78406623 chevron inspection and testing heat exchanger

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Chevron Corporation 900-1 December 1989 900 Inspection and Testing Abstract This section covers both shop inspection of new equipment and inspection of existing units during maintenance turnarounds. The section on shop inspection covers information on shop testing and inspection to verify that new units are built to specification and with good workmanship. Heat exchanger failures cause many plant shutdowns and slowdowns. The cost of these failures is high due to lost production and replacement of the exchangers. Inspection’s responsibilities are to: (1) inspect existing exchangers when they are taken out of service to determine extent of repairs and remaining life; (2) verify that repairs are completed to the tolerances specified; and (3) maintain accurate long term records that facilitate accurate forecasting. This section covers inspection and testing requirements for new and existing shell and tube and air cooled heat exchangers. The type of damage found in exchangers is discussed, along with the primary inspection and testing techniques used to deter- mine the condition of an exchanger. Detailed shutdown inspection checklists are included. Acceptable dimensional tolerances are discussed, and guidance on Safety Instruction Sheets (SIS) for shell and tube exchangers and air cooled heat exchangers is provided. Contents Page 910 Shop Inspection of New Exchangers 900-3 911 General Comments 912 Degree of Inspection 913 Shop Inspection of Shell and Tube Exchangers 914 Shop Inspection of Air Cooled Heat Exchangers 915 Inspection Tasks 920 Inspection of Existing Shell and Tube Exchangers and Air Cooled Exchangers 900-9 921 The Inspection, Engineering, Operation, and Maintenance Team 922 Inspection Sequence 923 Double Pipe Exchangers

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900 Inspection and Testing

AbstractThis section covers both shop inspection of new equipment and inspection of existing units during maintenance turnarounds. The section on shop inspectioncovers information on shop testing and inspection to verify that new units are buto specification and with good workmanship.

Heat exchanger failures cause many plant shutdowns and slowdowns. The costhese failures is high due to lost production and replacement of the exchangersInspection’s responsibilities are to: (1) inspect existing exchangers when they ataken out of service to determine extent of repairs and remaining life; (2) verify repairs are completed to the tolerances specified; and (3) maintain accurate lonterm records that facilitate accurate forecasting.

This section covers inspection and testing requirements for new and existing shand tube and air cooled heat exchangers. The type of damage found in exchanis discussed, along with the primary inspection and testing techniques used to mine the condition of an exchanger. Detailed shutdown inspection checklists arincluded. Acceptable dimensional tolerances are discussed, and guidance on SInstruction Sheets (SIS) for shell and tube exchangers and air cooled heat exchangers is provided.

Contents Page

910 Shop Inspection of New Exchangers 900-3

911 General Comments

912 Degree of Inspection

913 Shop Inspection of Shell and Tube Exchangers

914 Shop Inspection of Air Cooled Heat Exchangers

915 Inspection Tasks

920 Inspection of Existing Shell and Tube Exchangers and Air Cooled Exchangers 900-9

921 The Inspection, Engineering, Operation, and Maintenance Team

922 Inspection Sequence

923 Double Pipe Exchangers

Chevron Corporation 900-1 December 1989

900 Inspection and Testing Heat Exchanger and Cooling Tower Manual

924 Inspection of State Registered Unfired Steam Generators

930 Types of Damage Found In Exchangers 900-11

940 Inspection and Testing Techniques 900-12

941 Inspection Techniques

942 Pressure Testing Techniques

943 Safety

950 Dimensional Tolerances 900-14

960 Safety Instruction Sheets 900-15

970 Maintenance Inspection Checklists 900-17

December 1989 900-2 Chevron Corporation

Heat Exchanger and Cooling Tower Manual 900 Inspection and Testing

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910 Shop Inspection of New Exchangers

911 General CommentsShop inspection is warranted for virtually all heat exchangers except “off-the-shlube oil coolers. Inspection at the fabrication plant is normally done by the QualAssurance (QA) section of Purchasing, or by an inspector contracted by PurchaQA to inspect the exchanger. The purpose of shop inspection is to provide assuance that the equipment meets specification and order requirements, displays gworkmanship, and is free of significant damage or defects.

