 8
  • Slide 9
  • Slide 10
  • Slide 11
  • Slide 12
  • Slide 13
  • a) Powder fill by weight or volume b) Filling of the mould from the top
  • Slide 15
  • Slide 16
  • Slide 17
  • Slide 18
  • Slide 19
  • Slide 20
  • Slide 21
  • Slide 22
  • Slide 23
  • Slide 24
  • Slide 25
  • Slide 26
  • Slide 27
  • Slide 28
  • Slide 29
  • Slide 30
  • Slide 31
  • Slide 32
  • Slide 33
  • Slide 34
  • Slide 35
  • Slide 36
  • Slide 37
  • Tubes Made by Isostatic Pressing 1048698Isopressing Mold and Mandrel
  • Slide 39
Page 3: ISOSTATIC PRESSING

ISOSTATIC PRESSING

bull The metal powder is compacted uniformly in all directions so that the compact becomes an accurate scale down of the mould------- uniform density ------- a homogeneous microstructure

bull For this purpose the powder is sealed in a flexible envelope and the assembly (mould-powder) is immersed in a fluid which is pressurized

bull There are virtually no residual stresses in the compacted material because there is no die wall friction

Why Isostatic Pressing

To get uniform density and compaction

To make intricate shapes

To get objects with great dimensional tolerance

To get homogeneous structure

Figure1 shows the use of formers and use of

containers with holes for support purposes

Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing

Process CharacteristicsUnique aspects of CIP as compared to die compaction for PM parts include

bull Hydrostatic application of pressure over all surfaces of the mold produces uniform powder density for simple and complicated shapes

bull Die-wall friction is not a factor in the densification process because of the elastic behavior of the mold

bull Organic binder or lubricant additions to the metal powders are not required to achieve useful green strength In fact these materials are detrimental because of the adverse influence on metal chemistry and related mechanical properties for many of the reactive metals commonly processed by CIP if all these materials were present

bull Shapes with high ratios (greater than 10) of length to characteristic diameter can be densified and handled

bull Parts with reentrant and three-dimensional curved geometries can be made

bull Elastomer tooling can be combined with metal tooling inserts to exactly control certain part dimensions such as cylinder bores or outside diameters

bull Thin-walled sections and parts can be pressed

bull Elastomer tooling costs are low

Recognized limitations of the process includebull Dimensional control is generally less precise than

with metal die compaction because of the absence of exactly dimensioned reference surfaces and variability of the local poured powder density within the mold

bull Surface finish of cold isostatically pressed parts is rough compared to die-compacted parts except for areas in contact with hard tool inserts in hybrid molds

bull Production rates are low compared to metal die compaction

bull Elastomer molds have a relatively short life because of abrasive wear

bull Leakage of a mold in the CIP vessel due to mold tearing or poor closure and sealing practice results in loss of material due to contamination by the working fluid

bull With reactive fine powders such as aluminum in large molds water leakage into the mold can produce a hazardous exothermic reaction

bull Figure Complex cold isostatically pressed PM part made using internal round and square hard-tooling inserts

Two types of processes

i) Cold Isostatic Pressing

ii) Hot Isostatic Pressing

Cold Isostaic Process ----- two methods are used

(a) free mould or wet bag process is suited for

(i) batch scale production

(ii) the mold is filled and sealed outside the pressure vessel

(iii) After the mold is introduced in to the pressure vessel it is completely immersed in the pressure medium usually water containing lubricating and corrosion-preventive additives

(iv) complex parts

(v) research and prototype work

(vi) several moulds in one run-even with differing shape ie parts of different sizes and shapes that require the same process parameters can be pressed in the same cycle

a) Powder fill by weight or volume b) Filling of the mould from the top

c) Top lid put on the mould container

d) Mould is placed inside the pressure vessel

e) Top lid put on the pressure vessel after necessary evacuation and filling with the pressurizing medium

f) Top lid removed after required isostatic compaction for removal of the mould

(b) fixed mould or dry bag process (Figure 3) which is characterized by

(i) envelope is permanently fixed into the pressure vessel

(ii) After the elastomeric mold is filled with powder pressure is applied by introducing pressurized oil between the fixed mold and the vessel wall

(iii) only one compact at a time is used

(iv) more simple shapes are made and

(v) more suited for mass production and faster production rates

Fig3 Schematic of equipment for dry-bag isostatic pressing

Pressure Generators

bull Pressure is generated in the pressure medium through the use of air-driven and hydraulically driven pumps and pressure intensifiers bull The pressure medium typically is oil for dry bag processes water containing additives (water-soluble oil or rust inhibitors) is used for wet bag processes A filtering system should be included with all systems to protect the pressure-generating equipment from particulate contamination

bullDepressurization Systems Depressurization can be accomplished with a single metering valve

Tooling for Isostatic Compacting

Cold isostatic pressing tooling is composed of two partsmdashthe elastomeric mold or bag and a mandrel

Elastomeric molds are made of a variety of materials some are flexible while others are fairly rigid

An outside fixture to hold the loaded form is required if the mold is exceptionally flexible

A number of factors must be considered in the selection of a mold material

Primarily the mold material must not interact with either the powder or the pressure medium

Materials have a range of durabilities Depending on the size of the production run and the

abrasiveness of the powder a material with the appropriate wear resistance should be selected

Mold materials used include natural rubber neoprene urethane polyvinyl chloride butyl nitrile and silicone

(A)suggestions for mould are

(1) Disposable and reusable mould materials are recommended

Disposable mould materials are polystyrene- polyethylene which provide thin wall envelopes and prevent breakage of the given compact but the mould becomes expensive

Reusable materials are urethane silicone rubber neoprene natural rubber and provide (a) greater wall thickness of the envelope (b) good shape control but complex parts may break upon pressure release

(2) The mould material must be sufficiently flexible (high elastic deformation) with low permanent set to accommodate the volume changes during compaction

(3) It must have a sufficient hardness and high resistance to abrasive wear High hardness also means no penetration of the material between powder particles and hence a good surface finish of the compacted part But in case of too high a hardness compressibility is poor and intricate shapes are difficult to fabricate A hardness between 65 and 95 shore A is used depending on the powder material and part shape

(4) Flexible thin walled envelopes may deform when filled with powder and support must be provided to control the compact shape eg container with holes is used or use of fasteners is made Fig 1

(5) Auxiliary tooling elements are

(a) a vacuum fan behind the support to pull the elastic mould exactly in place during filling For mixed mould processing the same action can be carried out by a reversed pumping action on the pressure medium

(b) a vacuum fan as reversed pumping can also be used to open up the mould for stripping compacted parts

(c) a vacuum connection to the filled area to de-air the filled mould before the compacting operation

(d) sealing support and clamping elements are also used

If internal shapes or cavities are desired in the compacted part a rigid mandrel can be used in the tooling

The mandrel usually is made of hardenable steel It should have a very smooth surface finish to encourage part release Complex shapes with reasonable tolerances can be achieved with the use of a mandrel

B) Suggestions for Equipment are as under1) Direct and indirect compression devices are used2) Pressure vessel material recommended is forged

medium carbon steel alloyed and heat treated3) Pressure vessels which have cover plates both on

top and on the bottom of the mould may be used so that the powder can be introduced at the top and the compact ejected at the bottom

4) Specialized equipment - the ROTOPRESS - 10 to 15 pieces per minute production units presently are being designed with 150 cm dia and maximum pressure 2000-3000 atmospheres or 60 cm dia and maximum pressure 10000 - 25000 atmospheres

5) Through the use of automated equipment it is possible to achieve

(a) careful processing (including particle size control)

(b) avoid contamination of the powders

(c) maintain uniform temperature of the pressurizing liquid and of the powders

(d) control of humidity of powders pressure and compacting time and

(e) ultimate excellent dimensional control

Applications of Cold Isostatic Compaction These include

(i) Titanium eg hydraulic aircraft fittings using Ti powder and Al-V master alloy powder

(ii) High-speed tool steels (eg cutting tools)

(iii) Compacts with interior threads

(iv) Long hollow cylindrical filters (stainless steel and titanium powder)

(v) Large shapes from tungsten powder such as rocket nozzle

(vi) Tungsten and molybdenum blooms or slabs for further forging andor rolling

Cross-section of Molding Bag

Body Armor

Bag and Molding Core Pin

Bag and Pressing Mandrel

A Sample of Bags

Cross-section of Bag

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
  • Slide 3
  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
  • Slide 6
  • Slide 7
  • Slide 8
  • Slide 9
  • Slide 10
  • Slide 11
  • Slide 12
  • Slide 13
  • a) Powder fill by weight or volume b) Filling of the mould from the top
  • Slide 15
  • Slide 16
  • Slide 17
  • Slide 18
  • Slide 19
  • Slide 20
  • Slide 21
  • Slide 22
  • Slide 23
  • Slide 24
  • Slide 25
  • Slide 26
  • Slide 27
  • Slide 28
  • Slide 29
  • Slide 30
  • Slide 31
  • Slide 32
  • Slide 33
  • Slide 34
  • Slide 35
  • Slide 36
  • Slide 37
  • Tubes Made by Isostatic Pressing 1048698Isopressing Mold and Mandrel
  • Slide 39
Page 4: ISOSTATIC PRESSING

Why Isostatic Pressing

To get uniform density and compaction

To make intricate shapes

To get objects with great dimensional tolerance

To get homogeneous structure

Figure1 shows the use of formers and use of

containers with holes for support purposes

Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing

Process CharacteristicsUnique aspects of CIP as compared to die compaction for PM parts include

bull Hydrostatic application of pressure over all surfaces of the mold produces uniform powder density for simple and complicated shapes

bull Die-wall friction is not a factor in the densification process because of the elastic behavior of the mold

bull Organic binder or lubricant additions to the metal powders are not required to achieve useful green strength In fact these materials are detrimental because of the adverse influence on metal chemistry and related mechanical properties for many of the reactive metals commonly processed by CIP if all these materials were present

bull Shapes with high ratios (greater than 10) of length to characteristic diameter can be densified and handled

bull Parts with reentrant and three-dimensional curved geometries can be made

bull Elastomer tooling can be combined with metal tooling inserts to exactly control certain part dimensions such as cylinder bores or outside diameters

bull Thin-walled sections and parts can be pressed

bull Elastomer tooling costs are low

Recognized limitations of the process includebull Dimensional control is generally less precise than

with metal die compaction because of the absence of exactly dimensioned reference surfaces and variability of the local poured powder density within the mold

bull Surface finish of cold isostatically pressed parts is rough compared to die-compacted parts except for areas in contact with hard tool inserts in hybrid molds

bull Production rates are low compared to metal die compaction

bull Elastomer molds have a relatively short life because of abrasive wear

bull Leakage of a mold in the CIP vessel due to mold tearing or poor closure and sealing practice results in loss of material due to contamination by the working fluid

bull With reactive fine powders such as aluminum in large molds water leakage into the mold can produce a hazardous exothermic reaction

bull Figure Complex cold isostatically pressed PM part made using internal round and square hard-tooling inserts

Two types of processes

i) Cold Isostatic Pressing

ii) Hot Isostatic Pressing

Cold Isostaic Process ----- two methods are used

(a) free mould or wet bag process is suited for

(i) batch scale production

(ii) the mold is filled and sealed outside the pressure vessel

(iii) After the mold is introduced in to the pressure vessel it is completely immersed in the pressure medium usually water containing lubricating and corrosion-preventive additives

(iv) complex parts

(v) research and prototype work

(vi) several moulds in one run-even with differing shape ie parts of different sizes and shapes that require the same process parameters can be pressed in the same cycle

a) Powder fill by weight or volume b) Filling of the mould from the top

c) Top lid put on the mould container

d) Mould is placed inside the pressure vessel

e) Top lid put on the pressure vessel after necessary evacuation and filling with the pressurizing medium

f) Top lid removed after required isostatic compaction for removal of the mould

(b) fixed mould or dry bag process (Figure 3) which is characterized by

(i) envelope is permanently fixed into the pressure vessel

(ii) After the elastomeric mold is filled with powder pressure is applied by introducing pressurized oil between the fixed mold and the vessel wall

(iii) only one compact at a time is used

(iv) more simple shapes are made and

(v) more suited for mass production and faster production rates

Fig3 Schematic of equipment for dry-bag isostatic pressing

Pressure Generators

bull Pressure is generated in the pressure medium through the use of air-driven and hydraulically driven pumps and pressure intensifiers bull The pressure medium typically is oil for dry bag processes water containing additives (water-soluble oil or rust inhibitors) is used for wet bag processes A filtering system should be included with all systems to protect the pressure-generating equipment from particulate contamination

bullDepressurization Systems Depressurization can be accomplished with a single metering valve

Tooling for Isostatic Compacting

Cold isostatic pressing tooling is composed of two partsmdashthe elastomeric mold or bag and a mandrel

Elastomeric molds are made of a variety of materials some are flexible while others are fairly rigid

An outside fixture to hold the loaded form is required if the mold is exceptionally flexible

A number of factors must be considered in the selection of a mold material

Primarily the mold material must not interact with either the powder or the pressure medium

Materials have a range of durabilities Depending on the size of the production run and the

abrasiveness of the powder a material with the appropriate wear resistance should be selected

Mold materials used include natural rubber neoprene urethane polyvinyl chloride butyl nitrile and silicone

(A)suggestions for mould are

(1) Disposable and reusable mould materials are recommended

Disposable mould materials are polystyrene- polyethylene which provide thin wall envelopes and prevent breakage of the given compact but the mould becomes expensive

Reusable materials are urethane silicone rubber neoprene natural rubber and provide (a) greater wall thickness of the envelope (b) good shape control but complex parts may break upon pressure release

(2) The mould material must be sufficiently flexible (high elastic deformation) with low permanent set to accommodate the volume changes during compaction

(3) It must have a sufficient hardness and high resistance to abrasive wear High hardness also means no penetration of the material between powder particles and hence a good surface finish of the compacted part But in case of too high a hardness compressibility is poor and intricate shapes are difficult to fabricate A hardness between 65 and 95 shore A is used depending on the powder material and part shape

(4) Flexible thin walled envelopes may deform when filled with powder and support must be provided to control the compact shape eg container with holes is used or use of fasteners is made Fig 1

(5) Auxiliary tooling elements are

(a) a vacuum fan behind the support to pull the elastic mould exactly in place during filling For mixed mould processing the same action can be carried out by a reversed pumping action on the pressure medium

(b) a vacuum fan as reversed pumping can also be used to open up the mould for stripping compacted parts

(c) a vacuum connection to the filled area to de-air the filled mould before the compacting operation

(d) sealing support and clamping elements are also used

If internal shapes or cavities are desired in the compacted part a rigid mandrel can be used in the tooling

The mandrel usually is made of hardenable steel It should have a very smooth surface finish to encourage part release Complex shapes with reasonable tolerances can be achieved with the use of a mandrel

B) Suggestions for Equipment are as under1) Direct and indirect compression devices are used2) Pressure vessel material recommended is forged

medium carbon steel alloyed and heat treated3) Pressure vessels which have cover plates both on

top and on the bottom of the mould may be used so that the powder can be introduced at the top and the compact ejected at the bottom

4) Specialized equipment - the ROTOPRESS - 10 to 15 pieces per minute production units presently are being designed with 150 cm dia and maximum pressure 2000-3000 atmospheres or 60 cm dia and maximum pressure 10000 - 25000 atmospheres

5) Through the use of automated equipment it is possible to achieve

(a) careful processing (including particle size control)

(b) avoid contamination of the powders

(c) maintain uniform temperature of the pressurizing liquid and of the powders

(d) control of humidity of powders pressure and compacting time and

(e) ultimate excellent dimensional control

Applications of Cold Isostatic Compaction These include

(i) Titanium eg hydraulic aircraft fittings using Ti powder and Al-V master alloy powder

(ii) High-speed tool steels (eg cutting tools)

