Optimization and experimental research on a new-type short cylindrical cup-shaped harmonic reducer

Hai-bo Gao , Hong-chao Zhuang , Zhi-gang Li , Zong-quan Deng , Liang Ding , Zhen Liu

Journal of Central South University ›› 2012, Vol. 19 ›› Issue (7) : 1869 -1882.

PDF
Journal of Central South University ›› 2012, Vol. 19 ›› Issue (7) : 1869 -1882. DOI: 10.1007/s11771-012-1221-0
Article

Optimization and experimental research on a new-type short cylindrical cup-shaped harmonic reducer

Author information +
History +
PDF

Abstract

In order to obtain a new-type short cylindrical cup-shaped flexspline that can be applied to space mechanisms, the APDL language of ANSYS software was employed to develop a parameterized equivalent contact model between a flexspline and a wave generator. The validity of the parameterized equivalent contact model was verified by comparing the results of the analytic value of the contact model and the value calculated by the theoretical formula. The curvilinear trend of stress was obtained by changing the structural parameter of the flexspline. Based on the curvilinear trend of stress, multi-objective optimizations of key structural parameters were achieved. Flexspline, wave generator, and circular spline of a new 32-type short cylindrical cup-shaped harmonic reducer were designed and manufactured. A performance test bench to carry out tests on the harmonic reducer was designed. Contrast experiments were implemented to determine the efficiency of the new 32-type short cylindrical cup-shaped harmonic reducer and the conventional 32-type harmonic reducer under different conditions. The experimental results reveal that there is approximately equality in terms of efficiency between the new 32-type short cylindrical cup-shaped harmonic reducer and the conventional 32-type harmonic reducer. The volume of the flexspline of the new 32-type short cylindrical cup-shaped harmonic reducer is reduced by approximately 30% through multi-objective optimization. When the new 32-type short cylindrical cup-shaped harmonic reducer is used on the wheel of a rover prototype, the mass of the wheel hub is decreased by 0.42 kg. Test analysis of wheel motion verifies that the new 32-type short cylindrical cup-shaped harmonic reducer can meet the requirements regarding bearing capacity and efficiency.

Keywords

harmonic drive / flexspline / structural parameter / multi-objective optimization

Cite this article

Download citation ▾
Hai-bo Gao, Hong-chao Zhuang, Zhi-gang Li, Zong-quan Deng, Liang Ding, Zhen Liu. Optimization and experimental research on a new-type short cylindrical cup-shaped harmonic reducer. Journal of Central South University, 2012, 19(7): 1869-1882 DOI:10.1007/s11771-012-1221-0

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

MUSSER C W. Strain wave gearing. US 2906143[P]. 1959.
[2]

GodlerI., HashimotoM.. Torque control of harmonic drive gears with built-in sensing[C]. Proceedings of the 24th Annual Conference of the IEEE Industrial Electronics Society, IECON, 1998AachenIEEE Comp Soc1818-1823

[3]

GandhiP. S., GhorbelF. H., DabneyJ.. Modeling, identification, and compensation of friction in harmonic drives [C]. 41st IEEE Conference on Decision and Control, 2002Las Vegas, Nevada USAInstitute of Electrical and Electronics Engineers Inc160-166
[4]

TuttleT. D.Understanding and modeling the behavior of a harmonic drive gear transmission [R], 1992MassachusettsMIT Artificial Intelligence Laboratory
[5]

HanC. H., WangC. C., MasayoshiT.. Suppression of vibration due to transmission error of harmonic drives using peak filter with acceleration feedback [C]. 10th International Workshop on Advanced Motion Control, AMC’08, 2008TrentoInstitute of Electrical and Electronics Engineers Inc182-187
[6]

SlatterR., DegenR.. Miniature zero-backlash gears and actuators for precision positioning applications [C]. 11th European Space Mechanisms and Tribology Symposium, ESMATS 2005, 2005Lucerne, SwitzerlandEuropean Space Agency9-15
[7]

DhaouadiR., GhorbelF. H., GandhiP. S.. A new dynamic model of hysteresis in harmonic drives [J]. A IEEE Transactions on Industrial Electronics, 2003, 50(6): 1165-1171

[8]

