Analysis of Multistage Linkage Based Eclipse Gearbox for Wind Mill Applications

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Analysis of Multistage Linkage Based Eclipse Gearbox for Wind Mill Applications 1 Shrutika Patil, 2 J. G. Patil, 3 R. Y. Patil 1 M.E. Student, 2 Associate Professor, 3 Head of Department, Department of Mechanical Engineering, SGDCOE, Jalgaon(MS), India Abstract A wind energy conversion system consists of number of components to transfer the wind energy to electrical energy. Presently wind mills employ epicyclic gearbox for transfer of high torque generated by rotor to low torque required for generator. Gearbox is expensive and critical component of wind turbine. Moreover the high speed ratio and fluctuating loads put limitation on module of gear teeth that lead to failure of conventional gearbox due to breaking of teeth. The three stage overlay kinematic linkage system and epicyclic gearbox combination provides a reliable solution to above problem where in high strength, robustness and friction less performance of kinematic linkage ensure a fail safe operation and high efficiency and maximum life. Index Terms Eclipse gearbox, Reliability of gearbox, Crankshaft, Traditional gearbox, Wind turbine. I. INTRODUCTION A wind energy conversion system consists of a number of components to transform the energy in the wind to electrical energy. One of these components is the rotor, which is the component that extracts energy from the wind. The operating regime of a wind turbine is divided into three regions. Fig. 1: Power O/p Vs Wind speed Region 1(wind speed up to (4m/s) is the low wind speed region for which the turbine does not produce any power, the rotor is standing still and the turbine is disconnected from the grid. When the turbine would be connected to the grid at these low wind speeds, the generator would start working as a motor, driving the turbine. The turbine would then actually be working as a huge fan, consuming energy instead of producing. The second region, region 2(wind speed 4 to 14m/s), is the region between the wind speed at which the turbine starts to operate (Vw;cut in) and the wind speed at which maximum power is produced (Vw;rated). This is the region for which maximizing energy capture is very important, but limitation of dynamic loads also becomes more important. In a typical wind turbine, region 2 operation accounts for more than 50% of the annual energy capture. This indicates the importance of efficient operation in this regime. Finally there is region 3, which is the region from the rated wind speed to the wind speed at which the turbine is stopped to prevent damage (vw;cut out). In this region, energy capture is limited such that the turbine and generator are not overloaded and dynamic loads do not result in mechanical failure. The limitation in energy capture is generally controlled by pitching the rotor blades. [1] IJEDR1703082 International Journal of Engineering Development and Research (www.ijedr.org) 556

