基于模糊综合层次评判法的精密齿轮制造工艺优化优先度分析

doi:10.3969/j.issn.1000-1093.2017.04.017

兵工学报 ›› 2017, Vol. 38 ›› Issue (4): 750-757.doi: 10.3969/j.issn.1000-1093.2017.04.017

基于模糊综合层次评判法的精密齿轮制造工艺优化优先度分析

李强，谢里阳，李海洋，张芳敏，宋佳昕

(东北大学现代设计与分析研究所，辽宁沈阳 110819)

收稿日期:2016-07-14 修回日期:2016-07-14 上线日期:2017-06-06
通讯作者: 谢里阳（1962—），男，教授，博士生导师 E-mail:lyxie@mail.neu.edu.cn
作者简介:李强(1988—)，男，博士研究生。E-mail: liqiang_neu@163.com
基金资助:
国家科技支撑计划课题“精密机械传动设计和高档齿轮制造技术”（2014BAF08B01）；辽宁重大装备制造协同创新中心资助项目（2014年~2017年）

Optimization Priority Analysis of Precision Gear Manufacturing Process Based on AHP Fuzzy Comprehensive Evaluation Method

LI Qiang, XIE Li-yang, LI Hai-yang, ZHANG Fang-min, SONG Jia-xin

(Institute of Modern Design and Analysis, Northeast University, Shenyang 110819, Liaoning, China)

Received:2016-07-14 Revised:2016-07-14 Online:2017-06-06

摘要/Abstract

摘要： 传统故障模式影响及危害度分析(FMECA)多应用于产品故障模式风险分析，而未涉及产品制造流程工艺参数优化优先度分析，且其风险优先数(RPN)分析无法对严酷度、发生概率和检测难易程度进行权重分配。因而参照传统FMECA中的RPN分析方法，以精密齿轮制造工艺流程为研究对象，并考虑齿轮制造当前工艺水平和工艺改进成本等因素，提出优化优先数分析法从而代替RPN分析法，并结合层次分析法-模糊综合评判的方法对齿轮制造流程的各个工艺参数进行优化优先等级评判并排序。最终根据评判结果，提出对重要工艺参数改进的方案，从而提升精密齿轮产品的可靠性和保障性水平。

关键词: 机械制造工艺与设备, 故障模式影响及危害度分析, 风险优先数, 工艺参数, 齿轮制造流程, 层次分析法-模糊综合评判

Abstract: The traditional failure mode effect and criticality analysis (FMECA) is often used in product risk analysis of failure mode, which does not involve the technological parameter optimization priority analysis of product manufacturing process, and the unreasonable weight distribution of the severity, probability of occurrence and detective difficulty exists in risk priority number (RPN) analysis. A process optimization priority number (POPN) analysis method is proposed by referring to the RPN method of traditional FMECA, taking the manufacturing process of a precision gear as the research object, in which the current technology level and technology improvement cost are considered. And then the optimization priority levels of all technology parameters are evaluated and sequenced based on the analytic hierarchy process fuzzy comprehensive evaluation method. According to the evaluated results, the improvement projects of important technology parameters are presented to increase the reliability and supportability of precision gear products. Key

Key words: machinofaturetechniqueandequipment, FMECA, POPN, technologicalparameter, manufacturingprocess, APHfuzzycomprehensiveevaluationmethod

中图分类号:

TH162⁺.1

李强，谢里阳，李海洋，张芳敏，宋佳昕. 基于模糊综合层次评判法的精密齿轮制造工艺优化优先度分析[J]. 兵工学报, 2017, 38(4): 750-757.

LI Qiang, XIE Li-yang, LI Hai-yang, ZHANG Fang-min, SONG Jia-xin. Optimization Priority Analysis of Precision Gear Manufacturing Process Based on AHP Fuzzy Comprehensive Evaluation Method[J]. Acta Armamentarii, 2017, 38(4): 750-757.

