Research and Development for Preventive Maintenance-based Ship Grade Repair Decision-making Systems

doi:10.3969/j.issn.1004-132X.2022.04.012

Abstract

Abstract: The traditional periodic maintenance strategy often led to under-maintenance and over-maintenance of the ship equipment. To improve the scientificity of maintenance decision， a ship grade repair decision method was proposed based on the concept of preventive maintenance. According to the technical status and maintenance information of ship equipment， the failure mode and effectiveness analysis of key important components were carried out to determine their repair demand level and repair scope； meanwhile， the Weibull distribution model and the maximum likelihood estimation method were used to predict the median life of the equipment， and the production rules were defined； then， based on the three-level repair BOM structure of ship-system-critical parts， logic decision and rule reasoning were conducted from bottom to top to determine the repair grade and timing of the entire ship. A ship grade repair decision system was developed and functionally verified by cases， which might meet the application requirements of autonomous decision for ship grade repair and provide a feasible way for preventive maintenance of ships.

Key words: preventive maintenance, grade repair, maintenance decision, failure prediction, Weibull distribution, ship equipment

摘要： 传统的定期维修策略常导致舰船装备欠维修和过维修。为提高维修决策的科学性，提出了一种基于预防性维修理念的舰船等级修理决策方法。根据舰船装备的技术状态和维修信息，对关键重要部件（简称关重件）进行失效模式和效果分析，确定其修理需求级别和修理范围；同时采用威布尔分布模型和极大似然估计法预测装备的中位寿命，并定义产生式规则；进而基于舰船-系统-关重件三级维修BOM结构，自下而上地进行逻辑决断和规则推理，确定整舰的修理等级和时机。在此基础上开发了舰船等级修理决策系统，并通过案例进行功能验证，该系统可以满足舰船等级修理自主决策的应用需求，为舰船的预防性维修提供了一种可行的途径。

关键词: 预防性维修, 等级修理, 维修决策, 故障预测, 威布尔分布, 舰船装备

CLC Number:

SONG Tingxin, HAN Guochen. Research and Development for Preventive Maintenance-based Ship Grade Repair Decision-making Systems [J]. China Mechanical Engineering, 2022, 33(04): 496-503.

宋庭新, 韩国晨. 基于预防性维修的舰船装备等级修理决策系统研究[J]. 中国机械工程, 2022, 33(04): 496-503.

