An investigation into the vibration of harmonic drive systems

M. Masoumi; H. Alimohammadi

doi:10.1007/s11465-013-0275-5

Front. Mech. Eng. ›› 2013, Vol. 8 ›› Issue (4) : 409 -419. DOI: 10.1007/s11465-013-0275-5

RESEARCH ARTICLE

An investigation into the vibration of harmonic drive systems

M. Masoumi ¹^,¹
, H. Alimohammadi ²

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Abstract

Harmonic drive systems are precise and specific transmission gear systems which are beneficial in terms of the high transmission ratio and almost zero backlash. These inherent and spectacular properties result in using this mechanism in robotic and space sciences where the precision and lightwieght play an important role. This paper presents a vibration analysis of harmonic drive systems using the shell theory. Equations of vibration for the flexspline and the circular spline of the system are derived and used to find the natural frequencies for both parts and, moreover, vibration response of the system under the operating condition is calculated. Also, obtained vibration equations are utilized to study the effects of different involved parameters such as the geometry of the flexspline and its gear tooth, eccentricity, and unbalancing on the vibrational behavior of the system.

Keywords

harmonic drive system / strain wave gearing mechanism / vibration analysis / natural frequencies

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M. Masoumi, H. Alimohammadi. An investigation into the vibration of harmonic drive systems. Front. Mech. Eng., 2013, 8(4): 409-419 DOI:10.1007/s11465-013-0275-5

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Rong H. Research on amplitude value of vibration in harmonic gear. Machine Tool & Hydraulics, 1995, 6: 336-339

[2]	Musser C W. Strain wave gear-species. US Patent, 1960

[3]	Tuttle T D. Understanding and modeling the behavior of a harmonic drive gear transmission. Technical report, MIT Artificial Intelligence Laboratory, 1992

[4]	Kokhanovskii G I, Polenov V S, Spiridonov V V. Calculating the stress and strain state of the flexible wheel of a wave toothed transmission. International Applied Mechanics, 1973, 9(12): 1355-1358

[5]	Shuvalov S. Calculation of harmonic drives with allowance for pliancy of links. Russian Engineering Journal, 1974, 54: 47-52

[6]	Shuvalov S. Calculation of forces acting on members of a harmonic gear drive. Russian Engineering Journal, 1979, 59(10): 5-9

[7]	Sinkevich Y B. Effect of teeth on the rim rigidity of the flexible gear wheel of a harmonic drive. Russian Engineering Journal, 1978, 58(7): 19-22

[8]	Emel’yanov A. Calculation of the kinematic error of a harmonic gear transmission taking into account the compliance of elements. Soviet Engineering Research, 1983, 3(7): 7-10

[9]	Margulis M, Volkov D. Calculation of the torsional rigidity of a harmonic power drive with a disc generator. Soviet Engineering Research, 1987, 7(6): 17-19

[10]	Hashimoto M. Robot motion control based on joint torque sensing. In: Proceedings of IEEE International Conference on Robotics and Automation. Japan, 1989, 256-261

[11]	Karlen J P, Thompson J M, Vold H I, Farrell J D, Eismann P H. A dual-arm dexterous manipulator system with anthropomorphic kinematics. In: Proceedings of IEEE International Conference on Robotics and Automation. USA, Cincinnati, 1990, 368-373

[12]	Thompson B R. The PHD: A Planar, Harmonic Drive Robot for Joint Torque Control. Technical Report, Massachusetts Institute of Technology Cambridge Artificial Intelligence Laboratory, 1990

[13]	Legnani G, Faglia R. Harmonic drive transmissions: the effects of their elasticity, clearance and irregularity on the dynamic behaviour of an actual SCARA robot. Robotica, 1992, 10(4): 369-375

[14]	Tuttle T D, Seering W. Kinematic error, compliance, and friction in a harmonic drive gear transmission. In: proceedings of ASME Design Technical Conferences: 19^th Advances in Design Automation. USA, New Mexico, 1993, 319-324

[15]	Tuttle T D, Seering W. Modeling a harmonic drive gear transmission. In: Proceedings of IEEE International Conference on Robotics and Automation. USA, Atlanta, 1993, 624-629

[16]	Tuttle T D, Seering W. A nonlinear model of a harmonic drive gear transmission. IEEE Transactions on Robotics and Automation, 1996, 12(3): 368-374

[17]	Kircanski N M, Goldenberg A A. An experimental study of nonlinear stiffness, hysteresis, and friction effects in robot joints with harmonic drives and torque sensors. International Journal of Robotics Research, 1997, 16(2): 214-239

[18]	Rong H. Research About Vibration of Harmonic Drives. Mechanical Transmission, 1995, 1: 33-36

[19]	Taghirad H D, Belanger P. Torque ripple and misalignment torque compensation for the built-in torque sensor of harmonic drive systems. IEEE Transactions on Instrumentation and Measurement, 1998, 47(1): 309-315

[20]	Hashimoto M, Kiyosawa Y, Paul R P. A torque sensing technique for robots with harmonic drives. IEEE Transactions on Robotics and Automation, 1993, 9(1): 108-116

[21]	Jeon H S, Oh S H. A study on stress and vibration analysis of a steel and hybrid flexspline for harmonic drive. Composite Structures, 1999, 47(1): 827-833

[22]	Ghorbel F H, Gandhi P S, Alpeter F. On the kinematic error in harmonic drive gears. Journal of Mechanical Design, 2001, 123(1): 90-97

[23]	Gandhi P S, Ghorbel F H. Closed-loop compensation of kinematic error in harmonic drives for precision control applications. IEEE Transactions on Control Systems Technology, 2002, 10(6): 759-768

[24]	Dhaouadi R, Ghorbel F H, Gandhi P S. A new dynamic model of hysteresis in harmonic drives. IEEE Transactions on Industrial Electronics, 2003, 50(6): 1165-1171

[25]	Xu L, Zhu C, Qin L. Parametric vibration for electromechanical integrated electrostatic harmonic drive. Mechatronics, 2007, 17(1): 31-43

[26]	Rhéaume F, Champliaud H, Liu Z. Understanding and modelling the torsional stiffness of harmonic drives through finite-element method. Proceedings of the Institution of Mechanical Engineers. Part C, Journal of Mechanical Engineering Science, 2009, 223(2): 515-524

[27]	Dong H, Zhu Z, Zhou W, Chen Z. Dynamic Simulation of Harmonic Gear Drives Considering Tooth Profiles Parameters Optimization. Journal of Computers, 2012, 7(6): 1429-1436