ASME Code uses the term “Authorized Inspector” to describe the inspector whoworks for a state, municipality, or insurance company and must be used by the cator to inspect the exchanger and sign the Manufacturer’s Data Report. The Arized Inspector is not the same shop inspector that Chevron uses. The AuthorizeInspector’s responsibility is to verify that the exchanger is designed and fabricain accordance with ASME Code, but he has no interest in and does not check sthings as:

1. Dimensions or orientations (except for diameter and thickness).

2. Presence of all required nozzles, baffles, or impingement plates; plumb-ness/squareness of nozzles.

3. Limitations or restrictions in Company specifications on materials or weldinprocesses.

4. Special construction details in Company specifications that exceed ASME Code requirements.

5. Inspection or testing requirements in Company specifications that exceed ASME Code minimums.

912 Degree of InspectionFigures 900-1 and 900-2 show the degrees of inspection for shell and tube heaexchangers and for air cooled exchangers, respectively. The degrees of inspecranging from one or two inspection visits to resident inspection. The visits themselves are listed in chronological sequence. Degrees of inspection are listed geally in accordance with the importance of the visit.

Purchasing QA usually establishes the visits required based on the specifics oforder, but the job engineer can always participate in this decision. Figures 900-and 900-2 define the basic purpose for each visit but do not list all of the tasks the Company inspector is required to complete during these visits (see Section

Chevron Corporation 900-3 December 1989

900 Inspection and Testing Heat Exchanger and Cooling Tower Manual

Fig. 900-1 Degrees of Inspection for Shell and Tube Heat Exchangers

Visit Notes:A. This visit is required for any parts of exchanger that are required to be PWHT’D. This does not apply to stress relief of tube bends.

B. This visit is made prior to any hydrostatic test and after PWHT if any. For exchangers with fixed tubesheets, internal inspection of the shell prior to attachment of closing tubesheet is required.

C. This visit is required for all stacked exchangers with interconnecting nozzles.

D. This visit is required for Degree 9, 10, and 11 inspection if finish paint is shop applied.

General Notes:1. Add supplementary visits A, C, and D as applicable.

2. Visits for purposes other than listed may be warranted and added (for example, to witness penetrant test of sealwelded tubes/tubesheets).

3. This matrix does not include all of the inspection tasks that an inspector completes during the required plant visits shown. A list of detailed inspection tasks can be several pages long. This list is normally part of the inspection plan for a particular exchanger. Inspection plans are usually prepared by Purchasing QA.

4. Each visit is not necessarily a full 8-hour day.

5. Problems with quality, specification compliance, or vendor cooperation/scheduling could increase the number of visits beyond the number shown.

December 1989 900-4 Chevron Corporation

Heat Exchanger and Cooling Tower Manual 900 Inspection and Testing

Fig. 900-2 Degrees of Inspection for Air Cooled Exchangers

Visit Notes:A. Outside face of tubesheet must be painted prior to tubing bundle if painting outside face is important; not normally done.

B. Test erection and shop run are normally required. This visit can usually be included with visit for final inspection.

General Notes:1. Add supplementary visits A and B as applicable.

2. Visits for purposes other than listed may be warranted and added.

3. This matrix does not include all of the inspection tasks that an inspector completes during the required plant visits that are shown. A list of detailed inspection tasks can be several pages long. This list is normally part of the inspection plan for a particular exchanger. Inspection plans are usually prepared by Purchasing QA.

4. Each visit is not necessarily a full 8-hour day.

5. Problems with quality, specification compliance, or vendor cooperation/scheduling could increase the number of visits beyond the number shown.

Chevron Corporation 900-5 December 1989

900 Inspection and Testing Heat Exchanger and Cooling Tower Manual

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913 Shop Inspection of Shell and Tube ExchangersFigure 900-1 identifies the different degrees of inspection for shell and tube exchangers. Figure 900-3 summarizes when to use the various degrees. Degreabout the minimum for any shell and tube exchanger in hydrocarbon or critical service. Degree 10 is appropriate where any of the following apply.

• The exchanger has a fabrication time over 6 weeks.• The exchanger is very large (over 4 feet diameter).• The exchanger wall thickness is over 1-1/4 inch.• The exchanger has a high pressure rating (flanges 600 pounds or more).• The exchanger is fabricated from low alloy or high alloy steels.• The exchanger has substantial cladding or weld overlay.

Degree 11 (resident inspection) is rarely applied to heat exchangers but could bconsidered during fabrication of heavy wall shells or channels (over about 4 incthick).

Visits for purposes in addition to those listed can be added to cover any specialconcerns.

914 Shop Inspection of Air Cooled Heat ExchangersFigure 900-2 identifies the degree of inspection for air cooled heat exchangers.Degree 5 is about the minimum for any air cooled exchanger in hydrocarbon or critical service. Factors similar to those listed in Section 913 above are used to decide when more inspection visits are warranted; consult Purchasing QA for ational guidance.

