“Soft” Considerations in Equipment Selection for Building Construction Projects
Publication: Journal of Construction Engineering and Management
Volume 133, Issue 10
Abstract
This paper raises the issue of “soft” considerations in the selection of equipment for building construction projects. The paper aims at increasing the awareness: (1) to the nature, variety, and richness of soft factors; (2) to their significant role and potential impact on the outcome of decision making; and (3) to the inherent difficulty of evaluating them and integrating them within a comprehensive selection process. Existing state-of-the-art equipment selection models were analyzed and found to be inadequate in terms of both considering soft factors and providing mechanisms for their systematic evaluation. Six cases of large-size, complex construction projects were investigated to obtain an extensive list of typical soft factors. This investigation revealed that the consideration of soft factors in current practices is essentially unstructured and is not integrated within the selection process in a systematic manner. A desirable selection process is outlined that generally responds to the needs identified in the study. The proposition of a specific method for the quantitative treatment of soft factors and their tradeoff with cost factors is the subject of another paper.
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Acknowledgments
The writers gratefully acknowledge the support of the Technion V.P.R. Fund—M. and C. Papo Research Fund.
References
Al-Hussein, M., Alkass, S., and Moselhi, O. (2000). “D-CRANE: Database system for utilization of cranes.” Can. J. Civ. Eng., 27(6), 1130–1138.
Al-Hussein, M., Alkass, S., and Moselhi, O. (2001). “An algorithm for mobile crane selection and location on construction sites.” Constr. Innovation, 1(1), 91–105.
Alkass, S., Aronian, A., and Moselhi, O. (1993). “Computer-aided equipment selection for transporting and placing concrete.” J. Constr. Eng. Manage., 119(3), 445–465.
Choi, C. W., and Harris, F. C. (1991). “A model for determining optimum crane position.” ICE Proc., 90(3), 627–634.
Cooper, C. N. (1987). “Cranes—A rule-based assistant with graphics for construction planning engineers.” The application of artificial intelligence techniques to civil and structural engineering, Civil Comp Press, Edinburgh, U.K., 47–54.
Cranimax. (2006). “Cranimation and TowerManagement: Software for crane job site planning.” Cranimax GmbH, Zweibrücken, Germany, ⟨http://cranimation.org⟩.
Dickie, D. E. (1981). Crane handbook, Rev. Ed., Construction Safety Association of Ontario, D. Short, ed., Butterworths, London.
Dieleman, B. (2002). “Selecting a tower crane.” Cranes Today, 327, 31.
Dun & Bradstreet (D&B). (2003). “Dun’s 100. Construction, development, and infrastructure companies.” Israel, ⟨http://duns100.dundb.co.il/⟩.
Edwards, D., Holt, G., and Harris, F. (1998). “Maintenance management of heavy duty construction plant and equipment.” Current and future construction plant research, Chandos Publishing, Oxford, U.K., 121–124.
Farrell, C. W., and Hover, K. C. (1989). “Computerized crane selection and placement for the construction site.” Proc., 4th Int. Conf. on Civil and Structural Engineering Computing, B. H. V. Topping, ed., Vol. 1, Civil Comp Press, Edinburgh, U.K., 91–94.
Furusaka, S., and Gray, C. (1984). “Model for the selection of the optimum crane for construction sites.” Constr. Manage. Econom., 2(2), 157–176.
Goldenberg, M. (2002). “Analytic-hierarchy-process-based model for equipment selection in construction projects.” MSc thesis, Technion-Israel Institute of Technology, Haifa, Israel.
Goldenberg, M., and Shapira, A. (2007). “Systematic evaluation of construction equipment alternatives: case study.” J. Constr. Eng. Manage., 133(1), 72–85.
Gray, C. (1987). “Crane location and selection by computer.” Proc., 4th Int. Symp. Robotics and Artificial Intelligence in Building Construction, Vol. 1, Haifa, Israel, 163–167.
Gray, C., and Little, J. (1985). “A systematic approach to the selection of an appropriate crane for a construction site.” Constr. Manage. Econom., 3(2), 121–144.
Hanna, A. S., and Lotfallah, W. B. (1999). “A fuzzy logic approach to the selection of cranes.” Autom. Constr., 8(5), 597–608.
