re design of independent rotary drive unit batch members: p.guruchandranathan(07me14)...
TRANSCRIPT
RE DESIGN OF INDEPENDENT ROTARY DRIVE UNIT
BATCH MEMBERS: P.GURUCHANDRANATHAN(07ME14) G.KUMANAN(07ME21) S.RAJESHKUMAR
(07ME35) J.SATHISHKUMAR (07ME42)
PROJECT GUIDE: S.S.NIVAS.M.E,ASST PROF
PROJECT VENUE: ONGC
ABSTRACT
• The present IRD unit is using gear coupling and chain coupling which seems to be ineffective & have short life time.
• So we are proposing to use clutch mechanism instead of gear coupling in order to increase
its efficiency & life span.
INTRODUCTION
• The independent rotary drive system is used to dig the earth surface and collect the oil & gas which is avail in nature.
• It consists of a drive to the rotary table by an independent motor through two speed transmission.
• By installing the system, the drive to the rotary table from the draw works is eliminated.• An emergency sprocket is available in this system which
gives a provision to use draw works drive in case of emergencies for a temporary failure or a redesign work.
MOTORGEAR COUPLING
CLUTCH BRAKE
GEAR CHAIN COUPLING
ROTARY TABLE
COMPONENTS OF IRD UNIT
PROBLEM DESCRIPTION
• At very high speeds (1000 rpm), the conventionally used gear coupling in IRD unit gets damaged very often.
• In order to overcome this, we are going to redesign the coupling unit.
GEAR COUPLING USING IRD
SPECIFICATION
INPUT SPEED : 1240 rpm
OUTPUT SPEED : 566-1240 rpm
INPUT HORSE POWER : 600-1000 ihp
INPUT SHAFT DIAMETER : 3.940 Inches
OUTPUT SHAFT DIAMETER : 3.940 Inches
GEAR RATIO : 1:1.128
METHODOLOGY
• We can modify the gear coupling unit in two methods 1.Flange coupling. 2.Planetary gear mechanism.• By adopting these two methods the life of the coupling unit is
increased compared to the existing gear coupling methods.
• Of the two methods, the planetary gear mechanism is noisy in operation.
• So we preferred implement of flange coupling
PLANNING
• Study about planetary gear mechanism and flange coupling methodology. • Analysing the two methods.• Selection of the best among those two methods.• Implementation and Adoptation in the industrial
applications.
DESIGN PROCEDURE FOR FLANGE COUPLING
INPUT SPECIFICATION:
N=1240rpmP=1000HP 1HP=736W 1W=1NM/secP=736x103WP=736KW
DESIGN CALCULATION:
P=(2πNT)/60 736=(2×π×1240×T)/60 T =5667969.586Nmm
DESIGN OF SHAFT: After analysing the various material, we are concluded the
material for shaft as c45 from psg data book page no 1.9 τ=65N/mm2
σ=150N/mm2
we know that τ=π/16xτxd3 where,τ is the allowable shear strength for shaft material, we can calculate
the shaft diameter 5667.96 x103 =π/16x65xd3
d=76.29 = 80 mm(approximately)Based on the observation made in the unit, it is cleared, we have
to select more than 100mm diameter.
Because,the existing shaft dia is equal to 100mm.By referring Indian standard (IS 3688-1977)
we will select d=122mm DESIGN OF VARIOUS PARAMETERS: τf =0.5d
where, τf =thickness of flange
d=shaft dia τf =61mm
L=1.5d L=length of hub L=183mm D=2d
D=outer dia of hub D=2X122 D=244mm D1 =3d
D1 =Pitch Circle dia
D1 =366mm
D2 =4d
D2 =outside dia of flange
D2 =488mm
Number of bolts,n=4 for “d” up to 100mm
DESIGN OF HUB: we selected the hub material is plain carbon steel Ʈ = 40 N/MM2
σ = 80 N/MM2 T = 5667969.586 NMM
T = π/16 X Ʈ h X [ D4 - d4/ D]
D = outside diameter of hub d = shaft diameter of hub Ʈ h = 2.119 N/MM2
Induced shear stress of hub is less than 40 N/MM2
The design for the hub is safe
DESIGN OF KEY :
From PSG data book page no 5.16
b = 22mm h = 14mm b = width of the key h = thickness of the key L = l = length of key = 120mm
(a) Check for shearing: T = l X b X Ʈ k X d/2
5667969.586 = Ʈ k X 120 X 22 X 80/2
Ʈ k = 23.07 N/MM2
Induced shear stress of key is higher than the permissible stresses. The design for key is not safe
(b) CHECK FOR CRUSHING:
T = σc X l X h/2 X d/2
h = thickness of key d = shaft diameter of key l = length of key
5667969.586 = σc X 120 X 14/2 X 80/2
σc = 72.535 N/MM2
Induced crushing stress of key is higher than the permissible stresses.
The design for key is not safe.
To select the material c45 for the key because, it has the shear value greater than the calculated one that is τ=65n/mm2
b=25mm h=14mmCheck for shearing: T = l x b x τ x d/2 5667969.586 = 183 x 25 x τ x 122/2 τ = 20.3 N/MM2
Check for crushing: T = σc x l x h/2 x d/2
5667969.586 = σc x 183 x 14/2 x 122/2
σc = 72.535 N/MM2
b=28mm h=16mm
Check for shearing: τ = 18.13 N/MM2
Check for crushing: σc = 63.46 N/MM2
b=32mm h=18mmCheck for shearing: τ = 15.86 N/mm2
Induced shear stress of key is less than the permissible stresses. The design for key is safeCheck for crushing: σc = 56.41 N/mm2
Induced crushing stress of key is less than the permissible stresses. The design for key is safe.
DESIGN OF FLANGE: T=τхtfxπD2 /2
tf = Thickness of flange
D=Outer diameter τ=1.515N/mm2
Induced shear stress of flange is less than the permissible stresses.
The design for the flange is safe.
DESIGN OF BOLT: To select the bolt material is c45
τ=65N/mm2
σ=150N/mm2 T=τXnxdb
2 xπ/4xD1 /2
where, db =dia of bolt
n=num of bolt D1=pitch circle dia of bolts
n=4 and db =13mm
increase the bolt,so n=8 and db =9mm
n=10 and db =8mm
n=12 and db =7mm
Check for crushing: τ=σxnxdbxtf XD1 /2
Where, db =dia of bolt
tf =thickness of flange
Where, n=4 and d=12 σ=10.57N/mm2
n=8 and d=9 σ=7.05N/ mm2
n=10 and d=8 σ=6.34N/ mm2
n=12 and d=7 σ=6.044N/ mm2
Induced crushing stress is less than permissible stress The design of the bolt is safe.
………………THANKYOU…………..