Journal of the Architectural Institute of Korea Structure & Construction (대한건축학회논문집:구조계)

Architectural Institute of Korea (대한건축학회)
권호 표지
DOI QR코드

DOI QR Code

Tower Crane Location and Capacity Selection Model for the Mid-to-high-rise Modular Construction

중고층 모듈러 건축공사 타워크레인 위치 및 제원 선정 모델 개발

  • Received : 2016.09.13
  • Accepted : 2016.11.24
  • Published : 2016.11.30
⟨ Previous Next ⟩

Abstract

Modular construction is a construction method with the production work in factory and the installation work in field. Especially the lifting work is a large part that requires for the installation of modular units in the field work. The exact lifting work forecast in the initial phase of the project lead to calculate the optimum construction period and cost. However, existing lifting equipment selection is performed on the intuition and the experience. So, there is a need for the objective and logical lifting equipment selection tool. In this study, proposed a model that can be the selection of the optimum of the tower crane through the relationship of three variables(tower crane, installation module unit, transport trailer) that affect the lifting work. It was possible to determine the amount of appropriate levels of tower crane according to the optimum position selection of tower crane and transport trailer. In the future, used in a modular building project to sharing information between the designers and builders in the early stage of the project, can help make the optimum lifting plan.

Keywords

Acknowledgement

Supported by : 국토교통부

References

  1. Chae H. D. (2002). Development of Tower Crane Planning Process in High-rise Building Projects, Doctoral dissertation, Seoul National University.
  2. Cho J. H., & Cho H. G. (2009). An Analysis Of Optimized Super Tall Building Tower Crane Selection Which Related With Project Construction Period. JOURNAL OF THE KOREA INSTITUTE OF BUILDING CONSTRUCTION, 9(6), 131-139.
  3. Chun J. Y., & Oh S. J. (2003). Constitutional Directions of Decision Support Process for Cooperative Design in Architectural Design Phase. JOURNAL OF THE ARCHITECTURAL INSTITUTE OF KOREA Structure & Construction, 19(11), 173-180.
  4. Gwak, H. S., Yi, C. Y., & Lee, D. E. (2014). Methodology for Selecting Optimal Earthmoving Haul-Routes using Genetic Algorithm. JOURNAL OF THE ARCHITECTURAL INSTITUTE OF KOREA Structure & Construction, 30(3), 141-150. https://doi.org/10.5659/JAIK_SC.2014.30.3.141
  5. Han S. M, Baek S. W., Jo S. Y., Lee D. W., & Kim H. D. (2008). Optimization of the Satellite Mission Scheduling Using Genetic Algorithms. Journal of The Korean Society for Aeronautical and Space Sciences, 36(12), 1163-1170. https://doi.org/10.5139/JKSAS.2008.36.12.1163
  6. Ho, J. K., Kim, S. K., & Kook, D. H. (2007). A System for the Selection of the Optimum Tower Cranes (Opt-TC). Korean Journal of Construction Engineering and Management, 8(6), 216-226.
  7. Jeong, Y. S., Kim, K. W., & Lim, S. H. (2015). Evaluation of the Environmental Performance of the Prefabricated Modular Housing using Mock-up Models. Journal of Korean Institute of Architectural Sustainable Environment and Building Systems, 9(2), 128-133.
  8. Joo J. H., Lee D. C., & Shin H. S. (1994). A Study on the Crane Location Optimization in the High-rise building Construction. JOURNAL OF THE ARCHITECTURAL INSTITUTE OF KOREA Structure & Construction, 14(1), 491-981.
  9. Kim D. J., Song Y. S., & Lim H. C. (2002). Rationalization the Lift car Planning Method in a High-rise Building Project. Proceeding of annual conference of the architectural institute of Korean, 22(2), 483-486.