Harris, F., and McCaffer, R. (2001). Modern construction management, 5th Ed., Blackwell Science, Oxford, U.K.
Hornaday, W. C., Haas, C. T., O’Connor, J. T., and Wen, J. (1993). “Computer-aided planning for heavy lifts.” J. Constr. Eng. Manage., 119(3), 498–515.
Illingworth, J. R. (1993). Construction methods and planning, E & FN Spon, London.
King, C., and Schexnayder, C. J. (2002). “Tower crane selection at Jonathon W. Rogers Surface Water Treatment Plant expansion.” Pract. Period. Struct. Des. Constr., 7(1), 5–8.
LiftPlanner Software. (2006). “LiftPlanner: 3D crane and rigging lift planning software.” Burnsville, Minn., www.liftplanner.net .
Lin, K.-L., and Haas, C. T. (1996a). “An interactive planning environment for critical operations.” J. Constr. Eng. Manage., 122(3), 212–222.
Lin, K.-L., and Haas, C. T. (1996b). “Multiple heavy lifts optimization.” J. Constr. Eng. Manage., 122(4), 354–362.
Meehan, J. (2005). “Computerize to organize.” Cranes Today, 369, 50.
North Cascade Industrial (NCI). (2006). “Compu-Crane CSPS/LPS: Crane selection and lift planning software.” Seattle, www.ncisoftware.com .
Peurifoy, R. L., Schexnayder, C. J., and Shapira, A. (2006). Construction planning, equipment, and methods, 7th Ed., McGraw-Hill, Boston.
Proctor, J. R. (1995). “Selecting tower cranes.” Civ. Eng. (N.Y.), 65(2), 52–56.
Proverbs, D. G., Olomolaiye, P. O., and Harris, F. C. (1996). “An evaluation of transportation systems for high rise concrete construction.” Build. Environ., 31(4), 363–374.
Sawhney, A., and Mund, A. (2001). “IntelliCranes: An integrated crane type and model selection system.” Constr. Manage. Econom., 19(2), 227–237.
Sawhney, A., and Mund, A. (2002). “Adaptive probabilistic neural network-based crane type selection system.” J. Constr. Eng. Manage., 128(3), 265–273.
Selinger, S., and Shapira, A. (1987). Construction equipment. Vol. II— Lifting and handling, Building Research Station, Technion, Haifa, Israel.
Shapira, A., and Glascock, J. D. (1996). “Culture of using mobile cranes for building construction.” J. Constr. Eng. Manage., 122(4), 298–307.
Shapira, A., and Goldenberg, M. (2005). “AHP-based equipment selection model for construction projects.” J. Constr. Eng. Manage., 131(12), 1263–1273.
Shapira, A., and Schexnayder, C. J. (1999). “Selection of mobile cranes for building construction projects.” Constr. Manage. Econom., 17(4), 519–527.
Shapiro, H. I., Shapiro, J. P., and Shapiro, L. K. (2000). Cranes and derricks, 3rd Ed., McGraw-Hill, New York.
Tam, C. M., Tong, T. K. L., and Chan, W. K. W. (2001). “Genetic algorithm for optimizing supply locations around tower crane.” J. Constr. Eng. Manage., 127(4), 315–321.
Varghese, K., Dharwadkar, P., Wolfhope, J., and O’Connor, J. T. (1997). “A heavy lift planning system for crane lifts.” Microcomput. Civ. Eng., 12(1), 31–42.
Warszawski, A. (1990). “Expert system for crane selection.” Constr. Manage. Econom., 8(2), 179–190.
Warszawski, A., and Peled, N. (1987). “An expert system for crane selection and location.” Proc., 4th Int. Symp. Robotics and Artificial Intelligence in Building Construction, Vol. 1, Haifa, Israel, 64–75.
Zhang, P., Harris, F. C., Olomolaiye, P. O., and Holt, G. D. (1999). “Location optimization for a group of tower cranes.” J. Constr. Eng. Manage., 125(2), 115–122.
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© 2007 ASCE.
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Received: Jun 17, 2003
Accepted: Dec 19, 2006
Published online: Oct 1, 2007
Published in print: Oct 2007
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