915 Inspection TasksFigures 900-1 and 900-2 do not list all of the tasks the Company inspector is required to complete during the plant visits. These tasks are normally listed in ainspection plan prepared by Purchasing QA. The tasks listed in the inspection pcan be several pages long. Some of the principal tasks are:

1. Verification that welding procedures and welders are qualified per ASME C

2. Review of material test reports for principal exchanger parts and verificationthat exchanger parts are traceable to material test reports.

3. Verification that welding procedures and preheat requirements are being followed.

4. Visual inspection of all welds for flaws, contour, size, and reinforcement.

5. Reading all radiographs (“x-rays”) and witnessing other nondestructive exanation, if required.

6. Complete dimensional and orientation check against Company reviewed vendor drawings.

December 1989 900-6 Chevron Corporation

Heat Exchanger and Cooling Tower Manual 900 Inspection and Testing

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Fig. 900-3 Application of the Degrees of Inspection for Shell and Tube Exchangers (1 of 2)

GUIDELINES FOR CHOOSING THE APPROPRIATE DEGREE OF INSPECTION FOR SHELL AND TUBE HEAT EXCHANGERS(NOTE THAT THESE ARE GUIDELINES ONLY)

Degree 1 when:

1. No Company specification applies, and

2. Exchanger:

a. is small and simple (under 18 inch diameter), and

b. is carbon steel (tubes can be another material), and

c. has low pressure rating (under 250 psig), and

d. is not in flammable or hazardous services.

Degree 2 when:

1. No Company specification applies, and

2. Exchanger:

a. is of moderate size (18 inch to 30 inch diameter), and

b. is carbon steel (tubes can be another material), and

c. has low pressure rating (under 250 psig).

OR

3. Only one low dollar value hair-pin type exchanger is on a purchase order (an attempt is made to accomplish Degree 2 inspection in one visit to include inspecting parts, witnessing assembly, and witnessing hydrostatic tests).

Degree 3 when:

1. Company specifications and/or standard drawings apply, and

2. Exchanger:

a. is small and simple (under 18 inch diameter), and

b. is carbon steel (tubes can be another material), and

c. has low pressure rating (under 250 psig), and

d. is in relatively noncritical service (choose at least Degree 4 for critical services).

Note “Critical Service” is difficult to define; judgment is required; factors to consider are type of service (contents of exchanger), consequences of failure with regard to the process, consequencefailure with regard to personnel and surrounding facilities.

Degree 4 (this is the normal minimum for exchangers in hydrocarbon service) when:

1. Company specifications and/or standard drawings apply, and

2. Exchanger:

a. is of moderate size (18 inch to 30 inch diameter), and

b. is carbon steel (tubes can be another material), and

c. has moderate pressure rating (150 pound or 300 pound flanges), and

d. is in relatively critical service.

Chevron Corporation 900-7 December 1989

900 Inspection and Testing Heat Exchanger and Cooling Tower Manual

Degree 5 when:

1. Company specifications and/or standard drawings apply, and

2. Exchanger:

a. is of large size (over 30 inch diameter), and

b. is carbon steel (tubes can be another material), and

c. has moderate pressure rating (150 pound or 300 pound flanges), and

d. is in relatively critical service

Degree 6 when:

1. Company specifications and/or standard drawings apply, and

2. Exchanger:

a. is of large size (over 30 inch diameter), and

b. is carbon steel (tubes can be another material), and

c. has shell thickness 3/4 inch or more, and

d. has moderate pressure rating (150 pound or 300 pound flanges), and

e. is in relatively critical service.

Degree 7 (same as Degree 6 but when diameter, thickness of tubesheet, or tubesheet material warrants a visit for tubesheet/baffle inspection before installing tubes; this visit should always be made for tubesheets that are clad, weld overlayed, or will have tube/tubesheet welds, and can be considered for all moderate size and large size process exchangers.)

Degree 8 (same as Degree 7 but when surface preparation required for painting is “near-white” or “White Metal.”)

Degree 9 (same as Degree 7 but when surface preparation required for painting is “near-white” or “White Metal” and inspection of dry primer is judged to be warranted.)

Degree 10 when:

1. Exchanger:

a. fabrication time is over 6 weeks, or

b. is very large (over 4 feet diameter), or

c. has wall thickness over 1-1/4 inch, or

d. has a high pressure rating (flanges 600 pound or more), or

e. is fabricated from low alloy or high alloy steels.

f. is fabricated from clad or weld overlayed material.