参考文献

［1］ Li Y F, Valla S, Zio E. Reliability assessment of generic geared wind turbines by GTST-MLD model and Monte Carlo simulation［J］. Renewable Energy, 2015, 83:222-233.
［2］ GJB 451A—2005 可靠性维修性保障性术语［S］. 北京：中国人民解放军总装备部，2005.
GJB 451A—2005 Reliability, maintainability and supportability terms［S］. Beijing: General Armament Department of PLA, 2005. (in Chinese)
［3］ GJB 450A—2004 装备可靠性工作通用要求［S］. 北京：中国人民解放军总装备部，2004.
GJB 450A—2004 General requirement for reliability program［S］. Beijing: General Armament Department of PLA, 2004. (in Chinese)
［4］戴城国，王晓红，张新，等. 基于模糊综合评判的电液伺服阀FMECA［J］. 北京航空航天大学学报，2011，37(12)：1575-1578.
DAI Cheng-guo, WANG Xiao-hong, ZHANG Xin, et al. Fuzzy comprehensive evaluation in FMECA of electro-hydraulic servo valve［J］. Journal of Beijing University of Aeronautics and Astronautics, 2011, 37(12): 1575-1578. (in Chinese)
［5］ Bowles J B. An assessment of RPN prioritization in a failure modes effects and criticality analysis［C］∥Proceedings of Annual Reliability and Maintainability Symposium. Tampa Florida, US: IEEE, 2003: 380-386.
［6］陈颖，康锐. FMECA技术及其应用［M］. 北京：国防工业出版社，2014：45-49.
CHEN Ying, KANG Rui. FMECA methodology and applications［M］. Beijing: National Defense Industry Press, 2014: 45-49. (in Chinese)
［7］ PetroviAc＇G2 D V, TanasijeviAc＇G2 M, MiliAc＇G2 V, et al. Risk assessment model of mining equipment failure based on fuzzy logic［J］. Expert Systems with Applications, 2014, 41(18):8157-8164.
［8］ Miller H, Rodríguez G. An integrated fuzzy risk assessment for seaport operations［J］. Safety Science, 2014, 68:180-194.
［9］王梦琦，王端民，杨雪. 基于改进模糊综合评判的航空发动机状态评估［J］. 润滑与密封，2011，36(1)：80-84.
WANG Meng-qi, WANG Duan-min, YANG Xue. Aeroengine performance monitoring based on improved fuzzy synthetic evaluation［J］. Lubrication Engineering, 2011, 36(1): 80-84. (in Chinese)

［10］ Chanamool N, Naenna T. Fuzzy FMEA application to improve decision-making process in an emergency department［J］. Applied Soft Computing, 2016, 43:441-453.
［11］ Ahmad R, Kamaruddin S, Azid I A, et al. Failure analysis of machinery component by considering external factors and multiple failure modes—a case study in the processing industry［J］. Engineering Failure Analysis, 2012, 25:182-192.
［12］肖运启，王昆朋，贺贯举，等. 基于趋势预测的大型风电机组运行状态模糊综合评价［J］. 中国电机工程学报，2014，34(13)： 2132-2139.
XIAO Yun-qi, WANG Kun-peng, HE Guan-ju, et al. Fuzzy comprehensive evaluation for operating condition of large-scale wind turbines based on trend predication［J］. Proceedings of the CSEE, 2014, 34(13): 2132-2139. (in Chinese)
［13］ Wessiani N A, Sarwoko S O. Risk analysis of poultry feed production using fuzzy FMEA［J］. Procedia Manufacturing, 2015, 4(9): 270-281.
［14］曹茂林. 层次分析法确定评价指标权重及Excel计算［J］. 江苏科技信息，2012，35(2)：39-40.
CAO Mao-lin. Evaluation indications weights and Excel calculation based on analytic hierarchy process［J］. Jiangsu Science and Technology Information, 2012, 35(2): 39-40. (in Chinese)
［15］王时龙，孙守利，周杰，等. 滚刀几何误差与齿轮几何精度的映射规律研究［J］. 机械工程学报，2013，49(19)：119-125.
WANG Shi-long, SUN Shou-li, ZHOU Jie, et al. Research on mapping rules of hob geometric errors and gear geometric precision［J］. Journal of Mechanical Engineering, 2013, 49(19): 119-125.(in Chinese)
［16］李辉煌. 田口方法品质设计的原理与实务［M］. 新北：高立图书有限公司，2011.
Lee Huei-huang. Taguchi methods: principles and practices of quality design［M］. New Taipei City: Gau Lih Book Co., Ltd., 2011. (in Chinese)