II. BLADE PITCH CONTROL Blade pitch control is used to control the aerodynamic power captured from the wind. By pitching the rotor blades along their longitudinal axis, the aerodynamic efficiency of the rotor is changed. This change is caused by a modification in the aerodynamic angle of attack. The aerodynamic angle of attack is defined as the angle between the chord line of the rotor blade and the direction of the approaching wind, as seen by the rotor blade. When decreasing the angle of attack, called feathering, the lift capacity of the blades is reduced and therefore the power captured by the rotor decreases. Conversely, an increase in the angle of attack, with respect to the operational position, will lead to a higher power capture due to a reduction in drag. When the critical aerodynamic angle of attack is reached, the airflow separates at the surface of the rotor blades, limiting the power. This effect is called stall. Below rated wind speed, the pitch angle can be controlled to change the tip speed ratio. However, application of blade pitch control to follow the desired tip speed ratio is limited by the rate at which the blades can be pitched and the reaction time of the rotor speed to change. A disadvantage of using blade pitching below rated speed is that less energy is extracted from the wind, decreasing the efficiency. For this reason, blade pitch control is generally not used below the rated wind speed. Above rated wind speed, blade pitch control is used to limit the angular speed of the rotor by capturing less power from the wind then available and to protect the system from excessive forces. By pitching the blades, the operating range of the turbine in terms of wind speed is increased. Without blade pitch control, the maximum operating speed would be rated wind speed. Above rated, the dynamic loads on the mechanical components would become too high and the angular speed of the rotor would exceed its maximum. With blade pitch control, the operating range is typically increased up to 25 m/s. [2] III. METHODOLOGY Fig. 2: Layout of Eclipse Gear Box Epicyclic gear is connected to the input shaft (high torque) and linkages are connected to output shaft (low torque). Motion delivered by epicyclic to internal gear in 360 degree rotation of input shaft (by one pinion) is only during forward state due to one way clutch. Output is mainly depends on: Number of linkages, Linkages dimensions, Gear ratio of epicyclic gear and internal gear. A standard internal gear and pinion are meshed without tooth interference. On the driving shaft A is mounted an eccentric, the axis of the driving gear follows the motion of eccentric, but is kept from revolve about its own axis by pin, which works in the slot. Linkage is actuated by the eccentric, which constantly maintains slot in a perpendicular position through the action of parallel links, pivoted on studs. Since the axis of gear follows the motion of Eccentric and the gear does not rotate about its own axis, the motion imparted to the driven gear will be uniform. IV. DESIGN AND ANALYSIS OF VARIOUS COMPONENTS OF ECLIPSE GEARBOX Input Shaft To Calculate Input Torque, Input data - Motor is a Single phase AC motor, Power = 60watt, Speed is continuously variable from 0 to 6000 rpm. Considering the operating speed of motor = 600 rpm at the input shaft and assuming 75 % efficiency of belt drive. Input power = (60 /6000) x (600 x 5) x 0.75 = 22.5 watts Where, 5= reduction ratio of belt drive & 0.75 is efficiency. Motor Torque, P = 2 П N T 60 T = 22.5 x 60 2 П x 600 T = 0.35 N-m Considering 50 percent overload on system Tdesign = 1.5 x 0.35 = 0.54 N-m IJEDR1703082 International Journal of Engineering Development and Research (www.ijedr.org) 557

Fig. 3: Design of Input Shaft Design of Input Shaft - Theoretical method Table 1: Material Selection for Input Shaft Designation Ultimate Tensile Strength (N/mm 2 ) Yield Strength (N/mm 2 ) EN 24 As per ASME code, fs max = 108 N/mm 2 Check for torsional shear failure: fs act = 0.67 N/mm 2 As; fs act < fs all Input Shaft is safe under torsional load. 800 680 Fig. 4: Geometry of Input Shaft IJEDR1703082 International Journal of Engineering Development and Research (www.ijedr.org) 558

Fig. 5: Equivalent Stresses in Input Shaft Maximum stress by analytical methods is well below the allowable limit of 108 N/mm 2, hence the input shaft is safe. Yoke Design of Yoke - Theoretical Method Fig. 6: Design of Yoke Table 2: Material Selection for Yoke Designation Ultimate Tensile Strength(N/mm 2 ) Yield Strength(N/mm 2 ) EN9 600 380 As per ASME code, fs max = 100 N/mm 2 Check for torsional shear failure: fs act = 0.073N/mm 2 As, fs act < fs all Yoke is safe under torsional load IJEDR1703082 International Journal of Engineering Development and Research (www.ijedr.org) 559

Fig. 7: Geometry of Yoke Crank Fig. 8: Equivalent Stresses in Yoke Maximum stress by analytical methods is well below the allowable limit of 100 N/mm 2, hence the yoke is safe. Fig. 9: Design of Crank IJEDR1703082 International Journal of Engineering Development and Research (www.ijedr.org) 560

Design of Crank - Theoretical method Table 3: Material Selection for Crank Designation Ultimate Tensile strength (N/mm 2 ) Yield strength (N/mm 2 ) EN9 600 380 As per ASME code, fs max = 100 N/mm 2 Check for torsional shear failure: fs act = 0.087 N/mm 2 As fs act < fs all Crank is safe under torsion load. Fig. 10: Geometry of Crank Fig. 11: Equivalent Stresses in Crank Maximum stress by analytical methods is well below the allowable limit of 100 N/mm 2, hence the crank is safe. External Gear To calculate gear torque, Torque at the external and internal gear pair = Torque (without overload) x reduction ratio due to kinematic linkage x Gear ratio of internal external Where, Linkage reduction ratio is such that each link converts 360 degree to 45 degree hence total three links are these which means the net motion of the system is (45+45+45 = 135) and reduction ratio of linkage = 360 /135 = 2.93--- approximately 3 Tdesign for gear system = 0.35 x 3 x (50/44) = 1.19 N-m Hence, the torque used to design gear pair is 1.19 N-m. IJEDR1703082 International Journal of Engineering Development and Research (www.ijedr.org) 561