Degree 11 (Resident inspection is rarely applied to heat exchangers but could be considered during fabrication of heavy wall shells or channels; heavy wall means over 4 inches thick.)

Fig. 900-3 Application of the Degrees of Inspection for Shell and Tube Exchangers (2 of 2)

December 1989 900-8 Chevron Corporation

Heat Exchanger and Cooling Tower Manual 900 Inspection and Testing

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7. Verification that all nozzles are present, and that they are correct size, ratinand material.

8. Verification that bundle has all required baffles and support plates, and thatbaffle and tubesheet holes have been deburred; verification that tubes havebeen properly expanded into tubesheet holes.

9. Review of Manufacturer’s Data Report to verify all entries are correct.

920 Inspection of Existing Shell and Tube Exchangers and Air Cooled Exchangers

921 The Inspection, Engineering, Operation, and Maintenance TeamWhile much of the standard maintenance work on exchangers is initiated by instion, the major decisions must be made with input from inspection, engineeringoperations and maintenance. These decisions include:

• Retubing or rebundling• Plugging tubes• Nozzle replacement• Major shell repairs or replacement• Gasket surface repairs

The above organizations also must work together to establish the objectives of exchanger repairs well in advance of the shutdown. These objectives include:

• Exchanger or bundle design life

• Time between internal inspections (for some cases, this is determined by sregulations; i.e., waste heat boilers)

• Degree of internal or external leakage which is acceptable over the life of thbundle

• Degree of cleaning required (often dictated by process economics)

Section 1000 contains a Heat Exchanger Bundle Repair Worksheet for helping engineer coordinate the decision making process.

922 Inspection SequenceInspection of existing exchangers and air coolers involves the following steps:

1. Set objectives as discussed above.

2. Examine inspection and maintenance records to note any trends and makeinitial recommendations.

Chevron Corporation 900-9 December 1989

900 Inspection and Testing Heat Exchanger and Cooling Tower Manual

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3. Perform preshutdown inspection to note leaks and any areas which must binspected in more detail when the unit is shut down.

4. Determine need for bleeder tests prior to opening.

5. Inspect and photograph shell and bundle after exchanger has been openedbefore cleaning to look for patterns and types of fouling and evidence of plugged tubes.

6. Inspect shell and bundle after cleaning and make recommendations for rep

7. Inspect repairs and witness testing.

8. Record gagings and repairs in the inspection file to anticipate what to expethe future.

9. Process paperwork for any code repairs or operating permits for state registered equipment.

Section 970 contains a detailed inspection checklist for exchangers and air coo

923 Double Pipe ExchangersDouble pipe or “hairpin” exchangers can be one pipe or several pipes inside anpipe. In either type of exchanger the corrosion is usually found in the area of thinlet nozzle and at the return bend.

All these units are usually small enough in diameter to radiograph. Radiographcan reveal the inner and outer pipe wall thickness, tube-wall thickness, and anyfouling problem, without taking the unit out of service. Most repair work can thefore be planned before the plant is actually shut down.

In one double pipe exchanger, called a “chiller,” the stock in the inner pipe is scraped using a scroll, and corrosion is usually found externally because of lowtemperature conditions. The scrolls may also break or become disconnected.

924 Inspection of State Registered Unfired Steam GeneratorsLike fired boilers, unfired steam generators require periodic inspection and statcertification by qualified boiler inspectors. Generally, unfired steam generators aof tubular heat exchanger design. Consequently, inspection and repair follow thsame general pattern as that used for process heat exchangers.

1. The tube bundles are removed, cleaned, and inspected externally and inte

2. The shells and flash drums are internally inspected and ultrasonically gage

3. The gage glasses, pressure gages and alarms are cleaned and serviced. Tsafety valves are removed, cleaned, tested and reset.

4. Hydrostatic tests, when applied, should include the flash drum, if any, and interconnected piping and appurtenances.

December 1989 900-10 Chevron Corporation

Heat Exchanger and Cooling Tower Manual 900 Inspection and Testing

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The work copies of the inspection report and operating permit sheet are compleand processed as required by the local inspection organization.

930 Types of Damage Found In ExchangersThe various types of damage found in exchangers are discussed below. Refer tCorrosion Prevention Manual for more information.

End impingement—where high velocity stock enters the tube and erodes the enThis can involve the tubesheet as well.