(iii) Compacts with interior threads

(iv) Long hollow cylindrical filters (stainless steel and titanium powder)

(v) Large shapes from tungsten powder such as rocket nozzle

(vi) Tungsten and molybdenum blooms or slabs for further forging andor rolling

Cross-section of Molding Bag

Body Armor

Bag and Molding Core Pin

Bag and Pressing Mandrel

A Sample of Bags

Cross-section of Bag

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
  • Slide 3
  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
  • Slide 6
  • Slide 7
  • Slide 8
  • Slide 9
  • Slide 10
  • Slide 11
  • Slide 12
  • Slide 13
  • a) Powder fill by weight or volume b) Filling of the mould from the top
  • Slide 15
  • Slide 16
  • Slide 17
  • Slide 18
  • Slide 19
  • Slide 20
  • Slide 21
  • Slide 22
  • Slide 23
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  • Slide 34
  • Slide 35
  • Slide 36
  • Slide 37
  • Tubes Made by Isostatic Pressing 1048698Isopressing Mold and Mandrel
  • Slide 39
Page 5: ISOSTATIC PRESSING

Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing

Process CharacteristicsUnique aspects of CIP as compared to die compaction for PM parts include

bull Hydrostatic application of pressure over all surfaces of the mold produces uniform powder density for simple and complicated shapes

bull Die-wall friction is not a factor in the densification process because of the elastic behavior of the mold

bull Organic binder or lubricant additions to the metal powders are not required to achieve useful green strength In fact these materials are detrimental because of the adverse influence on metal chemistry and related mechanical properties for many of the reactive metals commonly processed by CIP if all these materials were present

bull Shapes with high ratios (greater than 10) of length to characteristic diameter can be densified and handled

bull Parts with reentrant and three-dimensional curved geometries can be made

bull Elastomer tooling can be combined with metal tooling inserts to exactly control certain part dimensions such as cylinder bores or outside diameters

bull Thin-walled sections and parts can be pressed

bull Elastomer tooling costs are low

Recognized limitations of the process includebull Dimensional control is generally less precise than

with metal die compaction because of the absence of exactly dimensioned reference surfaces and variability of the local poured powder density within the mold

bull Surface finish of cold isostatically pressed parts is rough compared to die-compacted parts except for areas in contact with hard tool inserts in hybrid molds

bull Production rates are low compared to metal die compaction

bull Elastomer molds have a relatively short life because of abrasive wear

bull Leakage of a mold in the CIP vessel due to mold tearing or poor closure and sealing practice results in loss of material due to contamination by the working fluid

bull With reactive fine powders such as aluminum in large molds water leakage into the mold can produce a hazardous exothermic reaction

bull Figure Complex cold isostatically pressed PM part made using internal round and square hard-tooling inserts

Two types of processes

i) Cold Isostatic Pressing

ii) Hot Isostatic Pressing

Cold Isostaic Process ----- two methods are used

(a) free mould or wet bag process is suited for

(i) batch scale production

(ii) the mold is filled and sealed outside the pressure vessel

(iii) After the mold is introduced in to the pressure vessel it is completely immersed in the pressure medium usually water containing lubricating and corrosion-preventive additives

(iv) complex parts

(v) research and prototype work

(vi) several moulds in one run-even with differing shape ie parts of different sizes and shapes that require the same process parameters can be pressed in the same cycle

a) Powder fill by weight or volume b) Filling of the mould from the top

c) Top lid put on the mould container

d) Mould is placed inside the pressure vessel

e) Top lid put on the pressure vessel after necessary evacuation and filling with the pressurizing medium

f) Top lid removed after required isostatic compaction for removal of the mould

(b) fixed mould or dry bag process (Figure 3) which is characterized by

(i) envelope is permanently fixed into the pressure vessel

(ii) After the elastomeric mold is filled with powder pressure is applied by introducing pressurized oil between the fixed mold and the vessel wall

(iii) only one compact at a time is used

(iv) more simple shapes are made and

(v) more suited for mass production and faster production rates

Fig3 Schematic of equipment for dry-bag isostatic pressing

Pressure Generators

bull Pressure is generated in the pressure medium through the use of air-driven and hydraulically driven pumps and pressure intensifiers bull The pressure medium typically is oil for dry bag processes water containing additives (water-soluble oil or rust inhibitors) is used for wet bag processes A filtering system should be included with all systems to protect the pressure-generating equipment from particulate contamination

bullDepressurization Systems Depressurization can be accomplished with a single metering valve

Tooling for Isostatic Compacting

Cold isostatic pressing tooling is composed of two partsmdashthe elastomeric mold or bag and a mandrel

Elastomeric molds are made of a variety of materials some are flexible while others are fairly rigid

An outside fixture to hold the loaded form is required if the mold is exceptionally flexible

A number of factors must be considered in the selection of a mold material

Primarily the mold material must not interact with either the powder or the pressure medium

Materials have a range of durabilities Depending on the size of the production run and the

abrasiveness of the powder a material with the appropriate wear resistance should be selected

Mold materials used include natural rubber neoprene urethane polyvinyl chloride butyl nitrile and silicone

(A)suggestions for mould are

(1) Disposable and reusable mould materials are recommended

Disposable mould materials are polystyrene- polyethylene which provide thin wall envelopes and prevent breakage of the given compact but the mould becomes expensive

Reusable materials are urethane silicone rubber neoprene natural rubber and provide (a) greater wall thickness of the envelope (b) good shape control but complex parts may break upon pressure release

(2) The mould material must be sufficiently flexible (high elastic deformation) with low permanent set to accommodate the volume changes during compaction

(3) It must have a sufficient hardness and high resistance to abrasive wear High hardness also means no penetration of the material between powder particles and hence a good surface finish of the compacted part But in case of too high a hardness compressibility is poor and intricate shapes are difficult to fabricate A hardness between 65 and 95 shore A is used depending on the powder material and part shape

(4) Flexible thin walled envelopes may deform when filled with powder and support must be provided to control the compact shape eg container with holes is used or use of fasteners is made Fig 1

(5) Auxiliary tooling elements are

(a) a vacuum fan behind the support to pull the elastic mould exactly in place during filling For mixed mould processing the same action can be carried out by a reversed pumping action on the pressure medium

(b) a vacuum fan as reversed pumping can also be used to open up the mould for stripping compacted parts

(c) a vacuum connection to the filled area to de-air the filled mould before the compacting operation

(d) sealing support and clamping elements are also used

If internal shapes or cavities are desired in the compacted part a rigid mandrel can be used in the tooling

The mandrel usually is made of hardenable steel It should have a very smooth surface finish to encourage part release Complex shapes with reasonable tolerances can be achieved with the use of a mandrel

B) Suggestions for Equipment are as under1) Direct and indirect compression devices are used2) Pressure vessel material recommended is forged

medium carbon steel alloyed and heat treated3) Pressure vessels which have cover plates both on

top and on the bottom of the mould may be used so that the powder can be introduced at the top and the compact ejected at the bottom

4) Specialized equipment - the ROTOPRESS - 10 to 15 pieces per minute production units presently are being designed with 150 cm dia and maximum pressure 2000-3000 atmospheres or 60 cm dia and maximum pressure 10000 - 25000 atmospheres

5) Through the use of automated equipment it is possible to achieve

(a) careful processing (including particle size control)

(b) avoid contamination of the powders

(c) maintain uniform temperature of the pressurizing liquid and of the powders

(d) control of humidity of powders pressure and compacting time and

(e) ultimate excellent dimensional control

Applications of Cold Isostatic Compaction These include

(i) Titanium eg hydraulic aircraft fittings using Ti powder and Al-V master alloy powder

(ii) High-speed tool steels (eg cutting tools)

(iii) Compacts with interior threads

(iv) Long hollow cylindrical filters (stainless steel and titanium powder)

(v) Large shapes from tungsten powder such as rocket nozzle

(vi) Tungsten and molybdenum blooms or slabs for further forging andor rolling

Cross-section of Molding Bag

Body Armor

Bag and Molding Core Pin

Bag and Pressing Mandrel

A Sample of Bags

Cross-section of Bag

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
  • Slide 3
  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
  • Slide 6
  • Slide 7
  • Slide 8
  • Slide 9
  • Slide 10
  • Slide 11
  • Slide 12
  • Slide 13
  • a) Powder fill by weight or volume b) Filling of the mould from the top
  • Slide 15
  • Slide 16
  • Slide 17
  • Slide 18
  • Slide 19
  • Slide 20
  • Slide 21
  • Slide 22
  • Slide 23
  • Slide 24
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  • Slide 31
  • Slide 32
  • Slide 33
  • Slide 34
  • Slide 35
  • Slide 36
  • Slide 37
  • Tubes Made by Isostatic Pressing 1048698Isopressing Mold and Mandrel
  • Slide 39
Page 6: ISOSTATIC PRESSING

Process CharacteristicsUnique aspects of CIP as compared to die compaction for PM parts include

bull Hydrostatic application of pressure over all surfaces of the mold produces uniform powder density for simple and complicated shapes

bull Die-wall friction is not a factor in the densification process because of the elastic behavior of the mold

bull Organic binder or lubricant additions to the metal powders are not required to achieve useful green strength In fact these materials are detrimental because of the adverse influence on metal chemistry and related mechanical properties for many of the reactive metals commonly processed by CIP if all these materials were present

bull Shapes with high ratios (greater than 10) of length to characteristic diameter can be densified and handled

bull Parts with reentrant and three-dimensional curved geometries can be made

bull Elastomer tooling can be combined with metal tooling inserts to exactly control certain part dimensions such as cylinder bores or outside diameters

bull Thin-walled sections and parts can be pressed

bull Elastomer tooling costs are low

Recognized limitations of the process includebull Dimensional control is generally less precise than

with metal die compaction because of the absence of exactly dimensioned reference surfaces and variability of the local poured powder density within the mold

bull Surface finish of cold isostatically pressed parts is rough compared to die-compacted parts except for areas in contact with hard tool inserts in hybrid molds

bull Production rates are low compared to metal die compaction

bull Elastomer molds have a relatively short life because of abrasive wear

bull Leakage of a mold in the CIP vessel due to mold tearing or poor closure and sealing practice results in loss of material due to contamination by the working fluid

bull With reactive fine powders such as aluminum in large molds water leakage into the mold can produce a hazardous exothermic reaction

bull Figure Complex cold isostatically pressed PM part made using internal round and square hard-tooling inserts

Two types of processes

i) Cold Isostatic Pressing

ii) Hot Isostatic Pressing

Cold Isostaic Process ----- two methods are used

(a) free mould or wet bag process is suited for

(i) batch scale production

(ii) the mold is filled and sealed outside the pressure vessel

(iii) After the mold is introduced in to the pressure vessel it is completely immersed in the pressure medium usually water containing lubricating and corrosion-preventive additives

(iv) complex parts

(v) research and prototype work

(vi) several moulds in one run-even with differing shape ie parts of different sizes and shapes that require the same process parameters can be pressed in the same cycle

a) Powder fill by weight or volume b) Filling of the mould from the top

c) Top lid put on the mould container

d) Mould is placed inside the pressure vessel

e) Top lid put on the pressure vessel after necessary evacuation and filling with the pressurizing medium

f) Top lid removed after required isostatic compaction for removal of the mould

(b) fixed mould or dry bag process (Figure 3) which is characterized by

(i) envelope is permanently fixed into the pressure vessel

(ii) After the elastomeric mold is filled with powder pressure is applied by introducing pressurized oil between the fixed mold and the vessel wall

(iii) only one compact at a time is used

(iv) more simple shapes are made and

(v) more suited for mass production and faster production rates

Fig3 Schematic of equipment for dry-bag isostatic pressing

Pressure Generators

bull Pressure is generated in the pressure medium through the use of air-driven and hydraulically driven pumps and pressure intensifiers bull The pressure medium typically is oil for dry bag processes water containing additives (water-soluble oil or rust inhibitors) is used for wet bag processes A filtering system should be included with all systems to protect the pressure-generating equipment from particulate contamination

bullDepressurization Systems Depressurization can be accomplished with a single metering valve

Tooling for Isostatic Compacting

Cold isostatic pressing tooling is composed of two partsmdashthe elastomeric mold or bag and a mandrel

Elastomeric molds are made of a variety of materials some are flexible while others are fairly rigid

An outside fixture to hold the loaded form is required if the mold is exceptionally flexible

A number of factors must be considered in the selection of a mold material

Primarily the mold material must not interact with either the powder or the pressure medium

Materials have a range of durabilities Depending on the size of the production run and the

abrasiveness of the powder a material with the appropriate wear resistance should be selected

Mold materials used include natural rubber neoprene urethane polyvinyl chloride butyl nitrile and silicone

(A)suggestions for mould are

(1) Disposable and reusable mould materials are recommended

Disposable mould materials are polystyrene- polyethylene which provide thin wall envelopes and prevent breakage of the given compact but the mould becomes expensive

Reusable materials are urethane silicone rubber neoprene natural rubber and provide (a) greater wall thickness of the envelope (b) good shape control but complex parts may break upon pressure release

(2) The mould material must be sufficiently flexible (high elastic deformation) with low permanent set to accommodate the volume changes during compaction

(3) It must have a sufficient hardness and high resistance to abrasive wear High hardness also means no penetration of the material between powder particles and hence a good surface finish of the compacted part But in case of too high a hardness compressibility is poor and intricate shapes are difficult to fabricate A hardness between 65 and 95 shore A is used depending on the powder material and part shape

(4) Flexible thin walled envelopes may deform when filled with powder and support must be provided to control the compact shape eg container with holes is used or use of fasteners is made Fig 1

(5) Auxiliary tooling elements are

(a) a vacuum fan behind the support to pull the elastic mould exactly in place during filling For mixed mould processing the same action can be carried out by a reversed pumping action on the pressure medium

(b) a vacuum fan as reversed pumping can also be used to open up the mould for stripping compacted parts

(c) a vacuum connection to the filled area to de-air the filled mould before the compacting operation

(d) sealing support and clamping elements are also used

If internal shapes or cavities are desired in the compacted part a rigid mandrel can be used in the tooling

The mandrel usually is made of hardenable steel It should have a very smooth surface finish to encourage part release Complex shapes with reasonable tolerances can be achieved with the use of a mandrel

B) Suggestions for Equipment are as under1) Direct and indirect compression devices are used2) Pressure vessel material recommended is forged

medium carbon steel alloyed and heat treated3) Pressure vessels which have cover plates both on

top and on the bottom of the mould may be used so that the powder can be introduced at the top and the compact ejected at the bottom

4) Specialized equipment - the ROTOPRESS - 10 to 15 pieces per minute production units presently are being designed with 150 cm dia and maximum pressure 2000-3000 atmospheres or 60 cm dia and maximum pressure 10000 - 25000 atmospheres

5) Through the use of automated equipment it is possible to achieve

(a) careful processing (including particle size control)

(b) avoid contamination of the powders

(c) maintain uniform temperature of the pressurizing liquid and of the powders

(d) control of humidity of powders pressure and compacting time and

(e) ultimate excellent dimensional control

Applications of Cold Isostatic Compaction These include

(i) Titanium eg hydraulic aircraft fittings using Ti powder and Al-V master alloy powder

(ii) High-speed tool steels (eg cutting tools)

(iii) Compacts with interior threads

(iv) Long hollow cylindrical filters (stainless steel and titanium powder)