Fig. 12: Design of External Gear Design of External Gear - Theoretical method Table 4: Material Selection for External Gear Designation Ultimate Tensile Strength (N/mm 2 ) Yield Strength (N/mm 2 ) EN 24 800 680 As per ASME code, fs max = 108 N/mm 2 Check for torsional shear failure: fs act = 0.02 N/mm 2 As, fs act < fs all External gear is safe under torsion load Fig. 13: Moment of External Gear IJEDR1703082 International Journal of Engineering Development and Research (www.ijedr.org) 562

Fig. 14: Equivalent Stresses in External Gear. Maximum stress by analytical methods is well below the allowable limit of 108 N/N/mm 2, hence the external gear is safe. Internal Gear Design of Internal Gear- Theoretical Method Fig. 15: Design of Internal Gear Table 5: Material Selection for Internal Gear Designation Ultimate Tensile Strength (N/mm 2 ) Yield Strength (N/mm 2 ) EN 24 800 680 As per ASME code, fs max = 108 N/mm 2 Check for torsional shear failure: fs act = 0.01 N/mm 2 fs act < fs all Internal gear is safe under torsion load. IJEDR1703082 International Journal of Engineering Development and Research (www.ijedr.org) 563

Fig. 16: Moment of Internal Gear Fig. 17: Equivalent Stresses in Internal Gear Maximum stress by analytical methods is well below the allowable limit of 108 N/mm 2, hence the internal gear is safe. V. RESULTS Name of the Components Table 6: Results of Components of Eclipse Gearbox Theoretical Stress (N/mm 2 ) Maximum Allowable Stress (N/mm 2 ) Maximum Analytical Stress (N/mm 2 ) Results Input shaft 108 0.671 2.0256 Safe Yoke 100 0.073 0.18024 Safe Crank 100 0.087 0.51424 Safe External gear 108 0.02 0.08251 Safe Internal gear 108 0.01 0.039876 Safe IJEDR1703082 International Journal of Engineering Development and Research (www.ijedr.org) 564

VI. CONCLUSIONS Determined stress by theoretical and analytical methods is well below the allowable limit of 108 N/mm 2 hence the input shaft, external gear and internal is safe. Determined stress by theoretical and analytical methods is well below the allowable limit of 100 N/mm 2 hence the yoke and crank is safe. All the components shows stresses well below the permissible limit indicating safety of the component which solve the reliability problems. The service life for the proposed eclipse gear box will be marginally higher as compared to the existing gearbox. REFERENCES [1] M. J. Verdonschot, Modeling and Control of wind turbines using a Continuously Variable Transmission, DCT 2009.028 [2] E. Muljadi and C. P. Butterfield, Pitch-controlled variable-speed wind turbine generation, NREL, Conference Report, 2000. [3] R. R. Salunkhe, Prof V. R. Gambhire, R. S. Kapare, Review on Eclipse Gearbox Reliability, IOSR Journal of Mechanical and Civil Engineering (IOSR-JMCE), PP: 27-34. [4] Terry Lester Lestran Engineering Fort Worth, Solving the Gearbox Reliability Problem, Texas, USA [5] P. Sakthivel, Dr. Rajamani, Pitting Analysis Of Wind Mill Gear, International Journal of Engineering Research & Technology,Vol. 1 Issue 8, ISSN: 2278-0181, October - 2012. [6] PSG College of Technology, PSG Machine Design Data Book, Publisher, PSG College of Technology, 1966. [7] A. A. Keste, A. A. Tolani, V. A. Handre, N. R. Sharma, M. A. Gavhane, Eclipse Drive Train for Windmill, IOSR Journal of Mechanical and Civil Engineering (IOSR-JMCE) ISSN (e): 2278-1684, ISSN (p): 2320 334X, PP : 45-47. IJEDR1703082 International Journal of Engineering Development and Research (www.ijedr.org) 565

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