Galvanic corrosion—occurs when the tube material and tubesheet material are apart on the galvanic scale, often with salt water as the electrolyte; e.g., for a Mtubesheet with titanium tubes, the Monel tubesheet will corrode.

Lodgement attack—occurs when an obstruction in the tube increases velocitiesthat point and erodes the tube.

External corrosion—wall thinning on the outside of the tube.

Internal corrosion—wall thinning on the inside of the tube.

Dezincification—usually occurs on the I.D. of Admiralty brass tubes in saltwaterservice operating above 120°F or when an inhibited grade of Admiralty was notused.

Denickelification—usually occurs on the I.D. of copper-nickel tubes in saltwaterservice which have operated well above their normal tube-wall temperature.

CO2 attack—occurs in condensing steam service and is common at the floatingtubesheet end of the tube O.D. on vertical reboilers.

Stress corrosion cracking—usually occurs at a stressed point of tubes, such as the U-bends. Can occur on any metal. Chlorides with stainless steels or NH3 with brass are examples where this can be a problem.

Mechanical deformation—caused by improper sling placement when handling tbundle, for example.

Vibration wear—occurs when the area between the tube and transverse baffle too great or when the baffle spacing is too great, allowing the tube to vibrate in hole.

Seal weld cracking—cracks in the tube-to-tubesheet seal weld. (Usually detecteduring a hydrotest.)

Roll leaks—when the tube-to-tubesheet roll joint leaks. (Usually detected duringhydrotest.)

Thermal shock—usually occurs during an operation upset. Improper starting upshutting down of equipment or loss of cooling water can cause shock. This commonly causes roll leaks.

Chevron Corporation 900-11 December 1989

900 Inspection and Testing Heat Exchanger and Cooling Tower Manual

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External impingement—usually occurs on the tube O.D. in the area of the shell inlet nozzle. Can be remedied by installing an impingement device on the bundusually impingement rods or tubes.

Necking down—occurs on the tube O.D. at the transverse baffle. It is caused bytoo large an area between the tube O.D. and the transverse baffle, allowing bypassing. Usually the baffle will erode as well as the tube, requiring replacemeat the next retubing.

940 Inspection and Testing TechniquesThis section discusses the primary inspection and testing techniques used to dmine the condition of an exchanger before, during, and after repairs. It does noinclude visual inspection, which is very important.

941 Inspection Techniques• Ultrasonic (UT) gaging can be used to determine remaining wall thickness o

the shell as well as defects in the wall.

• Micrometer measurements are used to determine tube wall thickness, depthof pitting, and metal loss on body flanges or tubesheets.

• Radiography can be used to check wall thickness and fouling in tubes. Radraphy can be used on large bundles by sliding the film under the outer row tubes. On large U-tube bundles the U-bends can be radiographed for wall tness and fouling.

On bundles with tubes 2-inch O.D. and larger, tube wall thickness and O.Dfouling can be identified using radiography by sliding a narrow film cassetteone tube and the source in another tube. Place the film in Tube A as shownFigure 900-4. Put the source in Tube D. The two walls projected on the filmwill be the inside walls of Tubes B and C. Any fouling between Tubes B andwill show on the film. Several films can be shot with one exposure, dependion the tube layout and space available.

Fig. 900-4 Film Layout for X-Raying Bundles with Tube 2 inches and Larger

December 1989 900-12 Chevron Corporation

Heat Exchanger and Cooling Tower Manual 900 Inspection and Testing

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• Eddy current testing is an effective inspection tool for determining tube walthickness. It is very useful for determining the tube wall in the center of tubebundles when specimen tubes are unattainable, such as in U-tube bundlesFerrous as well as nonferrous tubes can be inspected; however, the tubes be clean, and specimen tubes to confirm eddy current results are advisablebefore major repairs.

• Specimen tubes are tubes which have been removed from various locationsthroughout the bundle to determine the extent of corrosion in the bundle. Choosing the proper location of the specimen tubes is critical in developingaccurate profile of the corrosion. Often, eddy current is used to determine tworst areas of corrosion before pulling specimen tubes.

• Boroscopes connected to a TV can be used to visually inspect the tube interThis technique will not measure wall thickness or pitting depth but can be agood visual tool for determining tube condition.

942 Pressure Testing TechniquesIn general, exchangers out of service for repairs are pressure tested before therepairs to determine where work is required and after repairs to determine if theexchanger meets code requirements.