(v) Large shapes from tungsten powder such as rocket nozzle

(vi) Tungsten and molybdenum blooms or slabs for further forging andor rolling

Cross-section of Molding Bag

Body Armor

Bag and Molding Core Pin

Bag and Pressing Mandrel

A Sample of Bags

Cross-section of Bag

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
  • Slide 3
  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
  • Slide 6
  • Slide 7
  • Slide 8
  • Slide 9
  • Slide 10
  • Slide 11
  • Slide 12
  • Slide 13
  • a) Powder fill by weight or volume b) Filling of the mould from the top
  • Slide 15
  • Slide 16
  • Slide 17
  • Slide 18
  • Slide 19
  • Slide 20
  • Slide 21
  • Slide 22
  • Slide 23
  • Slide 24
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  • Slide 26
  • Slide 27
  • Slide 28
  • Slide 29
  • Slide 30
  • Slide 31
  • Slide 32
  • Slide 33
  • Slide 34
  • Slide 35
  • Slide 36
  • Slide 37
  • Tubes Made by Isostatic Pressing 1048698Isopressing Mold and Mandrel
  • Slide 39
Page 7: ISOSTATIC PRESSING

bull Parts with reentrant and three-dimensional curved geometries can be made

bull Elastomer tooling can be combined with metal tooling inserts to exactly control certain part dimensions such as cylinder bores or outside diameters

bull Thin-walled sections and parts can be pressed

bull Elastomer tooling costs are low

Recognized limitations of the process includebull Dimensional control is generally less precise than

with metal die compaction because of the absence of exactly dimensioned reference surfaces and variability of the local poured powder density within the mold

bull Surface finish of cold isostatically pressed parts is rough compared to die-compacted parts except for areas in contact with hard tool inserts in hybrid molds

bull Production rates are low compared to metal die compaction

bull Elastomer molds have a relatively short life because of abrasive wear

bull Leakage of a mold in the CIP vessel due to mold tearing or poor closure and sealing practice results in loss of material due to contamination by the working fluid

bull With reactive fine powders such as aluminum in large molds water leakage into the mold can produce a hazardous exothermic reaction

bull Figure Complex cold isostatically pressed PM part made using internal round and square hard-tooling inserts

Two types of processes

i) Cold Isostatic Pressing

ii) Hot Isostatic Pressing

Cold Isostaic Process ----- two methods are used

(a) free mould or wet bag process is suited for

(i) batch scale production

(ii) the mold is filled and sealed outside the pressure vessel

(iii) After the mold is introduced in to the pressure vessel it is completely immersed in the pressure medium usually water containing lubricating and corrosion-preventive additives

(iv) complex parts

(v) research and prototype work

(vi) several moulds in one run-even with differing shape ie parts of different sizes and shapes that require the same process parameters can be pressed in the same cycle

a) Powder fill by weight or volume b) Filling of the mould from the top

c) Top lid put on the mould container

d) Mould is placed inside the pressure vessel

e) Top lid put on the pressure vessel after necessary evacuation and filling with the pressurizing medium

f) Top lid removed after required isostatic compaction for removal of the mould

(b) fixed mould or dry bag process (Figure 3) which is characterized by

(i) envelope is permanently fixed into the pressure vessel

(ii) After the elastomeric mold is filled with powder pressure is applied by introducing pressurized oil between the fixed mold and the vessel wall

(iii) only one compact at a time is used

(iv) more simple shapes are made and

(v) more suited for mass production and faster production rates

Fig3 Schematic of equipment for dry-bag isostatic pressing

Pressure Generators

bull Pressure is generated in the pressure medium through the use of air-driven and hydraulically driven pumps and pressure intensifiers bull The pressure medium typically is oil for dry bag processes water containing additives (water-soluble oil or rust inhibitors) is used for wet bag processes A filtering system should be included with all systems to protect the pressure-generating equipment from particulate contamination

bullDepressurization Systems Depressurization can be accomplished with a single metering valve

Tooling for Isostatic Compacting

Cold isostatic pressing tooling is composed of two partsmdashthe elastomeric mold or bag and a mandrel

Elastomeric molds are made of a variety of materials some are flexible while others are fairly rigid

An outside fixture to hold the loaded form is required if the mold is exceptionally flexible

A number of factors must be considered in the selection of a mold material

Primarily the mold material must not interact with either the powder or the pressure medium

Materials have a range of durabilities Depending on the size of the production run and the

abrasiveness of the powder a material with the appropriate wear resistance should be selected

Mold materials used include natural rubber neoprene urethane polyvinyl chloride butyl nitrile and silicone

(A)suggestions for mould are

(1) Disposable and reusable mould materials are recommended

Disposable mould materials are polystyrene- polyethylene which provide thin wall envelopes and prevent breakage of the given compact but the mould becomes expensive

Reusable materials are urethane silicone rubber neoprene natural rubber and provide (a) greater wall thickness of the envelope (b) good shape control but complex parts may break upon pressure release

(2) The mould material must be sufficiently flexible (high elastic deformation) with low permanent set to accommodate the volume changes during compaction

(3) It must have a sufficient hardness and high resistance to abrasive wear High hardness also means no penetration of the material between powder particles and hence a good surface finish of the compacted part But in case of too high a hardness compressibility is poor and intricate shapes are difficult to fabricate A hardness between 65 and 95 shore A is used depending on the powder material and part shape

(4) Flexible thin walled envelopes may deform when filled with powder and support must be provided to control the compact shape eg container with holes is used or use of fasteners is made Fig 1

(5) Auxiliary tooling elements are

(a) a vacuum fan behind the support to pull the elastic mould exactly in place during filling For mixed mould processing the same action can be carried out by a reversed pumping action on the pressure medium

(b) a vacuum fan as reversed pumping can also be used to open up the mould for stripping compacted parts

(c) a vacuum connection to the filled area to de-air the filled mould before the compacting operation

(d) sealing support and clamping elements are also used

If internal shapes or cavities are desired in the compacted part a rigid mandrel can be used in the tooling

The mandrel usually is made of hardenable steel It should have a very smooth surface finish to encourage part release Complex shapes with reasonable tolerances can be achieved with the use of a mandrel

B) Suggestions for Equipment are as under1) Direct and indirect compression devices are used2) Pressure vessel material recommended is forged

medium carbon steel alloyed and heat treated3) Pressure vessels which have cover plates both on

top and on the bottom of the mould may be used so that the powder can be introduced at the top and the compact ejected at the bottom

4) Specialized equipment - the ROTOPRESS - 10 to 15 pieces per minute production units presently are being designed with 150 cm dia and maximum pressure 2000-3000 atmospheres or 60 cm dia and maximum pressure 10000 - 25000 atmospheres

5) Through the use of automated equipment it is possible to achieve

(a) careful processing (including particle size control)

(b) avoid contamination of the powders

(c) maintain uniform temperature of the pressurizing liquid and of the powders

(d) control of humidity of powders pressure and compacting time and

(e) ultimate excellent dimensional control

Applications of Cold Isostatic Compaction These include

(i) Titanium eg hydraulic aircraft fittings using Ti powder and Al-V master alloy powder

(ii) High-speed tool steels (eg cutting tools)

(iii) Compacts with interior threads

(iv) Long hollow cylindrical filters (stainless steel and titanium powder)

(v) Large shapes from tungsten powder such as rocket nozzle

(vi) Tungsten and molybdenum blooms or slabs for further forging andor rolling

Cross-section of Molding Bag

Body Armor

Bag and Molding Core Pin

Bag and Pressing Mandrel

A Sample of Bags

Cross-section of Bag

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
  • Slide 3
  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
  • Slide 6
  • Slide 7
  • Slide 8
  • Slide 9
  • Slide 10
  • Slide 11
  • Slide 12
  • Slide 13
  • a) Powder fill by weight or volume b) Filling of the mould from the top
  • Slide 15
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  • Tubes Made by Isostatic Pressing 1048698Isopressing Mold and Mandrel
  • Slide 39
Page 8: ISOSTATIC PRESSING

Recognized limitations of the process includebull Dimensional control is generally less precise than

with metal die compaction because of the absence of exactly dimensioned reference surfaces and variability of the local poured powder density within the mold

bull Surface finish of cold isostatically pressed parts is rough compared to die-compacted parts except for areas in contact with hard tool inserts in hybrid molds

bull Production rates are low compared to metal die compaction

bull Elastomer molds have a relatively short life because of abrasive wear

bull Leakage of a mold in the CIP vessel due to mold tearing or poor closure and sealing practice results in loss of material due to contamination by the working fluid

bull With reactive fine powders such as aluminum in large molds water leakage into the mold can produce a hazardous exothermic reaction

bull Figure Complex cold isostatically pressed PM part made using internal round and square hard-tooling inserts

Two types of processes

i) Cold Isostatic Pressing

ii) Hot Isostatic Pressing

Cold Isostaic Process ----- two methods are used

(a) free mould or wet bag process is suited for

(i) batch scale production

(ii) the mold is filled and sealed outside the pressure vessel

(iii) After the mold is introduced in to the pressure vessel it is completely immersed in the pressure medium usually water containing lubricating and corrosion-preventive additives

(iv) complex parts

(v) research and prototype work

(vi) several moulds in one run-even with differing shape ie parts of different sizes and shapes that require the same process parameters can be pressed in the same cycle

a) Powder fill by weight or volume b) Filling of the mould from the top

c) Top lid put on the mould container

d) Mould is placed inside the pressure vessel

e) Top lid put on the pressure vessel after necessary evacuation and filling with the pressurizing medium

f) Top lid removed after required isostatic compaction for removal of the mould

(b) fixed mould or dry bag process (Figure 3) which is characterized by

(i) envelope is permanently fixed into the pressure vessel

(ii) After the elastomeric mold is filled with powder pressure is applied by introducing pressurized oil between the fixed mold and the vessel wall

(iii) only one compact at a time is used

(iv) more simple shapes are made and

(v) more suited for mass production and faster production rates

Fig3 Schematic of equipment for dry-bag isostatic pressing

Pressure Generators

bull Pressure is generated in the pressure medium through the use of air-driven and hydraulically driven pumps and pressure intensifiers bull The pressure medium typically is oil for dry bag processes water containing additives (water-soluble oil or rust inhibitors) is used for wet bag processes A filtering system should be included with all systems to protect the pressure-generating equipment from particulate contamination

bullDepressurization Systems Depressurization can be accomplished with a single metering valve

Tooling for Isostatic Compacting

Cold isostatic pressing tooling is composed of two partsmdashthe elastomeric mold or bag and a mandrel

Elastomeric molds are made of a variety of materials some are flexible while others are fairly rigid

An outside fixture to hold the loaded form is required if the mold is exceptionally flexible

A number of factors must be considered in the selection of a mold material

Primarily the mold material must not interact with either the powder or the pressure medium

Materials have a range of durabilities Depending on the size of the production run and the

abrasiveness of the powder a material with the appropriate wear resistance should be selected

Mold materials used include natural rubber neoprene urethane polyvinyl chloride butyl nitrile and silicone

(A)suggestions for mould are

(1) Disposable and reusable mould materials are recommended

Disposable mould materials are polystyrene- polyethylene which provide thin wall envelopes and prevent breakage of the given compact but the mould becomes expensive

Reusable materials are urethane silicone rubber neoprene natural rubber and provide (a) greater wall thickness of the envelope (b) good shape control but complex parts may break upon pressure release

(2) The mould material must be sufficiently flexible (high elastic deformation) with low permanent set to accommodate the volume changes during compaction

(3) It must have a sufficient hardness and high resistance to abrasive wear High hardness also means no penetration of the material between powder particles and hence a good surface finish of the compacted part But in case of too high a hardness compressibility is poor and intricate shapes are difficult to fabricate A hardness between 65 and 95 shore A is used depending on the powder material and part shape

(4) Flexible thin walled envelopes may deform when filled with powder and support must be provided to control the compact shape eg container with holes is used or use of fasteners is made Fig 1

(5) Auxiliary tooling elements are

(a) a vacuum fan behind the support to pull the elastic mould exactly in place during filling For mixed mould processing the same action can be carried out by a reversed pumping action on the pressure medium

(b) a vacuum fan as reversed pumping can also be used to open up the mould for stripping compacted parts

(c) a vacuum connection to the filled area to de-air the filled mould before the compacting operation

(d) sealing support and clamping elements are also used

If internal shapes or cavities are desired in the compacted part a rigid mandrel can be used in the tooling

The mandrel usually is made of hardenable steel It should have a very smooth surface finish to encourage part release Complex shapes with reasonable tolerances can be achieved with the use of a mandrel

B) Suggestions for Equipment are as under1) Direct and indirect compression devices are used2) Pressure vessel material recommended is forged

medium carbon steel alloyed and heat treated3) Pressure vessels which have cover plates both on

top and on the bottom of the mould may be used so that the powder can be introduced at the top and the compact ejected at the bottom

4) Specialized equipment - the ROTOPRESS - 10 to 15 pieces per minute production units presently are being designed with 150 cm dia and maximum pressure 2000-3000 atmospheres or 60 cm dia and maximum pressure 10000 - 25000 atmospheres

5) Through the use of automated equipment it is possible to achieve

(a) careful processing (including particle size control)

(b) avoid contamination of the powders

(c) maintain uniform temperature of the pressurizing liquid and of the powders

(d) control of humidity of powders pressure and compacting time and

(e) ultimate excellent dimensional control

Applications of Cold Isostatic Compaction These include

(i) Titanium eg hydraulic aircraft fittings using Ti powder and Al-V master alloy powder

(ii) High-speed tool steels (eg cutting tools)

(iii) Compacts with interior threads

(iv) Long hollow cylindrical filters (stainless steel and titanium powder)

(v) Large shapes from tungsten powder such as rocket nozzle

(vi) Tungsten and molybdenum blooms or slabs for further forging andor rolling

Cross-section of Molding Bag

Body Armor

Bag and Molding Core Pin

Bag and Pressing Mandrel

A Sample of Bags

Cross-section of Bag

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
  • Slide 3
  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
  • Slide 6
  • Slide 7
  • Slide 8
  • Slide 9
  • Slide 10
  • Slide 11
  • Slide 12
  • Slide 13
  • a) Powder fill by weight or volume b) Filling of the mould from the top
  • Slide 15
  • Slide 16
  • Slide 17
  • Slide 18
  • Slide 19
  • Slide 20
  • Slide 21
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  • Slide 34
  • Slide 35
  • Slide 36
  • Slide 37
  • Tubes Made by Isostatic Pressing 1048698Isopressing Mold and Mandrel
  • Slide 39
Page 9: ISOSTATIC PRESSING

bull Leakage of a mold in the CIP vessel due to mold tearing or poor closure and sealing practice results in loss of material due to contamination by the working fluid

bull With reactive fine powders such as aluminum in large molds water leakage into the mold can produce a hazardous exothermic reaction

bull Figure Complex cold isostatically pressed PM part made using internal round and square hard-tooling inserts

Two types of processes

i) Cold Isostatic Pressing

ii) Hot Isostatic Pressing

Cold Isostaic Process ----- two methods are used

(a) free mould or wet bag process is suited for

(i) batch scale production

(ii) the mold is filled and sealed outside the pressure vessel

(iii) After the mold is introduced in to the pressure vessel it is completely immersed in the pressure medium usually water containing lubricating and corrosion-preventive additives

(iv) complex parts

(v) research and prototype work

(vi) several moulds in one run-even with differing shape ie parts of different sizes and shapes that require the same process parameters can be pressed in the same cycle

a) Powder fill by weight or volume b) Filling of the mould from the top

c) Top lid put on the mould container

d) Mould is placed inside the pressure vessel

e) Top lid put on the pressure vessel after necessary evacuation and filling with the pressurizing medium

f) Top lid removed after required isostatic compaction for removal of the mould

(b) fixed mould or dry bag process (Figure 3) which is characterized by

(i) envelope is permanently fixed into the pressure vessel

(ii) After the elastomeric mold is filled with powder pressure is applied by introducing pressurized oil between the fixed mold and the vessel wall

(iii) only one compact at a time is used

(iv) more simple shapes are made and

(v) more suited for mass production and faster production rates

Fig3 Schematic of equipment for dry-bag isostatic pressing

Pressure Generators

bull Pressure is generated in the pressure medium through the use of air-driven and hydraulically driven pumps and pressure intensifiers bull The pressure medium typically is oil for dry bag processes water containing additives (water-soluble oil or rust inhibitors) is used for wet bag processes A filtering system should be included with all systems to protect the pressure-generating equipment from particulate contamination

bullDepressurization Systems Depressurization can be accomplished with a single metering valve

