Analysis of Mechanical Characteristics of the Swing Angle Milling Head of a Heavy Computer Numerical Control Milling Machine and Research on the Light Weight of a Gimbal
-
Published:2024-01-09
Issue:2
Volume:17
Page:324
-
ISSN:1996-1944
-
Container-title:Materials
-
language:en
-
Short-container-title:Materials
Author:
Cui Youzheng123, Liu Chengxin1, Mu Haijing1, Jiang Hui4, Xu Fengxia123, Liu Yinfeng14, Hu Qingming15
Affiliation:
1. School of Mechanical and Electronic Engineering, Qiqihar University, Qiqihar 161006, China 2. The Engineering Technology Research Center for Precision Manufacturing Equipment and Industrial Perception of Heilongjiang Province, Qiqihar 161006, China 3. The Collaborative Innovation Center for Intelligent Manufacturing Equipment Industrialization, Qiqihar 161006, China 4. Qiqihar Heavy CNC Equipment Co., Ltd., Qiqihar 161005, China 5. School of Mechatronics Engineering, Harbin Institute of Technology, Harbin 150001, China
Abstract
As the key component of a five-axis CNC planer-type milling machine, the integral mechanical property of the A/C swing angle milling head directly affects the machining accuracy and stability of the milling machine. Taking the mechanical A/C swing-angle milling head of a five-axis numerical-control gantry milling machine as the research object, the stress deformation characteristics and natural frequency of the swing-angle milling head under actual working conditions were studied using finite-element analysis. Based on the analytical results, it was determined that the cardan frame, with its large mass proportion and strong rigidity of the whole milling head, is the object to be optimized. The topological optimization of the cardan frame, in which achieving the minimum flexibility was the optimization objective, was carried out to determine the quality reduction area. By comparing the simulation results of the cardan frames of three different rib plate structures, it was shown that the cardan frame performance of the ten-type rib plate structure was optimal. The analytical results showed that, when the cardan frame met the design requirements for stiffness and strength, the mass after optimization was reduced by 13.67% compared with the mass before optimization, the first-order natural frequency was increased by 7.9%, and the maximum response amplitude was reduced in all directions to avoid resonance, which was beneficial to the improvement of the dynamic characteristics of the whole machine. At the same time, the rationality and effectiveness of the lightweight design method of the cardan frame were verified, which has strong engineering practicality. The research results provide an important theoretical basis for the optimization of other machine tool gimbals and have important practical significance and application value.
Funder
Research Projects of Basic Scientific Research Business Expenses of Provincial Colleges and Universities in Heilongjiang Province
Reference28 articles.
1. Discrete variable topology optimization based on cellular mosaic grid;Chen;Modul. Mach. Tools Autom. Process. Technol.,2023 2. Weule, H., Fleischer, J., Neithardt, W., Emmrich, D., and Just, D. (2003, January 3–5). Structural Optimization of Machine Tools including the static and dynamic Workspace Behavior. Proceedings of the 36th CIRP-International Seminar on Manufacturing Systems, Saarbrucken, Germany. 3. Topology optimization approaches: A comparative review;Sigmund;Struct. Multidiscip. Optim.,2013 4. Lightweight Design of Tool Holder Bracket Based on Topology Optimization;Xie;Mech. Des. Manuf. Eng.,2019 5. Aggogeri, F., Borboni, A., Merlo, A., Pellegrini, N., and Ricatto, R. (2016). Vibration Damping Analysis of Lightweight Structures in Machine Tools. Materials, 10.
|
|