第38卷
第4期2017 年4月兵工学报ACTA
ARMAMENTARIIVol.38No.4Apr.2017

[1]	张庆军，谢颖，吴松. 基于正交实验与回归分析的机载共形天线吸波涂层厚度预测[J]. 兵工学报, 2021, 42(12): 2693-2699.
[2]	张震，王敏，范华献，刘广志. 基于尺寸预测的激光立体成形30CrNi2MoVA工艺参数研究[J]. 兵工学报, 2020, 41(2): 381-387.
[3]	李龙，李言，杨明顺，陈鑫，李嘉伟. 冷滚打工艺参数对成形力及金属变形影响研究[J]. 兵工学报, 2019, 40(2): 420-429.
[4]	张川，张福隆，李跃峰，刘双宇，薄洪雨，张宏，李彦清. 50CrV钢激光填丝焊焊缝成形多元非线性回归模型[J]. 兵工学报, 2018, 39(11): 2256-2266.
[5]	赵丹丹，焦锋. 基于灰色关联分析的35CrMoV钢活塞杆激光熔覆工艺参数优化[J]. 兵工学报, 2018, 39(10): 2073-2080.
[6]	辛彬，李淑娟，李玉玺. 单晶硅电火花成形加工试验研究与工艺参数优化[J]. 兵工学报, 2017, 38(9): 1854-1861.
[7]	何泽地，田东宁，杨金川，姚智慧. 薄壁球壳真空吸附装夹变形力学分析与控制[J]. 兵工学报, 2017, 38(7): 1409-1415.
[8]	郑建新，刘威成，段玉涛. 7075铝合金二维超声挤压加工表面质量影响因素及其交互作用研究[J]. 兵工学报, 2017, 38(6): 1231-1238.
[9]	陈实现，刘双宇，张宏，李彦清，刘凤德. 激光-电弧复合焊等离子体特性与焊缝熔深相关性研究[J]. 兵工学报, 2017, 38(5): 978-985.
[10]	赵建社，周学德，周旭娇，汪文峰. 带冠整体叶轮电火花加工电极及其运动轨迹同步设计方法[J]. 兵工学报, 2017, 38(4): 744-749.
[11]	林涛, 杨炜, 王健. 基于快速抛光技术的光学元件材料去除模型研究[J]. 兵工学报, 2017, 38(3): 527-533.
[12]	杨臻，张平，蔡志海，秦航. 高强钢激光-电弧复合焊接接头力学性能研究[J]. 兵工学报, 2017, 38(3): 549-554.
[13]	陆益敏，黄国俊，郭延龙，丁方正，陈霞，韦尚方，米朝伟. 激光沉积大面积均匀类金刚石膜的设计改进及实验[J]. 兵工学报, 2017, 38(3): 555-560.
[14]	崔凤奎，凌远非，薛进学，李玉玺，李言，解克各. 花键冷滚打成形表层加工硬化研究[J]. 兵工学报, 2017, 38(2): 358-366.
[15]	张国华，李咚咚，李茂伟，张德远. 超声椭圆振动车削三维形貌形成研究[J]. 兵工学报, 2017, 38(10): 2002-2009.

基于模糊综合层次评判法的精密齿轮制造工艺优化优先度分析

Optimization Priority Analysis of Precision Gear Manufacturing Process Based on AHP Fuzzy Comprehensive Evaluation Method

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

本文评价