THREE PIN CONSTANT VELOCITY JOINT FOR PARALLEL AND ANGULAR POWER TRANSMISSION

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THREE PIN CONSTANT VELOCITY JOINT FOR PARALLEL AND ANGULAR POWER TRANSMISSION Swapnil Barde 1, Dr.Vithoba Tale 2, Tejas Adak 3, Kushal Balgude 4, Ajitkumar Chendage 5 2 Professor: Department of Mechanical Engineering, GSMCOE Balewadi Pune, (India) 1,3,4,5 Department of Mechanical Engineering, GSMCOE Balewadi Pune, (India) ABSTRACT Now a days, universal joint and couplings are used for parallel offset power transmission and angular offset power transmission. These joints are used to transfer power from engine shaft to rear wheels. These joints have limitations like offset distance, angle&speed and causes in vibrations and also low efficiency (below 65%). So the three pin constant velocity jointgives more advantages such as 15 mm parallel offset and 12 degree angular offset, at high speeds up to 2000 to 2400 rpm, and gives efficiency up to 85-90%. The three pin constant velocity joint minimizes the cost of production, space requirement and provides simple technology as compared to Oldham s coupling and universal joint. Keywords: Angular Offset, Parallel Offset, Power Transmission, 3-Pin Constant Velocity Joint I INTRODUCTION The couplings are used to connect two shafts for power transmission. Couplings transmits power from engine shaft to rear wheel of vehicle, without disconnection of shafts during operations. The main purpose of couplings is to transmit power between two rotating pieces, while permitting some degree of misalignment or end movement or both. Some of widely used couplings are as follows, Rigid couplings. Sleeve couplings. Flange Couplings. Flexible Couplings. Oldham s couplings. Universal Joints. 7 P a g e

1.1 Uses of Couplings Shaft couplings are used in machinery for several purposes. The most common of which are the following. 1. To provide for the connection of shafts of units that are manufactured separately such as a motor and generator and to provide for disconnection for repairs or alterations. 2. To provide for misalignment of the shafts or to introduce mechanical flexibility. 3. To reduce the transmission of shock loads from one shaft to another. 4. To alter the vibration characteristics of rotating units. 5. To connect driving and the driven part 6. To transfer power one end to another end.(ex: motor transfer power to pump through coupling)for power transmission. This couplings have following Drawbacks- Maximum efficiency is limited upto 65-70%. Maximum operating speed upto 1400 rpm. Radial and angular loads reduces bearing life. Maximum angular offset permissible upto 12mm only. Vibration problem. This drawback overcome by using alternatives as constant velocity joints. Types of constant velocity joint are- Rzeppa constant velocity (CV) joint. Tripod Constant Velocity Joint. Centre Support Bearings. Bendix-Weiss constant velocity (CV) joint. Three pin constant velocity. II FEATURES & ADVANTAGES The Three pin Constant velocity joint is an ideal solution to the power transmission between shafts and permits angular offset, the only wearing parts being the trunion joints. The Three pin constant velocity joint ensures that no fluctuating loads are transmitted across to the output shaft. The features of the Constant velocity joint are as follows: 1. True constant velocity high angle shaft coupling through all angles and rotation and articulation 2. Maximum working articulation angle of 15 degrees. Coupling does provide a stroke limiting device to prevent angle being exceeded. 3. Nominal high torque rating 4. Maximum peak torque rating for short duration periods. 5. Maximum speed of rotation 2,400 rpm. 8 P a g e

6. Generation and excitation of vibration forces is minimised through patented spherical dividing mechanism providing true constant velocity rotation. 7. True point centricity enabling pivoting applications to be fully realised 8. High torsional and radial rigidity. Axial length compensation can be achieved by appropriate splined shaft connections or similar if required. 9. High axial rigidity feature allows for axial load transfer. eg transfer of thrust loads. 10. No requirement for phased or angular connecting flanges as with traditional UJ technology. 11. Minimal heat generation from roller bearing componentry unlike traditional cv joint technology thus providing highest efficiency and maximum service life at high speeds AND full angle. 12. Three pin constant velocity Joint is corrosion protected. 13. Actual bearing life depends on combination of factors including equivalent speed, torque and angle as well as shock loads, re-lubrication frequency and environmental conditions. Figure 1. Constant Velocity Joint 2.1 Advantages of 3 pin constant velocity joints Step-less variation of angular offset: Any displacement between 0 to 60 mm can be obtained.hence the drive provides flexibility in operation and setting as prime mover location can be varies as per space available Wide range of angular displacement: The wide range of angular displacement 30 to 65 degrees enables to get vibration free power transmission at high speed. Compact size: The size of the gear less variable speed reducer is very compact; which makes it low weight and occupies less space in any drive. Ease of operation : The changing of angular and angular offset is gradual one hence no calculations of speed ratio required for change gearing.merely by rotating hand wheel speed can be changed Singular control: Entire range of offset is covered by a single hand wheel control. Maximum efficiency: The efficiency is increased upto 90%. 9 P a g e

III EXPERIMENTAL ANALYSIS 3.1 Parallel Offset: 12mm Figure 2. Experimental Setup Aim: -To conduct trial a) TORQUE Vs. CHARACTERISTICS b) POWER Vs. CHARACTERISTICS c) EFFICIENCY Vs. CHARACTERISTICS In order to conduct trial, a dyno brake pulley cord, weight pan are provided on the Output shaft. Procedure 1) Start motor 2) Let mechanism run & stabilize at certain speed (say 1500 rpm) 3) Place the pulley cord on dyno brake pulley and add 0.1 KG weight into, The pan, note down the output speed for this load by means of tachometer. 4) Add another 0.1KG cut & take reading. 5) Tabulate the readings in the observation table 6) Plot Torque Vs. speed characteristic Power Vs. speed characteristic 10 P a g e