  10. Kim J. J. (2003). A Study on the Hoisting Planning System in Highrise Building Construction, Doctoral dissertation, Myungji University.
  11. Kim K. J., Kim K. M., & Lee S. K. (2009). Optimization of Multiple Tower Cranes and Material Stockyards Layout. Korea Journal of Construction Engineering and Management, 10(6), 127-134.
  12. Kim M. J., Park M. S., Lee H. S., Lee J. H. & Hyun H. S. (2014). The Activation Plan of Modular Construction in Educational Facilities using QFD. Korea Journal of Construction Engineering and Management Conference Proceeding 11, 113-114.
  13. Kim M. J., Park M. S., Lee H. S., Lee J. H. & Lee K. P. (2015). Development of Manufacturing Planning for Multi Modular Construction Project based on Genetic-Algorithm. Korea Journal of Construction Engineering and Management, 16(5), 54-64
  14. Lee H. S., Chae H. D., & Jang M. H. (2002). Development of Tower Crane Planning Process in High-rise Building Projects. JOURNAL OF THE ARCHITECTURAL INSTITUTE OF KOREA Structure & Construction, 18(6), 119-126.
  15. Lee M. D., Won M. K., Lee U. K., Cho H. H., & Kang K. I. (2014). Integrated Lifting Model of Planning and Operation for Finishing Works in Tall Building Construction. JOURNAL OF THE ARCHITECTURAL INSTITUTE OF KOREA Structure & Construction, 30(5), 125-133. https://doi.org/10.5659/JAIK_SC.2014.30.5.125
  16. Lee S. W. (2011). Efficient Genetic Algorithm for Resource Constrained Project Scheduling Problem. JOURNAL OF THE KOREA CONTENTS ASSOCIATION, 11(6), 59-66. https://doi.org/10.5392/JKCA.2011.11.6.059
  17. Lee U. K., Kim J. Y., Seo D. S., & Kang K. I. (2004). Genetic Algorithms of Planning Transportation - Focused on Tower Crane -. JOURNAL OF THE ARCHITECTURAL INSTITUTE OF KOREA Structure & Construction, 20(2), 127-134.
  18. Lee Y. (1993). A Study on the Towercrane Locationwith Efficient planing of lifting, Master's thesis of Science Engineering, Hanyang University
  19. Leung. A. W., & Tam, C. M. (1999). Models forassessing hoisting times of tower cranes. Journal ofconstruction engineering and management, 125(6),385-391. https://doi.org/10.1061/(ASCE)0733-9364(1999)125:6(385)
  20. Oh K. S. (2004). A study on the Efficient cooperativedesign method of specialty-fields for building project, Master's thesis, Chung-Ang University.
  21. Park M. S., Yang Y. J., Lee H. S., Han S. W., & Ji S.H. (2011). Korea Journal of Construction Engineeringand Management. Korea Journal of ConstructionEngineering and Management, 12(1), 43-52. https://doi.org/10.6106/KJCEM.2011.12.1.43
  22. Rodriguez-Ramos. W. E., & Francis, R. L. (1983).Single crane location optimization. Journal of Construction Engineering and Management, 109(4),387-397. https://doi.org/10.1061/(ASCE)0733-9364(1983)109:4(387)
  23. Tam, C. M., Tong, T. K., & Chan, W. K. (2001).Genetic algorithm for optimizing supply locations around tower crane. Journal of construction engineering andmanagement, 127(4), 315-321. https://doi.org/10.1061/(ASCE)0733-9364(2001)127:4(315)
  24. Zhang, P., Harris, F. C., Olomolaiye, P. O., & Holt, G.D. (1999). Location optimization for a group of tower cranes. Journal of construction engineering and management, 125(2), 115-122. https://doi.org/10.1061/(ASCE)0733-9364(1999)125:2(115)
  25. Homepage of Jade Cheng(2016.9.1.)(http://jade-cheng.com/au/coalhmm/optimization/)
  26. Homepage of Tufts University School of Engineering(2016.9.1)(http://www.cs.tufts.edu/comp/131/classpages/)