Tooling for Isostatic Compacting

Cold isostatic pressing tooling is composed of two partsmdashthe elastomeric mold or bag and a mandrel

Elastomeric molds are made of a variety of materials some are flexible while others are fairly rigid

An outside fixture to hold the loaded form is required if the mold is exceptionally flexible

A number of factors must be considered in the selection of a mold material

Primarily the mold material must not interact with either the powder or the pressure medium

Materials have a range of durabilities Depending on the size of the production run and the

abrasiveness of the powder a material with the appropriate wear resistance should be selected

Mold materials used include natural rubber neoprene urethane polyvinyl chloride butyl nitrile and silicone

(A)suggestions for mould are

(1) Disposable and reusable mould materials are recommended

Disposable mould materials are polystyrene- polyethylene which provide thin wall envelopes and prevent breakage of the given compact but the mould becomes expensive

Reusable materials are urethane silicone rubber neoprene natural rubber and provide (a) greater wall thickness of the envelope (b) good shape control but complex parts may break upon pressure release

(2) The mould material must be sufficiently flexible (high elastic deformation) with low permanent set to accommodate the volume changes during compaction

(3) It must have a sufficient hardness and high resistance to abrasive wear High hardness also means no penetration of the material between powder particles and hence a good surface finish of the compacted part But in case of too high a hardness compressibility is poor and intricate shapes are difficult to fabricate A hardness between 65 and 95 shore A is used depending on the powder material and part shape

(4) Flexible thin walled envelopes may deform when filled with powder and support must be provided to control the compact shape eg container with holes is used or use of fasteners is made Fig 1

(5) Auxiliary tooling elements are

(a) a vacuum fan behind the support to pull the elastic mould exactly in place during filling For mixed mould processing the same action can be carried out by a reversed pumping action on the pressure medium

(b) a vacuum fan as reversed pumping can also be used to open up the mould for stripping compacted parts

(c) a vacuum connection to the filled area to de-air the filled mould before the compacting operation

(d) sealing support and clamping elements are also used

If internal shapes or cavities are desired in the compacted part a rigid mandrel can be used in the tooling

The mandrel usually is made of hardenable steel It should have a very smooth surface finish to encourage part release Complex shapes with reasonable tolerances can be achieved with the use of a mandrel

B) Suggestions for Equipment are as under1) Direct and indirect compression devices are used2) Pressure vessel material recommended is forged

medium carbon steel alloyed and heat treated3) Pressure vessels which have cover plates both on

top and on the bottom of the mould may be used so that the powder can be introduced at the top and the compact ejected at the bottom

4) Specialized equipment - the ROTOPRESS - 10 to 15 pieces per minute production units presently are being designed with 150 cm dia and maximum pressure 2000-3000 atmospheres or 60 cm dia and maximum pressure 10000 - 25000 atmospheres

5) Through the use of automated equipment it is possible to achieve

(a) careful processing (including particle size control)

(b) avoid contamination of the powders

(c) maintain uniform temperature of the pressurizing liquid and of the powders

(d) control of humidity of powders pressure and compacting time and

(e) ultimate excellent dimensional control

Applications of Cold Isostatic Compaction These include

(i) Titanium eg hydraulic aircraft fittings using Ti powder and Al-V master alloy powder

(ii) High-speed tool steels (eg cutting tools)

(iii) Compacts with interior threads

(iv) Long hollow cylindrical filters (stainless steel and titanium powder)

(v) Large shapes from tungsten powder such as rocket nozzle

(vi) Tungsten and molybdenum blooms or slabs for further forging andor rolling

Cross-section of Molding Bag

Body Armor

Bag and Molding Core Pin

Bag and Pressing Mandrel

A Sample of Bags

Cross-section of Bag

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
  • Slide 3
  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
  • Slide 6
  • Slide 7
  • Slide 8
  • Slide 9
  • Slide 10
  • Slide 11
  • Slide 12
  • Slide 13
  • a) Powder fill by weight or volume b) Filling of the mould from the top
  • Slide 15
  • Slide 16
  • Slide 17
  • Slide 18
  • Slide 19
  • Slide 20
  • Slide 21
  • Slide 22
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  • Slide 33
  • Slide 34
  • Slide 35
  • Slide 36
  • Slide 37
  • Tubes Made by Isostatic Pressing 1048698Isopressing Mold and Mandrel
  • Slide 39
Page 10: ISOSTATIC PRESSING

bull Figure Complex cold isostatically pressed PM part made using internal round and square hard-tooling inserts

Two types of processes

i) Cold Isostatic Pressing

ii) Hot Isostatic Pressing

Cold Isostaic Process ----- two methods are used

(a) free mould or wet bag process is suited for

(i) batch scale production

(ii) the mold is filled and sealed outside the pressure vessel

(iii) After the mold is introduced in to the pressure vessel it is completely immersed in the pressure medium usually water containing lubricating and corrosion-preventive additives

(iv) complex parts

(v) research and prototype work

(vi) several moulds in one run-even with differing shape ie parts of different sizes and shapes that require the same process parameters can be pressed in the same cycle

a) Powder fill by weight or volume b) Filling of the mould from the top

c) Top lid put on the mould container

d) Mould is placed inside the pressure vessel

e) Top lid put on the pressure vessel after necessary evacuation and filling with the pressurizing medium

f) Top lid removed after required isostatic compaction for removal of the mould

(b) fixed mould or dry bag process (Figure 3) which is characterized by

(i) envelope is permanently fixed into the pressure vessel

(ii) After the elastomeric mold is filled with powder pressure is applied by introducing pressurized oil between the fixed mold and the vessel wall

(iii) only one compact at a time is used

(iv) more simple shapes are made and

(v) more suited for mass production and faster production rates

Fig3 Schematic of equipment for dry-bag isostatic pressing

Pressure Generators

bull Pressure is generated in the pressure medium through the use of air-driven and hydraulically driven pumps and pressure intensifiers bull The pressure medium typically is oil for dry bag processes water containing additives (water-soluble oil or rust inhibitors) is used for wet bag processes A filtering system should be included with all systems to protect the pressure-generating equipment from particulate contamination

bullDepressurization Systems Depressurization can be accomplished with a single metering valve

Tooling for Isostatic Compacting

Cold isostatic pressing tooling is composed of two partsmdashthe elastomeric mold or bag and a mandrel

Elastomeric molds are made of a variety of materials some are flexible while others are fairly rigid

An outside fixture to hold the loaded form is required if the mold is exceptionally flexible

A number of factors must be considered in the selection of a mold material

Primarily the mold material must not interact with either the powder or the pressure medium

Materials have a range of durabilities Depending on the size of the production run and the

abrasiveness of the powder a material with the appropriate wear resistance should be selected

Mold materials used include natural rubber neoprene urethane polyvinyl chloride butyl nitrile and silicone

(A)suggestions for mould are

(1) Disposable and reusable mould materials are recommended

Disposable mould materials are polystyrene- polyethylene which provide thin wall envelopes and prevent breakage of the given compact but the mould becomes expensive

Reusable materials are urethane silicone rubber neoprene natural rubber and provide (a) greater wall thickness of the envelope (b) good shape control but complex parts may break upon pressure release

(2) The mould material must be sufficiently flexible (high elastic deformation) with low permanent set to accommodate the volume changes during compaction

(3) It must have a sufficient hardness and high resistance to abrasive wear High hardness also means no penetration of the material between powder particles and hence a good surface finish of the compacted part But in case of too high a hardness compressibility is poor and intricate shapes are difficult to fabricate A hardness between 65 and 95 shore A is used depending on the powder material and part shape

(4) Flexible thin walled envelopes may deform when filled with powder and support must be provided to control the compact shape eg container with holes is used or use of fasteners is made Fig 1

(5) Auxiliary tooling elements are

(a) a vacuum fan behind the support to pull the elastic mould exactly in place during filling For mixed mould processing the same action can be carried out by a reversed pumping action on the pressure medium

(b) a vacuum fan as reversed pumping can also be used to open up the mould for stripping compacted parts

(c) a vacuum connection to the filled area to de-air the filled mould before the compacting operation

(d) sealing support and clamping elements are also used

If internal shapes or cavities are desired in the compacted part a rigid mandrel can be used in the tooling

The mandrel usually is made of hardenable steel It should have a very smooth surface finish to encourage part release Complex shapes with reasonable tolerances can be achieved with the use of a mandrel

B) Suggestions for Equipment are as under1) Direct and indirect compression devices are used2) Pressure vessel material recommended is forged

medium carbon steel alloyed and heat treated3) Pressure vessels which have cover plates both on

top and on the bottom of the mould may be used so that the powder can be introduced at the top and the compact ejected at the bottom

4) Specialized equipment - the ROTOPRESS - 10 to 15 pieces per minute production units presently are being designed with 150 cm dia and maximum pressure 2000-3000 atmospheres or 60 cm dia and maximum pressure 10000 - 25000 atmospheres

5) Through the use of automated equipment it is possible to achieve

(a) careful processing (including particle size control)

(b) avoid contamination of the powders

(c) maintain uniform temperature of the pressurizing liquid and of the powders

(d) control of humidity of powders pressure and compacting time and

(e) ultimate excellent dimensional control

Applications of Cold Isostatic Compaction These include

(i) Titanium eg hydraulic aircraft fittings using Ti powder and Al-V master alloy powder

(ii) High-speed tool steels (eg cutting tools)

(iii) Compacts with interior threads

(iv) Long hollow cylindrical filters (stainless steel and titanium powder)

(v) Large shapes from tungsten powder such as rocket nozzle

(vi) Tungsten and molybdenum blooms or slabs for further forging andor rolling

Cross-section of Molding Bag

Body Armor

Bag and Molding Core Pin

Bag and Pressing Mandrel

A Sample of Bags

Cross-section of Bag

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
  • Slide 3
  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
  • Slide 6
  • Slide 7
  • Slide 8
  • Slide 9
  • Slide 10
  • Slide 11
  • Slide 12
  • Slide 13
  • a) Powder fill by weight or volume b) Filling of the mould from the top
  • Slide 15
  • Slide 16
  • Slide 17
  • Slide 18
  • Slide 19
  • Slide 20
  • Slide 21
  • Slide 22
  • Slide 23
  • Slide 24
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  • Slide 29
  • Slide 30
  • Slide 31
  • Slide 32
  • Slide 33
  • Slide 34
  • Slide 35
  • Slide 36
  • Slide 37
  • Tubes Made by Isostatic Pressing 1048698Isopressing Mold and Mandrel
  • Slide 39
Page 11: ISOSTATIC PRESSING

Two types of processes

i) Cold Isostatic Pressing

ii) Hot Isostatic Pressing

Cold Isostaic Process ----- two methods are used

(a) free mould or wet bag process is suited for

(i) batch scale production

(ii) the mold is filled and sealed outside the pressure vessel

(iii) After the mold is introduced in to the pressure vessel it is completely immersed in the pressure medium usually water containing lubricating and corrosion-preventive additives

(iv) complex parts

(v) research and prototype work

(vi) several moulds in one run-even with differing shape ie parts of different sizes and shapes that require the same process parameters can be pressed in the same cycle

a) Powder fill by weight or volume b) Filling of the mould from the top

c) Top lid put on the mould container

d) Mould is placed inside the pressure vessel

e) Top lid put on the pressure vessel after necessary evacuation and filling with the pressurizing medium

f) Top lid removed after required isostatic compaction for removal of the mould

(b) fixed mould or dry bag process (Figure 3) which is characterized by

(i) envelope is permanently fixed into the pressure vessel

(ii) After the elastomeric mold is filled with powder pressure is applied by introducing pressurized oil between the fixed mold and the vessel wall

(iii) only one compact at a time is used

(iv) more simple shapes are made and

(v) more suited for mass production and faster production rates

Fig3 Schematic of equipment for dry-bag isostatic pressing

Pressure Generators

bull Pressure is generated in the pressure medium through the use of air-driven and hydraulically driven pumps and pressure intensifiers bull The pressure medium typically is oil for dry bag processes water containing additives (water-soluble oil or rust inhibitors) is used for wet bag processes A filtering system should be included with all systems to protect the pressure-generating equipment from particulate contamination

bullDepressurization Systems Depressurization can be accomplished with a single metering valve

Tooling for Isostatic Compacting

Cold isostatic pressing tooling is composed of two partsmdashthe elastomeric mold or bag and a mandrel

Elastomeric molds are made of a variety of materials some are flexible while others are fairly rigid

An outside fixture to hold the loaded form is required if the mold is exceptionally flexible

A number of factors must be considered in the selection of a mold material

Primarily the mold material must not interact with either the powder or the pressure medium

Materials have a range of durabilities Depending on the size of the production run and the

abrasiveness of the powder a material with the appropriate wear resistance should be selected

Mold materials used include natural rubber neoprene urethane polyvinyl chloride butyl nitrile and silicone

(A)suggestions for mould are

(1) Disposable and reusable mould materials are recommended

Disposable mould materials are polystyrene- polyethylene which provide thin wall envelopes and prevent breakage of the given compact but the mould becomes expensive

Reusable materials are urethane silicone rubber neoprene natural rubber and provide (a) greater wall thickness of the envelope (b) good shape control but complex parts may break upon pressure release

(2) The mould material must be sufficiently flexible (high elastic deformation) with low permanent set to accommodate the volume changes during compaction

(3) It must have a sufficient hardness and high resistance to abrasive wear High hardness also means no penetration of the material between powder particles and hence a good surface finish of the compacted part But in case of too high a hardness compressibility is poor and intricate shapes are difficult to fabricate A hardness between 65 and 95 shore A is used depending on the powder material and part shape

(4) Flexible thin walled envelopes may deform when filled with powder and support must be provided to control the compact shape eg container with holes is used or use of fasteners is made Fig 1

(5) Auxiliary tooling elements are

(a) a vacuum fan behind the support to pull the elastic mould exactly in place during filling For mixed mould processing the same action can be carried out by a reversed pumping action on the pressure medium

(b) a vacuum fan as reversed pumping can also be used to open up the mould for stripping compacted parts

(c) a vacuum connection to the filled area to de-air the filled mould before the compacting operation

(d) sealing support and clamping elements are also used

If internal shapes or cavities are desired in the compacted part a rigid mandrel can be used in the tooling

The mandrel usually is made of hardenable steel It should have a very smooth surface finish to encourage part release Complex shapes with reasonable tolerances can be achieved with the use of a mandrel

B) Suggestions for Equipment are as under1) Direct and indirect compression devices are used2) Pressure vessel material recommended is forged

medium carbon steel alloyed and heat treated3) Pressure vessels which have cover plates both on

top and on the bottom of the mould may be used so that the powder can be introduced at the top and the compact ejected at the bottom

4) Specialized equipment - the ROTOPRESS - 10 to 15 pieces per minute production units presently are being designed with 150 cm dia and maximum pressure 2000-3000 atmospheres or 60 cm dia and maximum pressure 10000 - 25000 atmospheres

5) Through the use of automated equipment it is possible to achieve

(a) careful processing (including particle size control)

(b) avoid contamination of the powders

(c) maintain uniform temperature of the pressurizing liquid and of the powders

(d) control of humidity of powders pressure and compacting time and

(e) ultimate excellent dimensional control

Applications of Cold Isostatic Compaction These include

(i) Titanium eg hydraulic aircraft fittings using Ti powder and Al-V master alloy powder

(ii) High-speed tool steels (eg cutting tools)

(iii) Compacts with interior threads

(iv) Long hollow cylindrical filters (stainless steel and titanium powder)