References

［1］阮旻智. 舰船装备维修决策建模与优化技术［M］. 北京：科学出版社， 2018：1-24.
RUAN Minzhi. Ship Equipment Maintenance Decision Modeling and Optimization Technology［M］. Beijing：Science Press， 2018：1-24.
［2］黎汉军，王乐，陈捷捷，等. 基于预防为主的舰船修理质量设计［J］. 船舶工程， 2017， 39（S1）：286-289.
LI Hanjun， WANG Le， CHEN Jiejie， et al. Ship Management Quality Design Based on Prevention First［J］. Ship Engineering， 2017， 39（S1）：286-289.
［3］李宣池，胡俊波，张志华. 考虑修理结构的舰船部署能力仿真［J］. 中国舰船研究， 2015， 10（5）：123-128.
LI Xuanchi， HU Junbo， ZHANG Zhihua. Simulation Analysis of Warship Deploy Ability with Maintenance Structures Involved［J］. Chinese Journal of Ship Research， 2015， 10（5）：123-128.
［4］朱石坚. 舰船等级修理模式改革研究与实践［J］. 中国工程科学， 2015， 17（5）：4-9.
ZHU Shijian. Research and Practice on the Reform of Scheduled Maintenance Mode of Warship［J］. Engineering Sciences， 2015， 17（5）：4-9.
［5］刘佳，杨建军，谢宗仁. 面向任务的舰船装备预防性维修规划模型研究［J］. 中国造船， 2016， 57（4）：157-163.
LIU Jia， YANG Jianjun， XIE Zongren. Research on Task Oriented and Preventive Maintenance Planning Model for Ship Equipment［J］. Shipbuilding of China， 2016， 57（4）：157-163.
［6］吕瑞，孙林夫. 基于多源信息融合故障树与模糊Petri网的复杂系统故障诊断方法［J］. 计算机集成制造系统， 2017， 23（8）：1817-1831.
LYU Rui， SUN Linfu. Fault Diagnosis Method of Complex System Based on Multi-source Information Fusion Fault Tree and Fuzzy Petri Net［J］. Computer Integrated Manufacturing Systems， 2017， 23（8）：1817-1831.
［7］CICEK K， CELIK M. Application of Failure Modes and Effects Analysis to Main Engine Crankcase Explosion Failure On-board Ship［J］. Safety Science， 2013， 51（1）：6-10.
［8］CULLUM J， BINNS J， LONSDALE M， et al. Risk-based Maintenance Scheduling with Application to Naval Vessels and Ships［J］. Ocean Engineering， 2018， 148：476-485.
［9］马珍杰. 基于维修的舰船装备自然寿命评估［J］. 舰船科学技术， 2015， 37（4）：232-235.
MA Zhenjie. The Natural Life Evaluation of Warship Equipment Based on Maintenance［J］. Ship Science and Technology， 2015， 37（4）：232-235.
［10］SIDIBE I， KATHAB A， ADIALLAH K. Reliability and Preventive Maintenance Analysis of Weibull Distributed Lifetime Systems［J］. IFAC Proceedings Volumes， 2013， 46（7）：306-311.
［11］NGUYEN K， MEDJAHER K. A New Dynamic Predictive Maintenance Framework Using Deep Learning for Failure Prognostics［J］. Reliability Engineering & System Safety， 2019，188:251-262.
［12］罗忠，周欣，史跃东. 基于军事需求和装备维修需求的舰船修理结构设计方法研究［J］. 海军工程大学学报（综合版）， 2018， 15（4）：60-64.
LUO Zhong， ZHOU Xin， SHI Yuedong. Research on Method of Warship Maintenance Structure Designing Based on Requirement of Assignment and Maintenance［J］. Journal of Naval University of Engineering， 2018， 15（4）：60-64.
［13］GEUM Y， CHO Y， PARK Y. A Systematic Approach for Diagnosing Service Failure：Service-specific FMEA and Grey Relational Analysis Approach［J］. Mathematical & Computer Modelling， 2011， 54（11/12）：3126-3142.
［14］BAPTISTA M， SANKARARAMAN S， MEDEIROS I D， et al. Forecasting Fault Events for Predictive Maintenance Using Data-driven Techniques and ARMA Modeling［J］. Computers & Industrial Engineering， 2018， 115：41-53.
［15］KAI G， CELAYA J， SANKARARAMAN S， et al［M］. Prognostics：The Science of Making Predictions， 2017.
［16］张友鹏，杨凯雄，石磊. 可靠度约束下不完全预防性维护经济优化模型［J］. 计算机集成制造系统， 2018， 24（12）：3019-3026.
ZHANG Youpeng， YANG Kaixiong， SHI Lei. Economic Optimization Model for Imperfect Preventive Maintenance under Reliability Constraints［J］. Computer Integrated Manufacturing Systems， 2018， 24（12）：3019-3026.
［17］石慧，曾建潮. 基于寿命预测的预防性维护维修策略［J］. 计算机集成制造系统， 2014， 20（5）：1133-1140.
SHI Hui， ZENG Jianchao. Preventive Maintenance Strategy Based on Life Prediction［J］. Computer Integrated Manufacturing Systems， 2014， 20（5）：1133-1140.
［18］ZHU T. Reliability Estimation for Two-parameter Weibull Distribution under Block Censoring［J］. Reliability Engineering and System Safety， 2020， 203：107071.
［19］邹争，董从林，袁成清，等. 基于二参数威布尔分布的水润滑橡胶尾轴承可靠性寿命分析［J］. 舰船科学技术， 2015， 37（2）：48-52.
ZOU Zheng， DONG Conglin， YUAN Chengqing， et al. Analysis Reliability Life of Water Lubricated Rubber Stern Tube Bearing Based on Two-parameter Weibull Distribution［J］. Ship Science and Technology， 2015， 37（2）：48-52.

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