Plant Journal (플랜트 저널)

Korea Institute of Plane Engineering and Construction (한국플랜트학회)
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A Study of FEED Verification process of Small Utility Equipment in Offshore plant

해양플랜트 소형 유틸리티장비의 FEED 검증 프로세스에 대한 연구

  • Han, Seong-Jong (Korea Research Institute of Ship & Ocean Engineering(KRISO)) ;
  • Park, Beom (Department of Systems Engineering, Ajou University)
  • 한성종 (선박해양플랜트연구소 해양플랜트산업지원센터) ;
  • 박범 (아주대학교 시스템공학과)
  • Received : 2017.06.09
  • Published : 2017.06.30
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Abstract

This paper is a study on FEED validation model that can be used in the bidding stage of small utility equipment in offshore plant industry using system engineering technique. Currently, domestic marine plant equipment industry companies are faced with the financial risk of project execution as they enter marine plant. The major cause was the insufficient ability to verify the FEED output from the contractor (Engineering or Procurement and Construction) of the equipment manufacturer (COMPANY or EPC). Therefore, we propose FEED design verification method that simplifies the system engineering method that sequentially applies requirements analysis, function, performance analysis and physical architecture building process. Also, we verified the suitability of the developed model by comparing the results of applying the developed FEED verification model and the verification method that depends on the existing experience for the small utility equipment (Air Compressor).

본 논문은 시스템엔지니어링기법을 이용하여 해양플랜트 산업의 소형 유틸리티 장비의 입찰단계에서 사용가능한 FEED 검증 수행모델에 대한 연구이다. 현재 국내 해양플랜트 기자재산업계는 해양플랜트에 진출하면서 프로젝트 수행에 따른 재정적 위험에 직면한 상태이며, 그 주요한 원인으로 기자재업체의 발주처(COMPANY 또는 EPC: Engineering, Procurement and Construction) 로부터 제공받은 FEED 결과물에 대한 검증능력부족으로 조사되었다. 이에 요구사항 분석, 기능, 성능분석 및 물리적아키텍처 구축프로세스를 순차적으로 적용하는 시스템 엔지니어링 기법을 간략화 한 FEED 설계 검증방법을 제안하고 이를 소형 유틸리티 장비(Air Compressor)를 대상으로 기존의 경험에 의존한 검증방법과 개발한 FEED 검증 모델을 적용한 결과를 비교함으로써 개발된 모델의 사용적정성을 검증하였다.

Keywords

References

  1. API(America Petroleum Institute), 2017, API RP 17A: Design and Operation of Subsea Production Systems-General Requirements and Recommendation.
  2. INCOSE(International Council on Systems Engineering),2012, Systems Engineering Handbook: A Guide for System Life Cycle Processes and Activities, version 3.2.2. San Diego, CA, USA:), INCOSE-TP-2003-002-03.2.2.
  3. ISO/IEC 15288, 2008, Systems and Software Engineering-System Life Cycle process, International Organization for Standardization (ISO).
  4. Kee-young, Dae Geu Hong, Soo Chel Yoon and SukHwan Suh. 2014. "A Study on Application of Systems Engineering Approach to Designing Continuous Casting System". Journal of the Korea Society o f Systems Engineering, Vol. 10, no. 2, pp. 15-20. https://doi.org/10.14248/JKOSSE.2014.10.2.015
  5. Sun Young Kim, Jae-Min Cha, Junpil Kim, Suk-Hwan Suh1, and Hwal Won Sur1, 201, "A Systems Engineering Approach to FEED Work Process Development for Refinery Plant," Journal of the Korea Society of Systems Engineering, Vol 10, No, 1, pp. 1-15, https://doi.org/10.14248/JKOSSE.2014.10.1.001
  6. Wan Wook Ki, Jun Pil Kim, Dae Geun Hong, and Suk-Hwan Suh, 2013, "A Study on Application of Systems Engineering Technical Process to FEED in Plant construction Industry - focused on a case of Environmental Plant," Journal of the Korea Society of Systems Engineering, vol. 9, no. 2, pp. 37-53 https://doi.org/10.14248/JKOSSE.2013.9.2.037
  7. Sirous Yasseri, 2014, "Application of Systems engineering to subsea development, Underwater Technology,"Vol. 32, no. 2, pp. 93-109 https://doi.org/10.3723/ut.32.093
  8. K.Dykes and R.Meadows, 2011, Applications of Systems Engineering to the Research, Design, and Development of Wind Energy Systems Technical Report NREL/TP-5000-52616