(v) Large shapes from tungsten powder such as rocket nozzle

(vi) Tungsten and molybdenum blooms or slabs for further forging andor rolling

Cross-section of Molding Bag

Body Armor

Bag and Molding Core Pin

Bag and Pressing Mandrel

A Sample of Bags

Cross-section of Bag

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
  • Slide 3
  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
  • Slide 6
  • Slide 7
  • Slide 8
  • Slide 9
  • Slide 10
  • Slide 11
  • Slide 12
  • Slide 13
  • a) Powder fill by weight or volume b) Filling of the mould from the top
  • Slide 15
  • Slide 16
  • Slide 17
  • Slide 18
  • Slide 19
  • Slide 20
  • Slide 21
  • Slide 22
  • Slide 23
  • Slide 24
  • Slide 25
  • Slide 26
  • Slide 27
  • Slide 28
  • Slide 29
  • Slide 30
  • Slide 31
  • Slide 32
  • Slide 33
  • Slide 34
  • Slide 35
  • Slide 36
  • Slide 37
  • Tubes Made by Isostatic Pressing 1048698Isopressing Mold and Mandrel
  • Slide 39
Page 12: ISOSTATIC PRESSING

Cold Isostaic Process ----- two methods are used

(a) free mould or wet bag process is suited for

(i) batch scale production

(ii) the mold is filled and sealed outside the pressure vessel

(iii) After the mold is introduced in to the pressure vessel it is completely immersed in the pressure medium usually water containing lubricating and corrosion-preventive additives

(iv) complex parts

(v) research and prototype work

(vi) several moulds in one run-even with differing shape ie parts of different sizes and shapes that require the same process parameters can be pressed in the same cycle

a) Powder fill by weight or volume b) Filling of the mould from the top

c) Top lid put on the mould container

d) Mould is placed inside the pressure vessel

e) Top lid put on the pressure vessel after necessary evacuation and filling with the pressurizing medium

f) Top lid removed after required isostatic compaction for removal of the mould

(b) fixed mould or dry bag process (Figure 3) which is characterized by

(i) envelope is permanently fixed into the pressure vessel

(ii) After the elastomeric mold is filled with powder pressure is applied by introducing pressurized oil between the fixed mold and the vessel wall

(iii) only one compact at a time is used

(iv) more simple shapes are made and

(v) more suited for mass production and faster production rates

Fig3 Schematic of equipment for dry-bag isostatic pressing

Pressure Generators

bull Pressure is generated in the pressure medium through the use of air-driven and hydraulically driven pumps and pressure intensifiers bull The pressure medium typically is oil for dry bag processes water containing additives (water-soluble oil or rust inhibitors) is used for wet bag processes A filtering system should be included with all systems to protect the pressure-generating equipment from particulate contamination

bullDepressurization Systems Depressurization can be accomplished with a single metering valve

Tooling for Isostatic Compacting

Cold isostatic pressing tooling is composed of two partsmdashthe elastomeric mold or bag and a mandrel

Elastomeric molds are made of a variety of materials some are flexible while others are fairly rigid

An outside fixture to hold the loaded form is required if the mold is exceptionally flexible

A number of factors must be considered in the selection of a mold material

Primarily the mold material must not interact with either the powder or the pressure medium

Materials have a range of durabilities Depending on the size of the production run and the

abrasiveness of the powder a material with the appropriate wear resistance should be selected

Mold materials used include natural rubber neoprene urethane polyvinyl chloride butyl nitrile and silicone

(A)suggestions for mould are

(1) Disposable and reusable mould materials are recommended

Disposable mould materials are polystyrene- polyethylene which provide thin wall envelopes and prevent breakage of the given compact but the mould becomes expensive

Reusable materials are urethane silicone rubber neoprene natural rubber and provide (a) greater wall thickness of the envelope (b) good shape control but complex parts may break upon pressure release

(2) The mould material must be sufficiently flexible (high elastic deformation) with low permanent set to accommodate the volume changes during compaction

(3) It must have a sufficient hardness and high resistance to abrasive wear High hardness also means no penetration of the material between powder particles and hence a good surface finish of the compacted part But in case of too high a hardness compressibility is poor and intricate shapes are difficult to fabricate A hardness between 65 and 95 shore A is used depending on the powder material and part shape

(4) Flexible thin walled envelopes may deform when filled with powder and support must be provided to control the compact shape eg container with holes is used or use of fasteners is made Fig 1

(5) Auxiliary tooling elements are

(a) a vacuum fan behind the support to pull the elastic mould exactly in place during filling For mixed mould processing the same action can be carried out by a reversed pumping action on the pressure medium

(b) a vacuum fan as reversed pumping can also be used to open up the mould for stripping compacted parts

(c) a vacuum connection to the filled area to de-air the filled mould before the compacting operation

(d) sealing support and clamping elements are also used

If internal shapes or cavities are desired in the compacted part a rigid mandrel can be used in the tooling

The mandrel usually is made of hardenable steel It should have a very smooth surface finish to encourage part release Complex shapes with reasonable tolerances can be achieved with the use of a mandrel

B) Suggestions for Equipment are as under1) Direct and indirect compression devices are used2) Pressure vessel material recommended is forged

medium carbon steel alloyed and heat treated3) Pressure vessels which have cover plates both on

top and on the bottom of the mould may be used so that the powder can be introduced at the top and the compact ejected at the bottom

4) Specialized equipment - the ROTOPRESS - 10 to 15 pieces per minute production units presently are being designed with 150 cm dia and maximum pressure 2000-3000 atmospheres or 60 cm dia and maximum pressure 10000 - 25000 atmospheres

5) Through the use of automated equipment it is possible to achieve

(a) careful processing (including particle size control)

(b) avoid contamination of the powders

(c) maintain uniform temperature of the pressurizing liquid and of the powders

(d) control of humidity of powders pressure and compacting time and

(e) ultimate excellent dimensional control

Applications of Cold Isostatic Compaction These include

(i) Titanium eg hydraulic aircraft fittings using Ti powder and Al-V master alloy powder

(ii) High-speed tool steels (eg cutting tools)

(iii) Compacts with interior threads

(iv) Long hollow cylindrical filters (stainless steel and titanium powder)

(v) Large shapes from tungsten powder such as rocket nozzle

(vi) Tungsten and molybdenum blooms or slabs for further forging andor rolling

Cross-section of Molding Bag

Body Armor

Bag and Molding Core Pin

Bag and Pressing Mandrel

A Sample of Bags

Cross-section of Bag

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
  • Slide 3
  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
  • Slide 6
  • Slide 7
  • Slide 8
  • Slide 9
  • Slide 10
  • Slide 11
  • Slide 12
  • Slide 13
  • a) Powder fill by weight or volume b) Filling of the mould from the top
  • Slide 15
  • Slide 16
  • Slide 17
  • Slide 18
  • Slide 19
  • Slide 20
  • Slide 21
  • Slide 22
  • Slide 23
  • Slide 24
  • Slide 25
  • Slide 26
  • Slide 27
  • Slide 28
  • Slide 29
  • Slide 30
  • Slide 31
  • Slide 32
  • Slide 33
  • Slide 34
  • Slide 35
  • Slide 36
  • Slide 37
  • Tubes Made by Isostatic Pressing 1048698Isopressing Mold and Mandrel
  • Slide 39
Page 13: ISOSTATIC PRESSING

a) Powder fill by weight or volume b) Filling of the mould from the top

c) Top lid put on the mould container

d) Mould is placed inside the pressure vessel

e) Top lid put on the pressure vessel after necessary evacuation and filling with the pressurizing medium

f) Top lid removed after required isostatic compaction for removal of the mould

(b) fixed mould or dry bag process (Figure 3) which is characterized by

(i) envelope is permanently fixed into the pressure vessel

(ii) After the elastomeric mold is filled with powder pressure is applied by introducing pressurized oil between the fixed mold and the vessel wall

(iii) only one compact at a time is used

(iv) more simple shapes are made and

(v) more suited for mass production and faster production rates

Fig3 Schematic of equipment for dry-bag isostatic pressing

Pressure Generators

bull Pressure is generated in the pressure medium through the use of air-driven and hydraulically driven pumps and pressure intensifiers bull The pressure medium typically is oil for dry bag processes water containing additives (water-soluble oil or rust inhibitors) is used for wet bag processes A filtering system should be included with all systems to protect the pressure-generating equipment from particulate contamination

bullDepressurization Systems Depressurization can be accomplished with a single metering valve

Tooling for Isostatic Compacting

Cold isostatic pressing tooling is composed of two partsmdashthe elastomeric mold or bag and a mandrel

Elastomeric molds are made of a variety of materials some are flexible while others are fairly rigid

An outside fixture to hold the loaded form is required if the mold is exceptionally flexible

A number of factors must be considered in the selection of a mold material

Primarily the mold material must not interact with either the powder or the pressure medium

Materials have a range of durabilities Depending on the size of the production run and the

abrasiveness of the powder a material with the appropriate wear resistance should be selected

Mold materials used include natural rubber neoprene urethane polyvinyl chloride butyl nitrile and silicone

(A)suggestions for mould are

(1) Disposable and reusable mould materials are recommended

Disposable mould materials are polystyrene- polyethylene which provide thin wall envelopes and prevent breakage of the given compact but the mould becomes expensive

Reusable materials are urethane silicone rubber neoprene natural rubber and provide (a) greater wall thickness of the envelope (b) good shape control but complex parts may break upon pressure release

(2) The mould material must be sufficiently flexible (high elastic deformation) with low permanent set to accommodate the volume changes during compaction

(3) It must have a sufficient hardness and high resistance to abrasive wear High hardness also means no penetration of the material between powder particles and hence a good surface finish of the compacted part But in case of too high a hardness compressibility is poor and intricate shapes are difficult to fabricate A hardness between 65 and 95 shore A is used depending on the powder material and part shape

(4) Flexible thin walled envelopes may deform when filled with powder and support must be provided to control the compact shape eg container with holes is used or use of fasteners is made Fig 1

(5) Auxiliary tooling elements are

(a) a vacuum fan behind the support to pull the elastic mould exactly in place during filling For mixed mould processing the same action can be carried out by a reversed pumping action on the pressure medium

(b) a vacuum fan as reversed pumping can also be used to open up the mould for stripping compacted parts

(c) a vacuum connection to the filled area to de-air the filled mould before the compacting operation

(d) sealing support and clamping elements are also used

If internal shapes or cavities are desired in the compacted part a rigid mandrel can be used in the tooling

The mandrel usually is made of hardenable steel It should have a very smooth surface finish to encourage part release Complex shapes with reasonable tolerances can be achieved with the use of a mandrel

B) Suggestions for Equipment are as under1) Direct and indirect compression devices are used2) Pressure vessel material recommended is forged

medium carbon steel alloyed and heat treated3) Pressure vessels which have cover plates both on

top and on the bottom of the mould may be used so that the powder can be introduced at the top and the compact ejected at the bottom

4) Specialized equipment - the ROTOPRESS - 10 to 15 pieces per minute production units presently are being designed with 150 cm dia and maximum pressure 2000-3000 atmospheres or 60 cm dia and maximum pressure 10000 - 25000 atmospheres

5) Through the use of automated equipment it is possible to achieve

(a) careful processing (including particle size control)

(b) avoid contamination of the powders

(c) maintain uniform temperature of the pressurizing liquid and of the powders

(d) control of humidity of powders pressure and compacting time and

(e) ultimate excellent dimensional control

Applications of Cold Isostatic Compaction These include

(i) Titanium eg hydraulic aircraft fittings using Ti powder and Al-V master alloy powder

(ii) High-speed tool steels (eg cutting tools)

(iii) Compacts with interior threads

(iv) Long hollow cylindrical filters (stainless steel and titanium powder)

(v) Large shapes from tungsten powder such as rocket nozzle

(vi) Tungsten and molybdenum blooms or slabs for further forging andor rolling

Cross-section of Molding Bag

Body Armor

Bag and Molding Core Pin

Bag and Pressing Mandrel

A Sample of Bags

Cross-section of Bag

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
  • Slide 3
  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
  • Slide 6
  • Slide 7
  • Slide 8
  • Slide 9
  • Slide 10
  • Slide 11
  • Slide 12
  • Slide 13
  • a) Powder fill by weight or volume b) Filling of the mould from the top
  • Slide 15
  • Slide 16
  • Slide 17
  • Slide 18
  • Slide 19
  • Slide 20
  • Slide 21
  • Slide 22
  • Slide 23
  • Slide 24
  • Slide 25
  • Slide 26
  • Slide 27
  • Slide 28
  • Slide 29
  • Slide 30
  • Slide 31
  • Slide 32
  • Slide 33
  • Slide 34
  • Slide 35
  • Slide 36
  • Slide 37
  • Tubes Made by Isostatic Pressing 1048698Isopressing Mold and Mandrel
  • Slide 39
Page 14: ISOSTATIC PRESSING

c) Top lid put on the mould container

d) Mould is placed inside the pressure vessel

e) Top lid put on the pressure vessel after necessary evacuation and filling with the pressurizing medium

f) Top lid removed after required isostatic compaction for removal of the mould

(b) fixed mould or dry bag process (Figure 3) which is characterized by

(i) envelope is permanently fixed into the pressure vessel

(ii) After the elastomeric mold is filled with powder pressure is applied by introducing pressurized oil between the fixed mold and the vessel wall

(iii) only one compact at a time is used

(iv) more simple shapes are made and

(v) more suited for mass production and faster production rates

Fig3 Schematic of equipment for dry-bag isostatic pressing

Pressure Generators

bull Pressure is generated in the pressure medium through the use of air-driven and hydraulically driven pumps and pressure intensifiers bull The pressure medium typically is oil for dry bag processes water containing additives (water-soluble oil or rust inhibitors) is used for wet bag processes A filtering system should be included with all systems to protect the pressure-generating equipment from particulate contamination

bullDepressurization Systems Depressurization can be accomplished with a single metering valve

Tooling for Isostatic Compacting

Cold isostatic pressing tooling is composed of two partsmdashthe elastomeric mold or bag and a mandrel

Elastomeric molds are made of a variety of materials some are flexible while others are fairly rigid

An outside fixture to hold the loaded form is required if the mold is exceptionally flexible

A number of factors must be considered in the selection of a mold material

Primarily the mold material must not interact with either the powder or the pressure medium

Materials have a range of durabilities Depending on the size of the production run and the

abrasiveness of the powder a material with the appropriate wear resistance should be selected

Mold materials used include natural rubber neoprene urethane polyvinyl chloride butyl nitrile and silicone

(A)suggestions for mould are

(1) Disposable and reusable mould materials are recommended

Disposable mould materials are polystyrene- polyethylene which provide thin wall envelopes and prevent breakage of the given compact but the mould becomes expensive

Reusable materials are urethane silicone rubber neoprene natural rubber and provide (a) greater wall thickness of the envelope (b) good shape control but complex parts may break upon pressure release

(2) The mould material must be sufficiently flexible (high elastic deformation) with low permanent set to accommodate the volume changes during compaction

(3) It must have a sufficient hardness and high resistance to abrasive wear High hardness also means no penetration of the material between powder particles and hence a good surface finish of the compacted part But in case of too high a hardness compressibility is poor and intricate shapes are difficult to fabricate A hardness between 65 and 95 shore A is used depending on the powder material and part shape

(4) Flexible thin walled envelopes may deform when filled with powder and support must be provided to control the compact shape eg container with holes is used or use of fasteners is made Fig 1

(5) Auxiliary tooling elements are

(a) a vacuum fan behind the support to pull the elastic mould exactly in place during filling For mixed mould processing the same action can be carried out by a reversed pumping action on the pressure medium

(b) a vacuum fan as reversed pumping can also be used to open up the mould for stripping compacted parts

(c) a vacuum connection to the filled area to de-air the filled mould before the compacting operation

(d) sealing support and clamping elements are also used

If internal shapes or cavities are desired in the compacted part a rigid mandrel can be used in the tooling

The mandrel usually is made of hardenable steel It should have a very smooth surface finish to encourage part release Complex shapes with reasonable tolerances can be achieved with the use of a mandrel