Test PressuresThe code hydrostatic test pressures are calculated using the code under whichexchanger was built (usually ASME). The exchanger fabricator generally supplithese pressures. The exchanger should be tested to full code test pressure afterepair work affecting the strength of the vessel.

Minimum Pressurizing Temperature (MPT)The temperature of the pressurizing fluid must be above the MPT as discussedSection 820 of this manual and in the Pressure Vessel Manual.

Tube Side TestsPressuring the tubes permits inspection of the channel cover gasket, channel, channel-to-tubesheet gasket, tubesheets, floating head gasket, floating head, atubes. Leaks can be identified by leakage at the joints; however, individual tubeleaks are not identifiable because the tubesheets are inaccessible.

Shell Side TestsPressuring the shell side tests the shell, shell-to-tubesheet gasket, channel-to-tubesheet gasket, tubesheets, and tubes. If the channel has a removable covertest allows individual leaking tubes to be plugged off because the tubesheet is asible. Roll leaks also can be individually identified and repaired. U-tube bundleseasily tested with the shell enclosed. Floating head bundles require the use of aring to observe the floating tubesheet during the shell test. Figure 900-5 is a scmatic of a test ring.

Chevron Corporation 900-13 December 1989

900 Inspection and Testing Heat Exchanger and Cooling Tower Manual

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Leakage TestsTests for leakage can be conducted at the operating pressure for repairs not affecting the vessel “strength,” such as plugging tubes.

Bleeder TestsShell and tube bleeder tests can be applied quickly; however, they will indicate that the unit is leaking. The type of leak will be unknown. When the shell or tubare pressured, inspect for leaks at the channel or shell drains.

Testing MediumThe testing medium should be oil or water. Gas tests are more sensitive, but arextremely dangerous. Such tests over 15 psig require the approval of local manment.

943 SafetyThe inspector must remember that pressure tests involve certain hazards. In adtion to gaskets blowing out, previously driven plugs can blow out as well. Whilewitnessing pressure tests, the inspector should stand to one side. Unauthorizedpersonnel should not be in the vicinity of the exchanger on test. The test pump have a safety valve set at the test pressure, and a gage with a range of roughlydouble the test pressure (i.e., if test pressure is 150 psi, gage range should be 300 psi).

950 Dimensional TolerancesDimensional tolerances for standard shell and tube exchangers are tabulated inSection 2 of the Standards of Tubular Exchanger Manufactures Association (TEMA).

Fig. 900-5 Test Ring - Floating Tubesheet (Courtesy of TEMA)

December 1989 900-14 Chevron Corporation

Heat Exchanger and Cooling Tower Manual 900 Inspection and Testing

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Copies of TEMA Tables F-1 and F-2 are included for your quick reference. (SeeFigures 900-6 and 900-7.)

Dimensional tolerances for air cooled exchangers are covered by API Standardalso included in this manual.

960 Safety Instruction SheetsSafety Instruction Sheets (SISs) are used by several organizations as a single-source summary document for important data on operating equipment. These dare important to operations, technical groups, inspection and maintenance, andinclude:

• Safe operating limits (temperatures, pressures, rotational speeds, etc.)

• Particular precautions for safe operation

• Specified routine tests required for safe operation

• References necessary to operate and/or maintain the equipment

• Inspection/technical data (minimum thickness, corrosion allowances, test psures, relief valve settings, minimum pressurizing temperatures, etc.)

SI sheets should be completed for (1) new exchangers and (2) existing exchanthat have been altered in any way that affects the SI sheet content. This includematerial changes, derating, minimum thickness changes.

SI sheets are routinely filled out by a project engineer and countersigned by anating representative. They become permanent records in the inspection groupsin the equipment manuals for the plants. Many technical groups also maintain compiled copies. Some organizations are now shifting this information to a cenized information database, PEIS (Plant Equipment Information System). Regarof the format, the SI sheet is a good checklist of important information to have readily available.

A significant problem with SI sheets has been getting them accurately and completely filled in prior to startup. One reason for this is that vendors are not always as responsive during the latter stages of a project, after the equipment hbeen purchased and installed. If you are committed to having SI sheets, you shconsider methods to motivate vendors to complete them (or provide data) after design and operating data are confirmed.

