基于UG的叶轮制造工艺研究与仿真
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摘要
叶轮广泛应用于航空、航天和汽车等领域。然而由于其复杂的结构和较高的精度要求,长期以来制造工艺的选择一直是制造该类产品的难题。基于某型号叶轮模型的结构特点,对其制造工艺进行研究。首先对叶轮车削工艺方案与铣削工艺参数进行分析;其次对叶轮的加工轨迹与数控原理进行分析;然后结合UG数控编程模块对叶轮加工程序进行分析与编制;最后,结合加工平台与加工信息对叶轮进行实际加工。经检测验证,按新工艺加工的叶轮满足产品的设计与精度要求。实践证明了所设计的制造工艺的正确性与可行性;提升了加工正确率、效率与精度;研究结果对相似零件加工具有参考价值。
Impeller is widely used in aviation,aerospace,automotive and other fields. However,due to its complex structure and high precision requirements,the choice of manufacturing process has been a difficult problem in the manufacture of this kind of products for a long time. Based on the structural characteristics of a certain type of impeller model,the manufacturing process was studied. Firstly,the impeller turning process scheme and milling process parameters were analyzed; next,the machining trajectory and numerical control principle of impeller were analyzed; and then the impeller machining program was analyzed and compiled in combination with UG NC programming module; finally,the impeller was processed in combination with machining platform and processing information. After testing and verification,the impeller processed by the new technology has met the requirements of product design and precision. The correctness and feasibility of the designed manufacturing process are verified by practice; and the accuracy,efficiency and precision of the machining are improved. The research results have reference value for similar parts processing.
Impeller is widely used in aviation,aerospace,automotive and other fields. However,due to its complex structure and high precision requirements,the choice of manufacturing process has been a difficult problem in the manufacture of this kind of products for a long time. Based on the structural characteristics of a certain type of impeller model,the manufacturing process was studied. Firstly,the impeller turning process scheme and milling process parameters were analyzed; next,the machining trajectory and numerical control principle of impeller were analyzed; and then the impeller machining program was analyzed and compiled in combination with UG NC programming module; finally,the impeller was processed in combination with machining platform and processing information. After testing and verification,the impeller processed by the new technology has met the requirements of product design and precision. The correctness and feasibility of the designed manufacturing process are verified by practice; and the accuracy,efficiency and precision of the machining are improved. The research results have reference value for similar parts processing.
引文
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[2]刘泽瑞,苟蘅汇,陶应森.基于NX8. 0与VERICUT的叶轮五轴加工技术研究[J].现代制造技术与装备,2013(4):1-2,16.
[3]任小中.机械制造技术基础[M].北京:科学出版社,2016:139-143.
[4]杨德武,彭芳瑜,周云飞.基于主曲率匹配的五坐标刀位轨迹优化[J].华中科技大学学报(自然科学版),2001,29(12):8-11.
[5]沈斌,欧阳华兵.关于复杂曲面刀具轨迹规划技术的研究[J].新技术新工艺,2010(9):24-28.
[6]郝无忌.整体式叶轮建模及数控加工仿真研究[D].沈阳:东北大学,2015.
[7]张吉堂,刘永姜,王爱玲,等.现代数控原理及控制系统[M]. 3版.北京:国防工业出版社,2009:104-106.
[8]毕庆贞,丁汉,王宇晗.复杂曲面零件五轴数控加工理论与技术[M].武汉:武汉理工大学出版社,2016.
[9]北京兆迪科技有限公司.UG NX10. 0数控加工教程[M].北京:机械工业出版,2015.
[10]付海军.五轴联动数控加工中心加工仿真研究[D].沈阳:东北大学,2012.
[11]原北京第一通用机械厂.机械工人切削手册[M].北京:机械工业出版社,2014.
[12]杨建中,王充,陈吉红,等.航空增压器叶轮多轴高效加工工艺与仿真优化[J].机械工程与自动化,2016(2):4-7.
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