B) Suggestions for Equipment are as under1) Direct and indirect compression devices are used2) Pressure vessel material recommended is forged

medium carbon steel alloyed and heat treated3) Pressure vessels which have cover plates both on

top and on the bottom of the mould may be used so that the powder can be introduced at the top and the compact ejected at the bottom

4) Specialized equipment - the ROTOPRESS - 10 to 15 pieces per minute production units presently are being designed with 150 cm dia and maximum pressure 2000-3000 atmospheres or 60 cm dia and maximum pressure 10000 - 25000 atmospheres

5) Through the use of automated equipment it is possible to achieve

(a) careful processing (including particle size control)

(b) avoid contamination of the powders

(c) maintain uniform temperature of the pressurizing liquid and of the powders

(d) control of humidity of powders pressure and compacting time and

(e) ultimate excellent dimensional control

Applications of Cold Isostatic Compaction These include

(i) Titanium eg hydraulic aircraft fittings using Ti powder and Al-V master alloy powder

(ii) High-speed tool steels (eg cutting tools)

(iii) Compacts with interior threads

(iv) Long hollow cylindrical filters (stainless steel and titanium powder)

(v) Large shapes from tungsten powder such as rocket nozzle

(vi) Tungsten and molybdenum blooms or slabs for further forging andor rolling

Cross-section of Molding Bag

Body Armor

Bag and Molding Core Pin

Bag and Pressing Mandrel

A Sample of Bags

Cross-section of Bag

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
  • Slide 3
  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
  • Slide 6
  • Slide 7
  • Slide 8
  • Slide 9
  • Slide 10
  • Slide 11
  • Slide 12
  • Slide 13
  • a) Powder fill by weight or volume b) Filling of the mould from the top
  • Slide 15
  • Slide 16
  • Slide 17
  • Slide 18
  • Slide 19
  • Slide 20
  • Slide 21
  • Slide 22
  • Slide 23
  • Slide 24
  • Slide 25
  • Slide 26
  • Slide 27
  • Slide 28
  • Slide 29
  • Slide 30
  • Slide 31
  • Slide 32
  • Slide 33
  • Slide 34
  • Slide 35
  • Slide 36
  • Slide 37
  • Tubes Made by Isostatic Pressing 1048698Isopressing Mold and Mandrel
  • Slide 39
Page 15: ISOSTATIC PRESSING

e) Top lid put on the pressure vessel after necessary evacuation and filling with the pressurizing medium

f) Top lid removed after required isostatic compaction for removal of the mould

(b) fixed mould or dry bag process (Figure 3) which is characterized by

(i) envelope is permanently fixed into the pressure vessel

(ii) After the elastomeric mold is filled with powder pressure is applied by introducing pressurized oil between the fixed mold and the vessel wall

(iii) only one compact at a time is used

(iv) more simple shapes are made and

(v) more suited for mass production and faster production rates

Fig3 Schematic of equipment for dry-bag isostatic pressing

Pressure Generators

bull Pressure is generated in the pressure medium through the use of air-driven and hydraulically driven pumps and pressure intensifiers bull The pressure medium typically is oil for dry bag processes water containing additives (water-soluble oil or rust inhibitors) is used for wet bag processes A filtering system should be included with all systems to protect the pressure-generating equipment from particulate contamination

bullDepressurization Systems Depressurization can be accomplished with a single metering valve

Tooling for Isostatic Compacting

Cold isostatic pressing tooling is composed of two partsmdashthe elastomeric mold or bag and a mandrel

Elastomeric molds are made of a variety of materials some are flexible while others are fairly rigid

An outside fixture to hold the loaded form is required if the mold is exceptionally flexible

A number of factors must be considered in the selection of a mold material

Primarily the mold material must not interact with either the powder or the pressure medium

Materials have a range of durabilities Depending on the size of the production run and the

abrasiveness of the powder a material with the appropriate wear resistance should be selected

Mold materials used include natural rubber neoprene urethane polyvinyl chloride butyl nitrile and silicone

(A)suggestions for mould are

(1) Disposable and reusable mould materials are recommended

Disposable mould materials are polystyrene- polyethylene which provide thin wall envelopes and prevent breakage of the given compact but the mould becomes expensive

Reusable materials are urethane silicone rubber neoprene natural rubber and provide (a) greater wall thickness of the envelope (b) good shape control but complex parts may break upon pressure release

(2) The mould material must be sufficiently flexible (high elastic deformation) with low permanent set to accommodate the volume changes during compaction

(3) It must have a sufficient hardness and high resistance to abrasive wear High hardness also means no penetration of the material between powder particles and hence a good surface finish of the compacted part But in case of too high a hardness compressibility is poor and intricate shapes are difficult to fabricate A hardness between 65 and 95 shore A is used depending on the powder material and part shape

(4) Flexible thin walled envelopes may deform when filled with powder and support must be provided to control the compact shape eg container with holes is used or use of fasteners is made Fig 1

(5) Auxiliary tooling elements are

(a) a vacuum fan behind the support to pull the elastic mould exactly in place during filling For mixed mould processing the same action can be carried out by a reversed pumping action on the pressure medium

(b) a vacuum fan as reversed pumping can also be used to open up the mould for stripping compacted parts

(c) a vacuum connection to the filled area to de-air the filled mould before the compacting operation

(d) sealing support and clamping elements are also used

If internal shapes or cavities are desired in the compacted part a rigid mandrel can be used in the tooling

The mandrel usually is made of hardenable steel It should have a very smooth surface finish to encourage part release Complex shapes with reasonable tolerances can be achieved with the use of a mandrel

B) Suggestions for Equipment are as under1) Direct and indirect compression devices are used2) Pressure vessel material recommended is forged

medium carbon steel alloyed and heat treated3) Pressure vessels which have cover plates both on

top and on the bottom of the mould may be used so that the powder can be introduced at the top and the compact ejected at the bottom

4) Specialized equipment - the ROTOPRESS - 10 to 15 pieces per minute production units presently are being designed with 150 cm dia and maximum pressure 2000-3000 atmospheres or 60 cm dia and maximum pressure 10000 - 25000 atmospheres

5) Through the use of automated equipment it is possible to achieve

(a) careful processing (including particle size control)

(b) avoid contamination of the powders

(c) maintain uniform temperature of the pressurizing liquid and of the powders

(d) control of humidity of powders pressure and compacting time and

(e) ultimate excellent dimensional control

Applications of Cold Isostatic Compaction These include

(i) Titanium eg hydraulic aircraft fittings using Ti powder and Al-V master alloy powder

(ii) High-speed tool steels (eg cutting tools)

(iii) Compacts with interior threads

(iv) Long hollow cylindrical filters (stainless steel and titanium powder)

(v) Large shapes from tungsten powder such as rocket nozzle

(vi) Tungsten and molybdenum blooms or slabs for further forging andor rolling

Cross-section of Molding Bag

Body Armor

Bag and Molding Core Pin

Bag and Pressing Mandrel

A Sample of Bags

Cross-section of Bag

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
  • Slide 3
  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
  • Slide 6
  • Slide 7
  • Slide 8
  • Slide 9
  • Slide 10
  • Slide 11
  • Slide 12
  • Slide 13
  • a) Powder fill by weight or volume b) Filling of the mould from the top
  • Slide 15
  • Slide 16
  • Slide 17
  • Slide 18
  • Slide 19
  • Slide 20
  • Slide 21
  • Slide 22
  • Slide 23
  • Slide 24
  • Slide 25
  • Slide 26
  • Slide 27
  • Slide 28
  • Slide 29
  • Slide 30
  • Slide 31
  • Slide 32
  • Slide 33
  • Slide 34
  • Slide 35
  • Slide 36
  • Slide 37
  • Tubes Made by Isostatic Pressing 1048698Isopressing Mold and Mandrel
  • Slide 39
Page 16: ISOSTATIC PRESSING

(b) fixed mould or dry bag process (Figure 3) which is characterized by

(i) envelope is permanently fixed into the pressure vessel

(ii) After the elastomeric mold is filled with powder pressure is applied by introducing pressurized oil between the fixed mold and the vessel wall

(iii) only one compact at a time is used

(iv) more simple shapes are made and

(v) more suited for mass production and faster production rates

Fig3 Schematic of equipment for dry-bag isostatic pressing

Pressure Generators

bull Pressure is generated in the pressure medium through the use of air-driven and hydraulically driven pumps and pressure intensifiers bull The pressure medium typically is oil for dry bag processes water containing additives (water-soluble oil or rust inhibitors) is used for wet bag processes A filtering system should be included with all systems to protect the pressure-generating equipment from particulate contamination

bullDepressurization Systems Depressurization can be accomplished with a single metering valve

Tooling for Isostatic Compacting

Cold isostatic pressing tooling is composed of two partsmdashthe elastomeric mold or bag and a mandrel

Elastomeric molds are made of a variety of materials some are flexible while others are fairly rigid

An outside fixture to hold the loaded form is required if the mold is exceptionally flexible

A number of factors must be considered in the selection of a mold material

Primarily the mold material must not interact with either the powder or the pressure medium

Materials have a range of durabilities Depending on the size of the production run and the

abrasiveness of the powder a material with the appropriate wear resistance should be selected

Mold materials used include natural rubber neoprene urethane polyvinyl chloride butyl nitrile and silicone

(A)suggestions for mould are

(1) Disposable and reusable mould materials are recommended

Disposable mould materials are polystyrene- polyethylene which provide thin wall envelopes and prevent breakage of the given compact but the mould becomes expensive

Reusable materials are urethane silicone rubber neoprene natural rubber and provide (a) greater wall thickness of the envelope (b) good shape control but complex parts may break upon pressure release

(2) The mould material must be sufficiently flexible (high elastic deformation) with low permanent set to accommodate the volume changes during compaction

(3) It must have a sufficient hardness and high resistance to abrasive wear High hardness also means no penetration of the material between powder particles and hence a good surface finish of the compacted part But in case of too high a hardness compressibility is poor and intricate shapes are difficult to fabricate A hardness between 65 and 95 shore A is used depending on the powder material and part shape

(4) Flexible thin walled envelopes may deform when filled with powder and support must be provided to control the compact shape eg container with holes is used or use of fasteners is made Fig 1

(5) Auxiliary tooling elements are

(a) a vacuum fan behind the support to pull the elastic mould exactly in place during filling For mixed mould processing the same action can be carried out by a reversed pumping action on the pressure medium

(b) a vacuum fan as reversed pumping can also be used to open up the mould for stripping compacted parts

(c) a vacuum connection to the filled area to de-air the filled mould before the compacting operation

(d) sealing support and clamping elements are also used

If internal shapes or cavities are desired in the compacted part a rigid mandrel can be used in the tooling

The mandrel usually is made of hardenable steel It should have a very smooth surface finish to encourage part release Complex shapes with reasonable tolerances can be achieved with the use of a mandrel

B) Suggestions for Equipment are as under1) Direct and indirect compression devices are used2) Pressure vessel material recommended is forged

medium carbon steel alloyed and heat treated3) Pressure vessels which have cover plates both on

top and on the bottom of the mould may be used so that the powder can be introduced at the top and the compact ejected at the bottom

4) Specialized equipment - the ROTOPRESS - 10 to 15 pieces per minute production units presently are being designed with 150 cm dia and maximum pressure 2000-3000 atmospheres or 60 cm dia and maximum pressure 10000 - 25000 atmospheres

5) Through the use of automated equipment it is possible to achieve

(a) careful processing (including particle size control)

(b) avoid contamination of the powders

(c) maintain uniform temperature of the pressurizing liquid and of the powders

(d) control of humidity of powders pressure and compacting time and

(e) ultimate excellent dimensional control

Applications of Cold Isostatic Compaction These include

(i) Titanium eg hydraulic aircraft fittings using Ti powder and Al-V master alloy powder

(ii) High-speed tool steels (eg cutting tools)

(iii) Compacts with interior threads

(iv) Long hollow cylindrical filters (stainless steel and titanium powder)

(v) Large shapes from tungsten powder such as rocket nozzle

(vi) Tungsten and molybdenum blooms or slabs for further forging andor rolling

Cross-section of Molding Bag

Body Armor

Bag and Molding Core Pin

Bag and Pressing Mandrel

A Sample of Bags

Cross-section of Bag

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
  • Slide 3
  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
  • Slide 6
  • Slide 7
  • Slide 8
  • Slide 9
  • Slide 10
  • Slide 11
  • Slide 12
  • Slide 13
  • a) Powder fill by weight or volume b) Filling of the mould from the top
  • Slide 15
  • Slide 16
  • Slide 17
  • Slide 18
  • Slide 19
  • Slide 20
  • Slide 21
  • Slide 22
  • Slide 23
  • Slide 24
  • Slide 25
  • Slide 26
  • Slide 27
  • Slide 28
  • Slide 29
  • Slide 30
  • Slide 31
  • Slide 32
  • Slide 33
  • Slide 34
  • Slide 35
  • Slide 36
  • Slide 37
  • Tubes Made by Isostatic Pressing 1048698Isopressing Mold and Mandrel
  • Slide 39
Page 17: ISOSTATIC PRESSING

Fig3 Schematic of equipment for dry-bag isostatic pressing

Pressure Generators

bull Pressure is generated in the pressure medium through the use of air-driven and hydraulically driven pumps and pressure intensifiers bull The pressure medium typically is oil for dry bag processes water containing additives (water-soluble oil or rust inhibitors) is used for wet bag processes A filtering system should be included with all systems to protect the pressure-generating equipment from particulate contamination

bullDepressurization Systems Depressurization can be accomplished with a single metering valve

Tooling for Isostatic Compacting

Cold isostatic pressing tooling is composed of two partsmdashthe elastomeric mold or bag and a mandrel

Elastomeric molds are made of a variety of materials some are flexible while others are fairly rigid

An outside fixture to hold the loaded form is required if the mold is exceptionally flexible

A number of factors must be considered in the selection of a mold material

Primarily the mold material must not interact with either the powder or the pressure medium

Materials have a range of durabilities Depending on the size of the production run and the

abrasiveness of the powder a material with the appropriate wear resistance should be selected

Mold materials used include natural rubber neoprene urethane polyvinyl chloride butyl nitrile and silicone

(A)suggestions for mould are

(1) Disposable and reusable mould materials are recommended

Disposable mould materials are polystyrene- polyethylene which provide thin wall envelopes and prevent breakage of the given compact but the mould becomes expensive

Reusable materials are urethane silicone rubber neoprene natural rubber and provide (a) greater wall thickness of the envelope (b) good shape control but complex parts may break upon pressure release

(2) The mould material must be sufficiently flexible (high elastic deformation) with low permanent set to accommodate the volume changes during compaction

(3) It must have a sufficient hardness and high resistance to abrasive wear High hardness also means no penetration of the material between powder particles and hence a good surface finish of the compacted part But in case of too high a hardness compressibility is poor and intricate shapes are difficult to fabricate A hardness between 65 and 95 shore A is used depending on the powder material and part shape

(4) Flexible thin walled envelopes may deform when filled with powder and support must be provided to control the compact shape eg container with holes is used or use of fasteners is made Fig 1

(5) Auxiliary tooling elements are

(a) a vacuum fan behind the support to pull the elastic mould exactly in place during filling For mixed mould processing the same action can be carried out by a reversed pumping action on the pressure medium

(b) a vacuum fan as reversed pumping can also be used to open up the mould for stripping compacted parts

(c) a vacuum connection to the filled area to de-air the filled mould before the compacting operation

(d) sealing support and clamping elements are also used

If internal shapes or cavities are desired in the compacted part a rigid mandrel can be used in the tooling

The mandrel usually is made of hardenable steel It should have a very smooth surface finish to encourage part release Complex shapes with reasonable tolerances can be achieved with the use of a mandrel