DongH., WangD.. Elastic deformation characteristic of the flexspline in harmonic drive [C]. ASME/IFToMM International Conference on Reconfigurable Mechanisms and Robots, 2009LondonIEEE Computer Society363-369
[9]

LiG.-jun.. Simulation of harmonic drive in precision robotic system [C]. 2010 Sixth International Conference on Natural Computation (ICNC 2010), 2010Yantai, ChinaIEEE Computer Society4278-4281

[10]

ChenX.-x., LinS.-z., XingJ.-zhong.. The investigation of elongation of the neutral line in harmonic drive [C]. 2010 International Conference on Computer Design and Applications (ICCDA 2010), 2010Qinhuangdao, ChinaIEEE Computer Society383-386
[11]

GaoW., FurukawaM., KiyonoS., YamazakiH.. Cutting error measurement of flexspline gears of harmonic speed reducers using laser probes [J]. Precision Engineering, 2004, 28(3): 358-363

[12]

JeonH. S., OhS. H.. A study on stress and vibration analysis of a steel and hybrid flexspline for harmonic drive [J]. Composite Structures, 1999, 47(1/2/3/4): 827-833

[13]

GaoH.-b., LiZ.-g., DengZ.-quan.. Sensitivity analysis of cup-shaped flexible gear parameters to its stress based on ANSYS [J]. Journal of Mechanical Engineering, 2010, 46(5): 1-7

[14]

BaumgartnerE. T., BonitzR. G., ShiraishiL. R., MelkoJ. P., LegerP. C.. The mars exploration rover instrument positioning system [C]. 2005 IEEE Aerospace Conference, 2005Big Sky, MontanaInstitute of Electrical and Electronics Engineers Computer Society1-19

[15]

ZhouH., WenQ.-p., ZhangW.-wen.. Harmonic drive used in spacecraft [J]. Vacuum & Cryogenics, 2004, 10(4): 187-192
[16]

XinH.-b., XieJ.-r., HeH.-y., ZhangZ.-mei.. Harmonic drive technology and its research tendency [J]. Journal of Beijing Institute of Light Industry, 1999, 17(1): 30-36
[17]

MaoB.-b., WangK.-wu.. Research and development outlined of tooth profile of harmonic gear [J]. Coal Mine Machinery, 2008, 29(7): 6-8
[18]

JinJ.-s., XiaJ.-c., WangX.-y., HuG.-a., LiuHua.. Die design for cold precision forging of bevel gear based on finite element method [J]. Journal of Central South University of Technology, 2009, 16(4): 546-551

[19]

ZhuangH.-c., WangJ.-d., WangN., ShiR., LiYan.. Mechanical characteristic analysis of the magnetometer structure component for the space exploration [J]. Chin J Space Sci, 2011, 31(1): 112-117
[20]

OstapskiW., MukhaI.. Stress state analysis of harmonic drive elements by FEM [J]. Bulletin of the Polish Academy of Science, Technical Science, 2007, 55(1): 115-123
[21]

HeJ.-l., WuX.-t., CuiY.-h., NieGang.. Tooth contact analysis of conical involute gears [J]. Chinese Journal of Mechanical Engineering, 2006, 19(1): 105-108

[22]

XinH.-bing.. Finite element analysis of stress on tooth rim of a flexspline [J]. Mechanical Science and Technology, 2003, 22(4): 558-559
[23]

KayabasiO., ErzincanliF.. Shape optimization of tooth profile of a flexspline for a harmonic drive by finite element modeling [J]. Materials & Design, 2007, 28(2): 441-447

[24]

Gear Manual Edit Committee.Gear manual [M], 2005BeijingChina Machine Press9-12-9-13
[25]

ShenY.-w., YeQ.-tai.The theory and design of the harmonic gear drive [M], 1985BeijingChina Machine Press2-235
[26]

RaoZ.-gang.The design of planetary transmission mechanism [M], 1994BeijingNational Defense Industrial Press547-581
[27]

YAN Yan-hong. Optimization design on structural dimensions of plastic harmonic gear drive [J]. Mechanical Design, 2002(10): 38–40. (in Chinese)
AI Summary AI Mindmap
PDF

169

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/