Instructions for completing the following SI sheets are included in the Safety Instruction Sheet Section:

• EXH-EF-787 Shell and Tube and Double Pipe Heat Exchangers SI Sheet• EXH-EF-788 Air Cooled Heat Exchangers SI Sheet

Chevron Corporation 900-15 December 1989

900 Inspection and Testing Heat Exchanger and Cooling Tower Manual

Fig. 900-6 Standard Tolerances for External Dimensions, Nozzle and Support Locations of Heat Exchanger (Cour-tesy of TEMA)

December 1989 900-16 Chevron Corporation

Heat Exchanger and Cooling Tower Manual 900 Inspection and Testing

970 Maintenance Inspection ChecklistsAttached are inspection checklists for the following:

• Shell and Tube Exchangers (Figure 900-8)• Air Cooled Exchangers (Figure 900-9)

This information was excerpted from the CUSA Manufacturing Inspection Manual.

Fig. 900-7 Standard Clearances and Tolerances for Tubesheets, Partitions, Covers, and Flanges (Courtesy of TEMA)

Chevron Corporation 900-17 December 1989

900 Inspection and Testing Heat Exchanger and Cooling Tower Manual

Fig. 900-8 Inspection Checklist—Shell and Tube Exchangers (1 of 3)

Date: ____________________

Exchanger: ____________________

Service: Tube side __________________

Shell side __________________

Initial: _______

Preshutdown Inspection:

Discuss and agree on the “shutdown objectives with Operations, Engineering, and Maintenance.” _______

Records Check:

Review records and become familiar with corrosion history. Prepare a sketch indicating type and location of previous corrosion.

_______

External Visual Inspection:

Inspect exchanger supports for proper bearing and anchoring. _______

Look for corrosion on the shell where it is in contact with the concrete fireproofing. _______

Check slide plates or slotted bolt holes for freedom of movement at the exchanger supports. _______

Inspect support leg fireproofing for cracks and spalling and corrosion underneath. _______

Inspect the anchor bolts for necking down at the baseplate. _______

Where exchangers are saddled into a concrete support, inspect the shell for external corrosion. _______

Inspect the insulation and retainers. Corrosion often occurs where moisture penetrates the insula-tion and the shell is not hot enough to dry it out. Insulated exchangers which operate below ambient temperature are susceptible to this type of corrosion. Representative sections, or even all of the insulation, should be removed to permit a complete external inspection and ultrasonic gaging.

_______

Inspect all small piping for leaks and external corrosion, including vents, drains, relief valves, plugs, and other small screwed fittings.

_______

Look for gasket leaks on the inlet and outlet piping flanges and at the channel or shell cover flanges. Evidence of leaks can be seen as deposits on the ground or platform under the unit.

_______

Check the packing gland on the bottom leg of the reboilers for leaks. _______

Check gaskets and gasket surfaces for evidence of leakage. _______

If the unit is a water cooler or condenser, note the water outlet temperature either by dial thermom-eter or by feel. Excessively high water temperature (above 120°F for salt water) indicates possible fouling and probable high corrosion rates in the tubes.

_______

Ultrasonic Inspection:

Take ultrasonic gage measurements at locations where internal corrosion is suspected. A sufficient number of measurements should be taken to provide reasonable assurance of the exchanger’s integrity. It is important to recognize that external gage points can reflect general corrosion rates, but that actual remaining wall thickness is probably lower.

_______

December 1989 900-18 Chevron Corporation

Heat Exchanger and Cooling Tower Manual 900 Inspection and Testing

Shutdown Inspection:

Shell and Covers:

Verify exchanger is properly cleaned for inspection. Cleaning can be done by water-washing, chem-ical cleaning, or by sandblasting. The amount of cleaning required depends on the severity of the corrosion and fouling in the unit.

_______

Internally inspect shells 20 inches or greater in diameter. Look for evidence of corrosion, noting particularly the nozzle, flange and shell welds, and the locations where the transverse baffles contact the shell.

_______

Take ultrasonic (UT) gage measurements in corroded areas and at representative locations on the shell cover and channel section to establish an accurate picture of the corrosion patterns. UT the shell at the inlet and outlet nozzles.

_______

Prior to cleaning, check gasket surfaces for evidence of leakage. _______

After buffing, inspect gasket surfaces and flanges for evidence of corrosion or mechanical damage. Severely corroded gasket surfaces can require weld buildup and machining. Lightly damaged gasket surfaces can be repaired by machining or drawfiling.

_______

Inspect the baffles in channel sections for warpage, distortion, corrosion, or evidence of bypassing. _______

Ensure that baffle stay rods are not cracked or broken. _______

Inspect lifting lugs on channel sections and covers for mechanical damage or corrosion to ensure they are safe for continued use.