B) Suggestions for Equipment are as under1) Direct and indirect compression devices are used2) Pressure vessel material recommended is forged

medium carbon steel alloyed and heat treated3) Pressure vessels which have cover plates both on

top and on the bottom of the mould may be used so that the powder can be introduced at the top and the compact ejected at the bottom

4) Specialized equipment - the ROTOPRESS - 10 to 15 pieces per minute production units presently are being designed with 150 cm dia and maximum pressure 2000-3000 atmospheres or 60 cm dia and maximum pressure 10000 - 25000 atmospheres

5) Through the use of automated equipment it is possible to achieve

(a) careful processing (including particle size control)

(b) avoid contamination of the powders

(c) maintain uniform temperature of the pressurizing liquid and of the powders

(d) control of humidity of powders pressure and compacting time and

(e) ultimate excellent dimensional control

Applications of Cold Isostatic Compaction These include

(i) Titanium eg hydraulic aircraft fittings using Ti powder and Al-V master alloy powder

(ii) High-speed tool steels (eg cutting tools)

(iii) Compacts with interior threads

(iv) Long hollow cylindrical filters (stainless steel and titanium powder)

(v) Large shapes from tungsten powder such as rocket nozzle

(vi) Tungsten and molybdenum blooms or slabs for further forging andor rolling

Cross-section of Molding Bag

Body Armor

Bag and Molding Core Pin

Bag and Pressing Mandrel

A Sample of Bags

Cross-section of Bag

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
  • Slide 3
  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
  • Slide 6
  • Slide 7
  • Slide 8
  • Slide 9
  • Slide 10
  • Slide 11
  • Slide 12
  • Slide 13
  • a) Powder fill by weight or volume b) Filling of the mould from the top
  • Slide 15
  • Slide 16
  • Slide 17
  • Slide 18
  • Slide 19
  • Slide 20
  • Slide 21
  • Slide 22
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  • Slide 37
  • Tubes Made by Isostatic Pressing 1048698Isopressing Mold and Mandrel
  • Slide 39
Page 18: ISOSTATIC PRESSING

Pressure Generators

bull Pressure is generated in the pressure medium through the use of air-driven and hydraulically driven pumps and pressure intensifiers bull The pressure medium typically is oil for dry bag processes water containing additives (water-soluble oil or rust inhibitors) is used for wet bag processes A filtering system should be included with all systems to protect the pressure-generating equipment from particulate contamination

bullDepressurization Systems Depressurization can be accomplished with a single metering valve

Tooling for Isostatic Compacting

Cold isostatic pressing tooling is composed of two partsmdashthe elastomeric mold or bag and a mandrel

Elastomeric molds are made of a variety of materials some are flexible while others are fairly rigid

An outside fixture to hold the loaded form is required if the mold is exceptionally flexible

A number of factors must be considered in the selection of a mold material

Primarily the mold material must not interact with either the powder or the pressure medium

Materials have a range of durabilities Depending on the size of the production run and the

abrasiveness of the powder a material with the appropriate wear resistance should be selected

Mold materials used include natural rubber neoprene urethane polyvinyl chloride butyl nitrile and silicone

(A)suggestions for mould are

(1) Disposable and reusable mould materials are recommended

Disposable mould materials are polystyrene- polyethylene which provide thin wall envelopes and prevent breakage of the given compact but the mould becomes expensive

Reusable materials are urethane silicone rubber neoprene natural rubber and provide (a) greater wall thickness of the envelope (b) good shape control but complex parts may break upon pressure release

(2) The mould material must be sufficiently flexible (high elastic deformation) with low permanent set to accommodate the volume changes during compaction

(3) It must have a sufficient hardness and high resistance to abrasive wear High hardness also means no penetration of the material between powder particles and hence a good surface finish of the compacted part But in case of too high a hardness compressibility is poor and intricate shapes are difficult to fabricate A hardness between 65 and 95 shore A is used depending on the powder material and part shape

(4) Flexible thin walled envelopes may deform when filled with powder and support must be provided to control the compact shape eg container with holes is used or use of fasteners is made Fig 1

(5) Auxiliary tooling elements are

(a) a vacuum fan behind the support to pull the elastic mould exactly in place during filling For mixed mould processing the same action can be carried out by a reversed pumping action on the pressure medium

(b) a vacuum fan as reversed pumping can also be used to open up the mould for stripping compacted parts

(c) a vacuum connection to the filled area to de-air the filled mould before the compacting operation

(d) sealing support and clamping elements are also used

If internal shapes or cavities are desired in the compacted part a rigid mandrel can be used in the tooling

The mandrel usually is made of hardenable steel It should have a very smooth surface finish to encourage part release Complex shapes with reasonable tolerances can be achieved with the use of a mandrel

B) Suggestions for Equipment are as under1) Direct and indirect compression devices are used2) Pressure vessel material recommended is forged

medium carbon steel alloyed and heat treated3) Pressure vessels which have cover plates both on

top and on the bottom of the mould may be used so that the powder can be introduced at the top and the compact ejected at the bottom

4) Specialized equipment - the ROTOPRESS - 10 to 15 pieces per minute production units presently are being designed with 150 cm dia and maximum pressure 2000-3000 atmospheres or 60 cm dia and maximum pressure 10000 - 25000 atmospheres

5) Through the use of automated equipment it is possible to achieve

(a) careful processing (including particle size control)

(b) avoid contamination of the powders

(c) maintain uniform temperature of the pressurizing liquid and of the powders

(d) control of humidity of powders pressure and compacting time and

(e) ultimate excellent dimensional control

Applications of Cold Isostatic Compaction These include

(i) Titanium eg hydraulic aircraft fittings using Ti powder and Al-V master alloy powder

(ii) High-speed tool steels (eg cutting tools)

(iii) Compacts with interior threads

(iv) Long hollow cylindrical filters (stainless steel and titanium powder)

(v) Large shapes from tungsten powder such as rocket nozzle

(vi) Tungsten and molybdenum blooms or slabs for further forging andor rolling

Cross-section of Molding Bag

Body Armor

Bag and Molding Core Pin

Bag and Pressing Mandrel

A Sample of Bags

Cross-section of Bag

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
  • Slide 3
  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
  • Slide 6
  • Slide 7
  • Slide 8
  • Slide 9
  • Slide 10
  • Slide 11
  • Slide 12
  • Slide 13
  • a) Powder fill by weight or volume b) Filling of the mould from the top
  • Slide 15
  • Slide 16
  • Slide 17
  • Slide 18
  • Slide 19
  • Slide 20
  • Slide 21
  • Slide 22
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  • Slide 30
  • Slide 31
  • Slide 32
  • Slide 33
  • Slide 34
  • Slide 35
  • Slide 36
  • Slide 37
  • Tubes Made by Isostatic Pressing 1048698Isopressing Mold and Mandrel
  • Slide 39
Page 19: ISOSTATIC PRESSING

Tooling for Isostatic Compacting

Cold isostatic pressing tooling is composed of two partsmdashthe elastomeric mold or bag and a mandrel

Elastomeric molds are made of a variety of materials some are flexible while others are fairly rigid

An outside fixture to hold the loaded form is required if the mold is exceptionally flexible

A number of factors must be considered in the selection of a mold material

Primarily the mold material must not interact with either the powder or the pressure medium

Materials have a range of durabilities Depending on the size of the production run and the

abrasiveness of the powder a material with the appropriate wear resistance should be selected

Mold materials used include natural rubber neoprene urethane polyvinyl chloride butyl nitrile and silicone

(A)suggestions for mould are

(1) Disposable and reusable mould materials are recommended

Disposable mould materials are polystyrene- polyethylene which provide thin wall envelopes and prevent breakage of the given compact but the mould becomes expensive

Reusable materials are urethane silicone rubber neoprene natural rubber and provide (a) greater wall thickness of the envelope (b) good shape control but complex parts may break upon pressure release

(2) The mould material must be sufficiently flexible (high elastic deformation) with low permanent set to accommodate the volume changes during compaction

(3) It must have a sufficient hardness and high resistance to abrasive wear High hardness also means no penetration of the material between powder particles and hence a good surface finish of the compacted part But in case of too high a hardness compressibility is poor and intricate shapes are difficult to fabricate A hardness between 65 and 95 shore A is used depending on the powder material and part shape

(4) Flexible thin walled envelopes may deform when filled with powder and support must be provided to control the compact shape eg container with holes is used or use of fasteners is made Fig 1

(5) Auxiliary tooling elements are

(a) a vacuum fan behind the support to pull the elastic mould exactly in place during filling For mixed mould processing the same action can be carried out by a reversed pumping action on the pressure medium

(b) a vacuum fan as reversed pumping can also be used to open up the mould for stripping compacted parts

(c) a vacuum connection to the filled area to de-air the filled mould before the compacting operation

(d) sealing support and clamping elements are also used

If internal shapes or cavities are desired in the compacted part a rigid mandrel can be used in the tooling

The mandrel usually is made of hardenable steel It should have a very smooth surface finish to encourage part release Complex shapes with reasonable tolerances can be achieved with the use of a mandrel

B) Suggestions for Equipment are as under1) Direct and indirect compression devices are used2) Pressure vessel material recommended is forged

medium carbon steel alloyed and heat treated3) Pressure vessels which have cover plates both on

top and on the bottom of the mould may be used so that the powder can be introduced at the top and the compact ejected at the bottom

4) Specialized equipment - the ROTOPRESS - 10 to 15 pieces per minute production units presently are being designed with 150 cm dia and maximum pressure 2000-3000 atmospheres or 60 cm dia and maximum pressure 10000 - 25000 atmospheres

5) Through the use of automated equipment it is possible to achieve

(a) careful processing (including particle size control)

(b) avoid contamination of the powders

(c) maintain uniform temperature of the pressurizing liquid and of the powders

(d) control of humidity of powders pressure and compacting time and

(e) ultimate excellent dimensional control

Applications of Cold Isostatic Compaction These include

(i) Titanium eg hydraulic aircraft fittings using Ti powder and Al-V master alloy powder

(ii) High-speed tool steels (eg cutting tools)

(iii) Compacts with interior threads

(iv) Long hollow cylindrical filters (stainless steel and titanium powder)

(v) Large shapes from tungsten powder such as rocket nozzle

(vi) Tungsten and molybdenum blooms or slabs for further forging andor rolling

Cross-section of Molding Bag

Body Armor

Bag and Molding Core Pin

Bag and Pressing Mandrel

A Sample of Bags

Cross-section of Bag

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
  • Slide 3
  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
  • Slide 6
  • Slide 7
  • Slide 8
  • Slide 9
  • Slide 10
  • Slide 11
  • Slide 12
  • Slide 13
  • a) Powder fill by weight or volume b) Filling of the mould from the top
  • Slide 15
  • Slide 16
  • Slide 17
  • Slide 18
  • Slide 19
  • Slide 20
  • Slide 21
  • Slide 22
  • Slide 23
  • Slide 24
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  • Slide 31
  • Slide 32
  • Slide 33
  • Slide 34
  • Slide 35
  • Slide 36
  • Slide 37
  • Tubes Made by Isostatic Pressing 1048698Isopressing Mold and Mandrel
  • Slide 39
Page 20: ISOSTATIC PRESSING

Materials have a range of durabilities Depending on the size of the production run and the

abrasiveness of the powder a material with the appropriate wear resistance should be selected

Mold materials used include natural rubber neoprene urethane polyvinyl chloride butyl nitrile and silicone

(A)suggestions for mould are

(1) Disposable and reusable mould materials are recommended

Disposable mould materials are polystyrene- polyethylene which provide thin wall envelopes and prevent breakage of the given compact but the mould becomes expensive

Reusable materials are urethane silicone rubber neoprene natural rubber and provide (a) greater wall thickness of the envelope (b) good shape control but complex parts may break upon pressure release

(2) The mould material must be sufficiently flexible (high elastic deformation) with low permanent set to accommodate the volume changes during compaction

(3) It must have a sufficient hardness and high resistance to abrasive wear High hardness also means no penetration of the material between powder particles and hence a good surface finish of the compacted part But in case of too high a hardness compressibility is poor and intricate shapes are difficult to fabricate A hardness between 65 and 95 shore A is used depending on the powder material and part shape

(4) Flexible thin walled envelopes may deform when filled with powder and support must be provided to control the compact shape eg container with holes is used or use of fasteners is made Fig 1

(5) Auxiliary tooling elements are

(a) a vacuum fan behind the support to pull the elastic mould exactly in place during filling For mixed mould processing the same action can be carried out by a reversed pumping action on the pressure medium

(b) a vacuum fan as reversed pumping can also be used to open up the mould for stripping compacted parts

(c) a vacuum connection to the filled area to de-air the filled mould before the compacting operation

(d) sealing support and clamping elements are also used

If internal shapes or cavities are desired in the compacted part a rigid mandrel can be used in the tooling

The mandrel usually is made of hardenable steel It should have a very smooth surface finish to encourage part release Complex shapes with reasonable tolerances can be achieved with the use of a mandrel

B) Suggestions for Equipment are as under1) Direct and indirect compression devices are used2) Pressure vessel material recommended is forged

medium carbon steel alloyed and heat treated3) Pressure vessels which have cover plates both on

top and on the bottom of the mould may be used so that the powder can be introduced at the top and the compact ejected at the bottom

4) Specialized equipment - the ROTOPRESS - 10 to 15 pieces per minute production units presently are being designed with 150 cm dia and maximum pressure 2000-3000 atmospheres or 60 cm dia and maximum pressure 10000 - 25000 atmospheres

5) Through the use of automated equipment it is possible to achieve

(a) careful processing (including particle size control)

(b) avoid contamination of the powders

(c) maintain uniform temperature of the pressurizing liquid and of the powders

(d) control of humidity of powders pressure and compacting time and

(e) ultimate excellent dimensional control

Applications of Cold Isostatic Compaction These include

(i) Titanium eg hydraulic aircraft fittings using Ti powder and Al-V master alloy powder

(ii) High-speed tool steels (eg cutting tools)

(iii) Compacts with interior threads

(iv) Long hollow cylindrical filters (stainless steel and titanium powder)

(v) Large shapes from tungsten powder such as rocket nozzle

(vi) Tungsten and molybdenum blooms or slabs for further forging andor rolling

Cross-section of Molding Bag

Body Armor

Bag and Molding Core Pin

Bag and Pressing Mandrel

A Sample of Bags

Cross-section of Bag

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
  • Slide 3
  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
  • Slide 6
  • Slide 7
  • Slide 8
  • Slide 9
  • Slide 10
  • Slide 11
  • Slide 12
  • Slide 13
  • a) Powder fill by weight or volume b) Filling of the mould from the top
  • Slide 15
  • Slide 16
  • Slide 17
  • Slide 18
  • Slide 19
  • Slide 20
  • Slide 21
  • Slide 22
  • Slide 23
  • Slide 24
  • Slide 25
  • Slide 26
  • Slide 27
  • Slide 28
  • Slide 29
  • Slide 30
  • Slide 31
  • Slide 32
  • Slide 33
  • Slide 34
  • Slide 35
  • Slide 36
  • Slide 37
  • Tubes Made by Isostatic Pressing 1048698Isopressing Mold and Mandrel
  • Slide 39
Page 21: ISOSTATIC PRESSING

(A)suggestions for mould are

(1) Disposable and reusable mould materials are recommended

Disposable mould materials are polystyrene- polyethylene which provide thin wall envelopes and prevent breakage of the given compact but the mould becomes expensive

Reusable materials are urethane silicone rubber neoprene natural rubber and provide (a) greater wall thickness of the envelope (b) good shape control but complex parts may break upon pressure release

(2) The mould material must be sufficiently flexible (high elastic deformation) with low permanent set to accommodate the volume changes during compaction

(3) It must have a sufficient hardness and high resistance to abrasive wear High hardness also means no penetration of the material between powder particles and hence a good surface finish of the compacted part But in case of too high a hardness compressibility is poor and intricate shapes are difficult to fabricate A hardness between 65 and 95 shore A is used depending on the powder material and part shape

