Abstract
The gravity balance mechanism plays a vital role in maintaining the equilibrium for robots and assistive devices. The purpose of this paper was to optimize the geometry of a planar spring, which is an essential element of the gravity balance mechanism. To implement the optimization process, a hybrid method is proposed by combining the finite element method, the deep feedforward neural network, and the water cycle algorithm. Firstly, datasets are collected using the finite element method with a full experiment design. Secondly, the output datasets are normalized to eliminate the effects of the difference of units. Thirdly, the deep feedforward neural network is then employed to build the approximate models for the strain energy, deformation, and stress of the planar spring. Finally, the water cycle algorithm is used to optimize the dimensions of the planar spring. The results found that the optimal geometries of the spring include the length of 45 mm, the thickness of 1.029 mm, the width of 9 mm, and the radius of 0.3 mm. Besides, the predicted results determined that the strain energy, the deformation, and the stress are 0.01123 mJ, 33.666 mm, and 79.050 MPa, respectively. The errors between the predicted result and the verifying results for the strain energy, the deformation, and the stress are about 1.87%, 1.69%, and 3.06%, respectively.
Highlights
A device is balanced when it can maintain equilibrium in any configuration or position without the need for external forces or actuators [1]
A nonlinear finite element method (FEM) is applied for the simulation process. e simulation process is set up as follows: the boundary condition and loads are given as shown in Figure 7. e planar spring (PS) is fixed with two holes, and a force of 10.935 N is applied to the top surface of the PS
Al T63-7075 is selected for the PS. e mechanical properties of the material are given in Table 2. e mesh is divided by using the sizing method. e element size greatly affects the behavior of the PS
Summary
A device is balanced when it can maintain equilibrium in any configuration or position without the need for external forces or actuators [1]. A gravity balance mechanism with adjusted loads was designed by the combination of a compliant spring and a torsion spring [9]. E PS is deformed during the working process, and it creates a strain energy and elastic force to compensate for the gravity generated by the mass. In order to work well, the strain energy of the PS should offer as large as possible and the stiffness of the PS should be ensured to create an elastic force that balances with the gravity due to the mass. Erefore, before building the approximate models, the structure optimization of the DFNN needs to be performed. The present paper is aimed to optimize the geometry factors of a planar spring, which is used for the gravity compensation mechanism. The WCA is applied to optimize the geometry of the planar spring
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