Journal of Aerospace System Engineering (항공우주시스템공학회지)

The Society for Aerospace System Engineering (항공우주시스템공학회)
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Development of Korean Condition Based Maintenance Systems to Monitor Naval Weapon Systems

해군 무기체계 한국형 상태진단시스템 발전방향 연구

  • Received : 2016.11.07
  • Accepted : 2016.12.14
  • Published : 2016.12.31
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Abstract

The primary aim for using a Korean Condition Based Maintenance (CBM) system is to maintain military operational readiness using Interactive Collection Analysis Systems (ICAS) installed on naval vessels. Other aims are to preemptively provision maintenance and supply functions, to guarantee economical management of logistical assets, and to implement data driven equipment life cycle management. In order to accomplish these aims, it is necessary to establish standard system conditions. However, because manufacturers do not provide the technology necessary for maintenance management, it is required to retain component performance maps for each piece of equipment, and to accumulate data about frequently occurring fault patterns. This study confirms the validity of component performance maps using micro gas turbines and provides accumulated data on machine break downs. This would allow real time equipment performance checks and present performance trends. Then analysis would provide solutions for maintaining the best machine operating conditions with detailed maintenance manuals for operators. This study is a basis for further research to investigate additional ways to develop CBM using data obtained from naval vessels used in actual military operations.

한국형 상태기준정비는 현재 한국해군 함정에 설치된 ICAS를 최대한 활용하여 전투준비태세를 완비하고, 선제적 정비/보급 지원과 군수자산의 경제적 운용, 데이터 기반 장비수명관리를 위한 것이다. 이러한 목적을 달성하기 위해서는 장비상태의 기준을 설정해야 하는데 이는 제작사에서 원천적인 기술을 제공하고 있지 않아 각 장비별 성능 맵 확보가 필요하고 고장패턴 등의 자료 축적이 필요하다. 본 연구에서는 소형 가스터빈엔진을 활용하여 가스터빈 성능 맵을 확인하고 고장정보를 축적하여 실시간으로 장비성능 확인과 성능 경향을 나타내게 하였고 이를 통해 운용자의 행동지침과 정비자의 검사 절차등을 명시하여 최적의 장비상태가 유지 될 수 있도록 솔루션을 개발하였다. 본 연구를 기반으로 실제 함정의 데이터를 이용한 상태진단기법 발전에 활용할 예정이다.

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References

  1. Jim Davis, "Information Revolution: Using the Information Evolution Model to Grow Your Business" 2006.
  2. Michael DiUlio, "ICAS and Remote Monitoring ; Informational Brief", AMG2CC Workshop, 2015.
  3. Y. G. Li, "GasTurbine Diagnostics", Cranfield University LectureNote. 2004.
  4. Ji. Jhou, "Intelligent Fault Diagnosis With Application to Gas Turbine Engines", Ph. D thesis. The University of Sheffield, 1998.
  5. L.A. Urban, "Gas Path Analysis Applied to Turbine Engine Condition Monitoring", J. of Aircraft, Vol.10, No7, pp.400-406. 1972 https://doi.org/10.2514/3.60240
  6. L. H. Tsoukalas and R. E. Uhrig, "Fuzzy and Neural Approaches in Engineering". John Wiley & Sons, Inc. 1997.
  7. K. W. Oh, H. S. Choi, C. D Kong and H. B. Park, "Research on Naval Weapons Systems MRO by analyzing Aerospace MRO Industry", SASE, Vol.8, No.2, pp.13-20, June, 2014.
  8. C. D. Kong, S. H. Kho, G. S. Park, G. L. Park, "Development of Practical Integral Condition Monitoring System for A Small Turbojet Engine Using SIMULINK and LabVIEW", Journal of the Korean Society of Propulsion Engineers, Vol.17 No.1, 80-88, 2013 https://doi.org/10.6108/KSPE.2013.17.1.080
  9. C. D. Kong, M. C. Kang, G. L. Park "Study on Fault Diagnostics Considering Sensor Noise and Bias of Mixed Flow Type 2-Spool Turbofan Engine using Non-Linear Gas Path Analysis Method and Genetic Algorithms", SASE, Vol.7, No.1, pp.8-18, March, 2013.