(4) Flexible thin walled envelopes may deform when filled with powder and support must be provided to control the compact shape eg container with holes is used or use of fasteners is made Fig 1

(5) Auxiliary tooling elements are

(a) a vacuum fan behind the support to pull the elastic mould exactly in place during filling For mixed mould processing the same action can be carried out by a reversed pumping action on the pressure medium

(b) a vacuum fan as reversed pumping can also be used to open up the mould for stripping compacted parts

(c) a vacuum connection to the filled area to de-air the filled mould before the compacting operation

(d) sealing support and clamping elements are also used

If internal shapes or cavities are desired in the compacted part a rigid mandrel can be used in the tooling

The mandrel usually is made of hardenable steel It should have a very smooth surface finish to encourage part release Complex shapes with reasonable tolerances can be achieved with the use of a mandrel

B) Suggestions for Equipment are as under1) Direct and indirect compression devices are used2) Pressure vessel material recommended is forged

medium carbon steel alloyed and heat treated3) Pressure vessels which have cover plates both on

top and on the bottom of the mould may be used so that the powder can be introduced at the top and the compact ejected at the bottom

4) Specialized equipment - the ROTOPRESS - 10 to 15 pieces per minute production units presently are being designed with 150 cm dia and maximum pressure 2000-3000 atmospheres or 60 cm dia and maximum pressure 10000 - 25000 atmospheres

5) Through the use of automated equipment it is possible to achieve

(a) careful processing (including particle size control)

(b) avoid contamination of the powders

(c) maintain uniform temperature of the pressurizing liquid and of the powders

(d) control of humidity of powders pressure and compacting time and

(e) ultimate excellent dimensional control

Applications of Cold Isostatic Compaction These include

(i) Titanium eg hydraulic aircraft fittings using Ti powder and Al-V master alloy powder

(ii) High-speed tool steels (eg cutting tools)

(iii) Compacts with interior threads

(iv) Long hollow cylindrical filters (stainless steel and titanium powder)

(v) Large shapes from tungsten powder such as rocket nozzle

(vi) Tungsten and molybdenum blooms or slabs for further forging andor rolling

Cross-section of Molding Bag

Body Armor

Bag and Molding Core Pin

Bag and Pressing Mandrel

A Sample of Bags

Cross-section of Bag

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
  • Slide 3
  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
  • Slide 6
  • Slide 7
  • Slide 8
  • Slide 9
  • Slide 10
  • Slide 11
  • Slide 12
  • Slide 13
  • a) Powder fill by weight or volume b) Filling of the mould from the top
  • Slide 15
  • Slide 16
  • Slide 17
  • Slide 18
  • Slide 19
  • Slide 20
  • Slide 21
  • Slide 22
  • Slide 23
  • Slide 24
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  • Slide 31
  • Slide 32
  • Slide 33
  • Slide 34
  • Slide 35
  • Slide 36
  • Slide 37
  • Tubes Made by Isostatic Pressing 1048698Isopressing Mold and Mandrel
  • Slide 39
Page 22: ISOSTATIC PRESSING

(3) It must have a sufficient hardness and high resistance to abrasive wear High hardness also means no penetration of the material between powder particles and hence a good surface finish of the compacted part But in case of too high a hardness compressibility is poor and intricate shapes are difficult to fabricate A hardness between 65 and 95 shore A is used depending on the powder material and part shape

(4) Flexible thin walled envelopes may deform when filled with powder and support must be provided to control the compact shape eg container with holes is used or use of fasteners is made Fig 1

(5) Auxiliary tooling elements are

(a) a vacuum fan behind the support to pull the elastic mould exactly in place during filling For mixed mould processing the same action can be carried out by a reversed pumping action on the pressure medium

(b) a vacuum fan as reversed pumping can also be used to open up the mould for stripping compacted parts

(c) a vacuum connection to the filled area to de-air the filled mould before the compacting operation

(d) sealing support and clamping elements are also used

If internal shapes or cavities are desired in the compacted part a rigid mandrel can be used in the tooling

The mandrel usually is made of hardenable steel It should have a very smooth surface finish to encourage part release Complex shapes with reasonable tolerances can be achieved with the use of a mandrel

B) Suggestions for Equipment are as under1) Direct and indirect compression devices are used2) Pressure vessel material recommended is forged

medium carbon steel alloyed and heat treated3) Pressure vessels which have cover plates both on

top and on the bottom of the mould may be used so that the powder can be introduced at the top and the compact ejected at the bottom

4) Specialized equipment - the ROTOPRESS - 10 to 15 pieces per minute production units presently are being designed with 150 cm dia and maximum pressure 2000-3000 atmospheres or 60 cm dia and maximum pressure 10000 - 25000 atmospheres

5) Through the use of automated equipment it is possible to achieve

(a) careful processing (including particle size control)

(b) avoid contamination of the powders

(c) maintain uniform temperature of the pressurizing liquid and of the powders

(d) control of humidity of powders pressure and compacting time and

(e) ultimate excellent dimensional control

Applications of Cold Isostatic Compaction These include

(i) Titanium eg hydraulic aircraft fittings using Ti powder and Al-V master alloy powder

(ii) High-speed tool steels (eg cutting tools)

(iii) Compacts with interior threads

(iv) Long hollow cylindrical filters (stainless steel and titanium powder)

(v) Large shapes from tungsten powder such as rocket nozzle

(vi) Tungsten and molybdenum blooms or slabs for further forging andor rolling

Cross-section of Molding Bag

Body Armor

Bag and Molding Core Pin

Bag and Pressing Mandrel

A Sample of Bags

Cross-section of Bag

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
  • Slide 3
  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
  • Slide 6
  • Slide 7
  • Slide 8
  • Slide 9
  • Slide 10
  • Slide 11
  • Slide 12
  • Slide 13
  • a) Powder fill by weight or volume b) Filling of the mould from the top
  • Slide 15
  • Slide 16
  • Slide 17
  • Slide 18
  • Slide 19
  • Slide 20
  • Slide 21
  • Slide 22
  • Slide 23
  • Slide 24
  • Slide 25
  • Slide 26
  • Slide 27
  • Slide 28
  • Slide 29
  • Slide 30
  • Slide 31
  • Slide 32
  • Slide 33
  • Slide 34
  • Slide 35
  • Slide 36
  • Slide 37
  • Tubes Made by Isostatic Pressing 1048698Isopressing Mold and Mandrel
  • Slide 39
Page 23: ISOSTATIC PRESSING

(5) Auxiliary tooling elements are

(a) a vacuum fan behind the support to pull the elastic mould exactly in place during filling For mixed mould processing the same action can be carried out by a reversed pumping action on the pressure medium

(b) a vacuum fan as reversed pumping can also be used to open up the mould for stripping compacted parts

(c) a vacuum connection to the filled area to de-air the filled mould before the compacting operation

(d) sealing support and clamping elements are also used

If internal shapes or cavities are desired in the compacted part a rigid mandrel can be used in the tooling

The mandrel usually is made of hardenable steel It should have a very smooth surface finish to encourage part release Complex shapes with reasonable tolerances can be achieved with the use of a mandrel

B) Suggestions for Equipment are as under1) Direct and indirect compression devices are used2) Pressure vessel material recommended is forged

medium carbon steel alloyed and heat treated3) Pressure vessels which have cover plates both on

top and on the bottom of the mould may be used so that the powder can be introduced at the top and the compact ejected at the bottom

4) Specialized equipment - the ROTOPRESS - 10 to 15 pieces per minute production units presently are being designed with 150 cm dia and maximum pressure 2000-3000 atmospheres or 60 cm dia and maximum pressure 10000 - 25000 atmospheres

5) Through the use of automated equipment it is possible to achieve

(a) careful processing (including particle size control)

(b) avoid contamination of the powders

(c) maintain uniform temperature of the pressurizing liquid and of the powders

(d) control of humidity of powders pressure and compacting time and

(e) ultimate excellent dimensional control

Applications of Cold Isostatic Compaction These include

(i) Titanium eg hydraulic aircraft fittings using Ti powder and Al-V master alloy powder

(ii) High-speed tool steels (eg cutting tools)

(iii) Compacts with interior threads

(iv) Long hollow cylindrical filters (stainless steel and titanium powder)

(v) Large shapes from tungsten powder such as rocket nozzle

(vi) Tungsten and molybdenum blooms or slabs for further forging andor rolling

Cross-section of Molding Bag

Body Armor

Bag and Molding Core Pin

Bag and Pressing Mandrel

A Sample of Bags

Cross-section of Bag

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
  • Slide 3
  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
  • Slide 6
  • Slide 7
  • Slide 8
  • Slide 9
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  • a) Powder fill by weight or volume b) Filling of the mould from the top
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If internal shapes or cavities are desired in the compacted part a rigid mandrel can be used in the tooling

The mandrel usually is made of hardenable steel It should have a very smooth surface finish to encourage part release Complex shapes with reasonable tolerances can be achieved with the use of a mandrel

B) Suggestions for Equipment are as under1) Direct and indirect compression devices are used2) Pressure vessel material recommended is forged

medium carbon steel alloyed and heat treated3) Pressure vessels which have cover plates both on

top and on the bottom of the mould may be used so that the powder can be introduced at the top and the compact ejected at the bottom

4) Specialized equipment - the ROTOPRESS - 10 to 15 pieces per minute production units presently are being designed with 150 cm dia and maximum pressure 2000-3000 atmospheres or 60 cm dia and maximum pressure 10000 - 25000 atmospheres

5) Through the use of automated equipment it is possible to achieve

(a) careful processing (including particle size control)

(b) avoid contamination of the powders

(c) maintain uniform temperature of the pressurizing liquid and of the powders

(d) control of humidity of powders pressure and compacting time and

(e) ultimate excellent dimensional control

Applications of Cold Isostatic Compaction These include

(i) Titanium eg hydraulic aircraft fittings using Ti powder and Al-V master alloy powder

(ii) High-speed tool steels (eg cutting tools)

(iii) Compacts with interior threads

(iv) Long hollow cylindrical filters (stainless steel and titanium powder)

(v) Large shapes from tungsten powder such as rocket nozzle

(vi) Tungsten and molybdenum blooms or slabs for further forging andor rolling

Cross-section of Molding Bag

Body Armor

Bag and Molding Core Pin

Bag and Pressing Mandrel

A Sample of Bags

Cross-section of Bag

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
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  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
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Page 25: ISOSTATIC PRESSING

B) Suggestions for Equipment are as under1) Direct and indirect compression devices are used2) Pressure vessel material recommended is forged

medium carbon steel alloyed and heat treated3) Pressure vessels which have cover plates both on

top and on the bottom of the mould may be used so that the powder can be introduced at the top and the compact ejected at the bottom

4) Specialized equipment - the ROTOPRESS - 10 to 15 pieces per minute production units presently are being designed with 150 cm dia and maximum pressure 2000-3000 atmospheres or 60 cm dia and maximum pressure 10000 - 25000 atmospheres

5) Through the use of automated equipment it is possible to achieve

(a) careful processing (including particle size control)

(b) avoid contamination of the powders

(c) maintain uniform temperature of the pressurizing liquid and of the powders

(d) control of humidity of powders pressure and compacting time and

(e) ultimate excellent dimensional control

Applications of Cold Isostatic Compaction These include

(i) Titanium eg hydraulic aircraft fittings using Ti powder and Al-V master alloy powder

(ii) High-speed tool steels (eg cutting tools)

(iii) Compacts with interior threads

(iv) Long hollow cylindrical filters (stainless steel and titanium powder)

(v) Large shapes from tungsten powder such as rocket nozzle

(vi) Tungsten and molybdenum blooms or slabs for further forging andor rolling

Cross-section of Molding Bag

Body Armor

Bag and Molding Core Pin

Bag and Pressing Mandrel

A Sample of Bags

Cross-section of Bag

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
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  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
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  • a) Powder fill by weight or volume b) Filling of the mould from the top
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Page 26: ISOSTATIC PRESSING

5) Through the use of automated equipment it is possible to achieve

(a) careful processing (including particle size control)

(b) avoid contamination of the powders

(c) maintain uniform temperature of the pressurizing liquid and of the powders

(d) control of humidity of powders pressure and compacting time and

(e) ultimate excellent dimensional control

Applications of Cold Isostatic Compaction These include

(i) Titanium eg hydraulic aircraft fittings using Ti powder and Al-V master alloy powder

(ii) High-speed tool steels (eg cutting tools)

(iii) Compacts with interior threads

(iv) Long hollow cylindrical filters (stainless steel and titanium powder)

(v) Large shapes from tungsten powder such as rocket nozzle

(vi) Tungsten and molybdenum blooms or slabs for further forging andor rolling

Cross-section of Molding Bag

Body Armor

Bag and Molding Core Pin

Bag and Pressing Mandrel

A Sample of Bags

Cross-section of Bag

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
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  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
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Page 27: ISOSTATIC PRESSING

Applications of Cold Isostatic Compaction These include

(i) Titanium eg hydraulic aircraft fittings using Ti powder and Al-V master alloy powder

(ii) High-speed tool steels (eg cutting tools)

(iii) Compacts with interior threads

(iv) Long hollow cylindrical filters (stainless steel and titanium powder)

(v) Large shapes from tungsten powder such as rocket nozzle

(vi) Tungsten and molybdenum blooms or slabs for further forging andor rolling

Cross-section of Molding Bag

Body Armor

Bag and Molding Core Pin

Bag and Pressing Mandrel

A Sample of Bags

Cross-section of Bag

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
  • Slide 3
  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
  • Slide 6
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  • a) Powder fill by weight or volume b) Filling of the mould from the top
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Page 28: ISOSTATIC PRESSING

Cross-section of Molding Bag

Body Armor

Bag and Molding Core Pin

Bag and Pressing Mandrel

A Sample of Bags

Cross-section of Bag

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
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  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
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  • a) Powder fill by weight or volume b) Filling of the mould from the top
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Page 29: ISOSTATIC PRESSING

Body Armor

Bag and Molding Core Pin

Bag and Pressing Mandrel

A Sample of Bags

Cross-section of Bag

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
  • Slide 3
  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
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  • a) Powder fill by weight or volume b) Filling of the mould from the top
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Page 30: ISOSTATIC PRESSING

Bag and Molding Core Pin

Bag and Pressing Mandrel

A Sample of Bags

Cross-section of Bag

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
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  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
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  • a) Powder fill by weight or volume b) Filling of the mould from the top
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Page 31: ISOSTATIC PRESSING

Bag and Pressing Mandrel

A Sample of Bags

Cross-section of Bag

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
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  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
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  • a) Powder fill by weight or volume b) Filling of the mould from the top
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Page 32: ISOSTATIC PRESSING

A Sample of Bags

Cross-section of Bag

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
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  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
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  • a) Powder fill by weight or volume b) Filling of the mould from the top
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Page 33: ISOSTATIC PRESSING

Cross-section of Bag

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
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  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
  • Slide 6
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  • a) Powder fill by weight or volume b) Filling of the mould from the top
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Page 34: ISOSTATIC PRESSING

cold isostatic press for ceramic

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
  • Slide 2
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  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
  • Slide 6
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  • a) Powder fill by weight or volume b) Filling of the mould from the top
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Page 35: ISOSTATIC PRESSING

Tubes Made by Isostatic Pressing

1048698Isopressing Mold and Mandrel

hot isostatic press

  • ISOSTATIC PRESSING
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  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
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Page 36: ISOSTATIC PRESSING

hot isostatic press

  • ISOSTATIC PRESSING
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  • Why Isostatic Pressing
  • Fig 1 Examples of use of (a) container with holes and (b) (c) formers for producing shaped components by isostatic pressing
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Effects of Hot Isostatic Pressing on Copper Parts ...Effects of Hot Isostatic Pressing on Copper Parts Additively Manufactured via Binder Jetting Ashwath Yegyan Kumar GENERAL AUDIENCE

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