交叉簧片柔性铰链是一种应用广泛的柔性转动关节。依靠簧片的分布式柔度可以产生较大的转动角度,但是与此同时铰链转动过程中的中心漂移大、抗干扰能力较差,这些都影响了铰链的传动精度和稳定性。通过采用非等直簧片构造的变截面交叉簧片柔性铰链可以使弹性元件的变形主要集中于铰链的交叉点附近,从而改变铰链的转动性能。基于Euler-Bernoulli梁理论建立了考虑几何非线性的变截面交叉簧片柔性铰链的末端载荷与铰链变形之间的关系。通过与有限元仿真进行对比,验证了文中建立的变形模型的准确性。利用柔性铰链的静态变形模型,分析了铰链的转动范围、转动刚度、中心漂移和抗干扰性能与簧片截面系数之间的关系。分析结果表明,对比传统交叉簧片柔性铰链,变截面交叉簧片柔性铰链具有更高的转动精度。
杨淼
,
杜志江
,
陈依
,
孙立宁
,
董为
. 变截面交叉簧片柔性铰链的力学建模与变形特性分析[J]. 机械工程学报, 2018
, 54(13)
: 73
-78
.
DOI: 10.3901/JME.2018.13.073
The cross-spring flexure pivot is a type of flexure joint which has been widely used in long stroke compliant mechanisms. Due to the distributed compliance, the flexure pivot can generate a large rotation angle, however, this structure also has some disadvantages, i.e., large center shift and low support stiffness. The concept of variable cross-section flexure pivot is proposed. The performance of the flexure pivot can be changed by applying non-prismatic spring leaves since they will concentrate the deformation of the leaves near the ration center of the flexure pivot. A static deformation model of the variable cross-section flexure pivot which considered the geometric nonlinearity of the spring leaves is proposed based on the Euler-Bernoulli beam theory. The model is verified by finite element simulations, the results obtained from those two methods agree with each other very well. Moreover, the relationship between the section factor of the spring leaves and the static deformation performances of the proposed flexure pivot, i.e., rotation range, rotation stiffness, center shift and anti-interference ability are discussed by using the deformation model. The results show that the flexure pivot with variable cross-section has higher rotational accuracy compared with the conventional one.
[1] YONG Y K, LU T, HANDLEY D C. Review of circular flexure hinge design equations and derivation of empirical formulations[J]. Precision Engineering, 2008, 32(2):63-70.
[2] TIAN Y, SHIRINZADEH B, ZHANG D, et al. Three flexure hinges for compliant mechanism designs based on dimensionless graph analysis[J]. Precision Engineering, 2010, 34(1):92-100.
[3] LOBONTIU N. Compliance-based matrix method for modeling the quasi-static response of planar serial flexure-hinge mechanisms[J]. Precision Engineering, 2014, 38(3):639-650.
[4] YANG M, DU Z, CHEN F, et al. Kinetostatic modelling of a 3-PRR planar compliant parallel manipulator with flexure pivots[J]. Precision Engineering, 2017, 48:323-330.
[5] BI S, YAO Y, ZHAO S, et al. Modeling of cross-spring pivots subjected to generalized planar loads[J]. Chinese Journal of Mechanical Engineering, 2012, 25(6):1075-1085.
[6] CHOI Y, SREENIVASAN S V, CHOI B J. Kinematic design of large displacement precision XY positioning stage by using cross strip flexure joints and over-constrained mechanism[J]. Mechanism and Machine Theory, 2008, 43(6):724-737.
[7] JENSEN B D, HOWELL L L. The modeling of cross-axis flexural pivots[J]. Mechanism and Machine Theory, 2002, 37(5):461-476.
[8] 杨其资,刘浪,毕树生,等. 广义三交叉簧片柔性轴承的旋转刚度特性研究[J]. 机械工程学报, 2015, 51(13):189-195. YANG Qizi, LIU Lang, BI Shusheng, et al. Rotational stiffness characterization of generalized triple-cross-spring flexure pivots[J]. Journal of Mechanical Engineering, 2015, 51(13):189-195.
[9] MERRIAM E G, LUND J M, HOWELL L L. Compound joints:Behavior and benefits of flexure arrays[J]. Precision Engineering, 2016, 45(6):79-89.
[10] MACHEKPOSHTI D F, TOLOU N, HERDER J L. A review on compliant joints and rigid-body constant velocity universal joints toward the design of compliant homokinetic couplings[J]. Journal of Mechanical Design, 2015, 137:0323013.
[11] HENEIN S, SPANOUDAKIS P, DROZ S, et al. Flexure pivot for aerospace mechanisms[C]//10th European Space Mechanisms and Tribology Symposium, San Sebastian, Spain, Sep. 24-26, 2003:285-288.
[12] LIU L, BI S, YANG Q, et al. Design and experiment of generalized triple-cross-spring flexure pivots applied to the ultra-precision instruments[J]. Review of Scientific Instruments, 2014, 85(10):105102.
[13] NAVES M, BROUWER D M, AARTS R G K M. Building block-based spatial topology synthesis method for large-stroke flexure hinges[J]. Journal of Mechanisms and Robotics, 2017, 9(4):41006.
[14] 张爱梅,陈贵敏,贾建援. 基于完备椭圆积分解的交叉簧片式柔性铰链大挠度建模[J]. 机械工程学报, 2014, 50(11):80-85. ZHANG Aimei, CHEN Guimin, JIA Jianyuan. Large deflection modeling of cross-spring pivots based on comprehensive elliptic integral solution[J]. Journal of Mechanical Engineering, 2014, 50(11):80-85.
[15] ZHAO H, BI S. Stiffness and stress characteristics of the generalized cross-spring pivot[J]. Mechanism and Machine Theory, 2010, 45(3):378-391.
[16] 赵宏哲,毕树生,于靖军. 三角形柔性铰链的建模与分析[J]. 机械工程学报, 2009, 45(8):1-5. ZHAO Hongzhe, BI Shusheng, YU Jingjun. Modeling and analysis of triangle flexible hinge[J]. Journal of Mechanical Engineering, 2009, 45(8):1-5.
[17] PEI X, YU J, ZONG G, et al. Design of compliant straight-line mechanisms using flexural joints[J]. Chinese Journal of Mechanical Engineering, 2014, 27(1):146-153.
[18] PEI X, YU J, ZONG G, et al. Analysis of rotational precision for an isosceles-trapezoidal flexural pivot[J]. Journal of Mechanical Design, 2008, 130(5):52302.
[19] VALENTINI P P, PENNESTRÌ E. Elasto-kinematic comparison of flexure hinges undergoing large displacement[J]. Mechanism and Machine Theory, 2017, 110:50-60.