_______

Hammer-test or UT gage all small piping on the channel, shell, or shell cover and inspect all threaded fittings as necessary. On high pressure, or stainless steel piping, radiography should be used instead of hammer-testing.

_______

For services other than water, verify that all piping connections, including small piping, are welded up to the first root value. Eliminate connections less than 3/4 inch in size.

_______

Inspect longitudinal grooves or guides in the shell for the horizontal baffle in the bundle. _______

Inspect alloy lining for cracked attachment welds and pinhole leaks. Have leaking or bulged lining removed for inspection under the lining.

_______

If channel cover staybolts are used, observe the bolt holes behind the lining. Graphitization frequently enlarges the holes and results in leaks. Repairs can be made by using oversize gaskets under the nuts.

_______

Inspect floating head bolts for evidence of corrosion, breakage or overstressing. _______

Inspect split rings for warpage which can cause leaks at the floating head gasket. _______

Bundles:

A summary of the various types of bundle wear is included in Section 930 of the Heat Exchanger and Cooling Tower Manual.

_______

Before Cleaning:

Record plugging and fouling conditions. _______

Record clean washed areas indicative of high velocity and subsequent corrosion. _______

Fig. 900-8 Inspection Checklist—Shell and Tube Exchangers (2 of 3)

Chevron Corporation 900-19 December 1989

900 Inspection and Testing Heat Exchanger and Cooling Tower Manual

Walk around the unclean bundle, take pictures, gather samples of fouling products and scale for analysis if necessary. Look for distortion, leaks, and any unusual condition. Much of this evidence is washed away when the bundle is cleaned.

_______

After Cleaning:

Gage O.D. of accessible tubes with calipers. _______

Use a mirror to visually inspect the full length of the outside of as many tubes as possible. Have the bundle rotated if necessary.

_______

Look for localized corrosion near the shell inlet nozzle in areas of impingement. _______

Use a boroscope or a mirror and reflected light to visually inspect tube I.D. _______

Look at tube ends for corrosion and thinning using a tube I.D. gage. _______

Consider eddy current inspection for tube wall thickness. _______

Pull specimen tubes in strategic areas if necessary. Split the tube and check the entire length for remaining wall thickness. The eddy current inspection may give you an idea of where to pull spec-imen tubes.

_______

Inspect the front and backsides of tubesheets for corrosion. _______

Verify that all gasket surfaces are clean and free of defects and corrosion that could affect the tight-ness of the gasketed joint.

_______

Check the tubesheet baffle gasket surfaces for bypassing. Bypassing can corrode both the tubesheet gasket surface and the baffles.

_______

Check tubesheets with seal welded tubes for warpage which can cause excessive baffle bypassing. _______

Inspect the tubesheet which is to be reused as a bundle to ensure that it is retubed. Look for the tube hole enlargement using a “go/no-go” gage. Look for pieces of thimbles left in the tubesheet serrations. Check for cracked ligaments. Note the history of the bundle. If roll leaks have been a problem, the ligaments are probably spongy, unable to hold a tight roll, and the tubesheet should be replaced.

_______

Inspect the segmental cross baffles for hole enlargement by moving the tubes and observing excess movement.

_______

Look for general thinning of all carcass components. _______

Inspect the carcass for possible reuse when the bundle is retubed. Ensure that the frame will last the life of the bundle, especially when the tube material is being upgraded.

_______

Fig. 900-8 Inspection Checklist—Shell and Tube Exchangers (3 of 3)

December 1989 900-20 Chevron Corporation

Heat Exchanger and Cooling Tower Manual 900 Inspection and Testing

Fig. 900-9 Inspection Checklist—Air Cooled Exchangers

Date: _____________________

Equipment #: _____________________

Service: _____________________

Initial _______

Tubes:

Inspect fin condition and fouling. _______

Have header plugs removed and measure tube I.D. with an I.D. gage. _______

Consider eddy current inspection to determine tube wall thickness. _______

Pull specimen tubes if the eddy current inspection indicates it is warranted. _______

Header boxes and tubesheet:

Inspect the header box and tubesheet for wall thickness. _______

Check the plugs for impingement on the outlet sides. _______

Check the plug and header hole threads for corrosion and galling. _______

Fan, driver, and housing:

Inspect the fan for cracking or distress. _______

Check the guards to ensure they are intact, for personnel protection. _______

Check the light gage steel housing for general condition. _______

Chevron Corporation 900-21 December 1989