Observation Table SR.NO LOADING UNLOADING MEAN WEIGHT WEIGHT (KG) (RPM) (KG) (KG) 1 0.2 1490 2 1470 1480 2 0.4 1408 4 1412 1410 3 0.6 1330 6 1350 1340 4 0.8 1200 8 1180 1190 5 1 950 10 924 937 Table.1 Observation Table Sample Calculations (0.6 Kg Load) 1) Average Speed N = = N= 1340 Rpm 2) Output Torque T dp = Weight in pan x Radius of Dyno brake Pulley = (0.6x 9.81) x 25 =147.15 N.mm Tdp = 0.1475N.m 3) Input Power:- (Pi/p) = 29 WATT 4) Output Power:- (Po/p) Po/p = = = 20.64watt 5) Efficiency:- = = = 71.17% Efficiency of transmission of gear drive at 0.6 kg load=71.17% 11 P a g e

Result Table SR NO. LOAD (kg) (rpm) TORQUE (n-m) POWER (watt) (%) 1 0.2 1480 0.04905 7.6020 26.21 2 0.4 1410 0.0981 14.484 49.94 3 0.6 1340 0.14715 20.648 71.2 4 0.8 1190 0.1962 24.449 84.3 5 1 937 0.24525 24.064 82.87 Table.2 Result Table Figure.3Speed v/s Torque Graph shows that torque increases with decrease in output speed Figure.4 Speed v/s Power Graph shows that maximum power is obtained around 1190 rpm thus it is recommended speed at maximum parallel offset Figure.5 Speed vs Efficiency Graph shows that maximum efficiency is obtained at about 1190 rpm thus it is recommended speed at maximum parallel offset 12 P a g e

3.2 Angular Offset: 14 Degree Maximum Aim: -To conduct trial d) TORQUE Vs CHARACTERISTICS e) POWER Vs CHARACTERISTICS f) EFFICIENCY Vs CHARACTERISTICS In order to conduct trial, a dyno brake pulley cord, weight pan are provided on the output shaft. Procedure 7) start motor 8) Let mechanism run & stabilize at certain speed (say 1500 rpm) 9) Place the pulley cord on dyno brake pulley and add 0.1 KG weight into, The pan, note down the output speed for this load by means of tachometer. 10) Add another 0.2KG cut & take reading. 11) Tabulate the readings in the observation table 12) Plot Torque vs. speed characteristic Power Vs. speed characteristic Observation Table SR.NO LOADING UNLOADING MEAN WEIGHT (KG) (RPM) WEIGHT (KG) (KG) 6 0.2 1425 2 1415 1420 7 0.4 1330 4 1310 1320 8 0.6 1230 6 1260 1245 9 0.8 1100 8 1070 1085 10 1 885 10 865 875 Table.3 Observation Table Result Table SR LOAD TORQUE POWER NO. (kg) (rpm) (n-m) (watt) (%) 1 0.2 1420 0.04905 7.2938 25.15 2 0.4 1320 0.0981 13.560 46.75 3 0.6 1245 0.14715 19.184 66.15 4 0.8 1085 0.1962 22.292 76.86 5 1 875 0.24525 22.47 77.48 13 P a g e

Table.4 Result Table Figure.6 Speed v/s Torque Graph shows that torque increases with decrease in output speed Figure.7 Speed v/s Power Graph shows that maximum power is obtained around 875 rpm thus it is recommended speed at maximum angular offset Figure.8Speed vs Efficiency Graph shows that maximum efficiency is obtained at about 875 rpm thus it is recommended speed at maximum angular offset IV CONCLUSION The 3-Pin Constant velocity joint is the most suitable joint for transmitting power with maximum parallel as well as maximum angular offset. It transmits the power with less vibration also maximum efficiency obtained as compared to other power transmitting devices. 14 P a g e

REFERENCES 1. Cooney Jr; Cetal (1979); Universal Joint and Driveshaft Design Manual 2. Pierburg B, Amborn P. (1998) ;Constant-Velocity Driveshafts for Passenger Cars 3. NikitasSidiropoulos (2003); Volvo Internal Document; Calculation Methodology for service life analysis of transmission components 4. ASTME1049-85 (2005); Standard Practices for Cycle Counting in Fatigue Analysis 5. Ulrich K, Eppinger S. (2007); Product Design and Development 6. Mayagoitia. R, Nene. A, Veltink. P. (2002) Accelerometer and rate gyroscope Measurement of kinematics: an inexpensive alternative to optical motion Analysis systems; Journal of Biomechanics; Nr 35; page 537-542 7. O'Donovan K, Kamnik R, O'Keeffe D, Lyons G. (2007) An inertial and magnetic Sensor based technique for joint angle measurement; Journal of Biomechanics; nr 40; page 2604-2611 8. Catharina R et al. (2006); Measuring the angle between a first and a second Element under dynamic condition; SE2219521 9. Steinert H-R. (2000); Sensor arrangement on a wheel suspension for a vehicle; US6126177 10. Kurzeja P et al. (2002); Method and apparatus for measuring driveline angles; US6490540 15 P a g e

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