Tower Crane Cycle Times: Case Study of Remote-Control versus Cab-Control Operation
Publication: Journal of Construction Engineering and Management
Volume 140, Issue 12
Abstract
Tower cranes commonly constitute the bottleneck of production on today’s typical building construction projects, so shortening of crane cycle durations is often the key to increased site productivity. This case study examined one potential determinant of cycle duration that has been largely overlooked in the wide body of cycle time research, which is the operation mode (OM) of top-slewing tower cranes: from the cab or by remote control. This knowledge gap was addressed by providing quantitative substantiation to qualitative evaluations regarding the advantages and disadvantages of both OMs. The results revealed that there prevail certain conditions under which the two OMs may yield identical cycle times or even give remote operation an advantage. The study also identified that it is the balance between the fast-travel part of the cycle and the fine-maneuvering part that determines which of the two OMs will generate shorter cycle times. These findings will be useful for construction professionals who are charged with the task of selecting the OM best suited for their project when both OMs are optional or when assessing the cost of using a dictated OM. Equally important is the contribution for scholars of crane work as offered by the research method used in this study.
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Acknowledgments
The authors thank the companies and individuals whose cooperation enabled the realization of this study: the construction company, the project manager and his team, and the two crane operators who participated in the study.
References
Aebi, W. (2012). “On the rail, safe into the height.” Die Baustellen, 10, 40–41.
Alkriz, K., and Mangin, J.-C. (2005). “A new model for optimizing the location of cranes and construction facilities using genetic algorithms.” Proc., 21st Annual ARCOM Conf., F. Khosrowshahi, ed., Vol. 2, ARCOM, U.K., 981–991.
Backhouse, C. J., Price, R. A., and Moore, P. R. (1994). “Crane automation.” Ind. Robot, 21(4), 22–25.
Bishop, P. (2006). “Rising towers.” Cranes Access, 8(4), 25–27.
Construction Plant-Hire Association (CPA). (2007). “Safe use of top slew tower cranes.”, Tower Crane Interest Group, London, U.K.
Dalrymple, W. (2003). “Self help.” Cranes Today, 345, 36–41.
Dalrymple, W. (2008). “A short history of tower crane remotes.” Cranes Today, 401, 41–42.
Elsilä, M., Koskela, L., Lempinen, H., Pieskä, S., and Salo, E. (1988). “An integrated approach to the development of construction site crane operation.” Proc., 5th Int. Symp. on Robotics in Construction, Tokyo, Japan, 643–652.
Everett, J. G., and Slocum, A. H. (1993). “CRANIUM: Device for improving crane productivity and safety.” J. Constr. Eng. Manage., 23–39.
Greeman, A. (2002). “Handy systems.” Cranes Today, 336, 33–39.
Huang, C., Wong, C. K., and Tam, C. M. (2011). “Optimization of tower crane and material supply locations in high-rise building site by mixed-integer linear programming.” Autom. Constr., 20(5), 571–580.
International Labor Organization (ILO). (1992). Introduction to work study, 4th Ed., ILO, Geneva, Switzerland.
Israel Institute for Occupational Safety and Hygiene (IIOSH). (2001). “Safety in operating tower cranes by remote control.” Safety and Hygiene, Newsletter 378, Tel Aviv, Israel.
Kang, S.-C., Chi, H.-K., and Miranda, E. (2009). “Three-dimensional simulation and visualization of crane assisted construction erection processes.” J. Comput. Civ. Eng., 363–371.
Lee, G., et al. (2012). “A BIM- and sensor-based tower crane navigation system for blind lifts.” Autom. Constr., 26(1), 1–10.
Lee, U.-K., Kang, K.-I., Kim, G.-H., and Cho, H.-H. (2006). “Improving tower crane productivity using wireless technology.” Comput.-Aided Civ. Infrastruct. Eng., 21(8), 594–604.
Leung, A. W. T., and Tam, C. M. (1999a). “Models for assessing hoisting times of tower cranes.” J. Constr. Eng. Manage., 385–391.
Leung, A. W. T., and Tam, C. M. (1999b). “Prediction of hoisting time for tower cranes for public housing construction in Hong Kong.” Constr. Manage. Econ., 17(3), 305–314.
Leung, A. W. T., Tam, C. M., and Liu, D. K. (2001). “Comparative study of artificial neural networks and multiple regression analysis for predicting hoisting times of tower cranes.” Build. Environ., 36(4), 457–467.
Li, H., Chan, G., and Skitmore, M. (2013). “Integrating real time positioning systems to improve blind lifting and loading crane operations.” Constr. Manage. Econ., 31(6), 596–605.
Mundel, M. E. (1985). Motion and time study, 6th Ed., Prentice-Hall, Englewood Cliffs, NJ.
National Standards Authority of Ireland (NSAI). (2013). “Code of practice for the safe use of tower cranes and self-erecting cranes.”, Dublin, Ireland.
NCCCO. (2008). “NCCCO launches signalpersons certificate.” Cranes today, 〈http://www.cranestodaymagazine.com/story.asp?storycode=2051090〉 (Apr. 23, 2013).
Neitzel, R. L., Seixas, N. S., and Ren, K. K. (2001). “A review of crane safety in the construction industry.” Appl. Occup. Environ. Hyg., 16(12), 1106–1117.
New South Wales Government (NSW). (2010). “Remotely operated tower cranes: Safety alert.” WC02823, 〈http://www.workcover.nsw.gov.au〉 (Apr. 23, 2013).
Price, A. D. F., and Harris, F. C. (1992). “Methods of measuring production times for construction work.” The practice of site management, P. A. Harlow, ed., Vol. 4, The Chartered Institute of Building, Ascot, Berkshire, U.K., 143–156.
“Prokrania’s tower crane lift secures CE certification.” (1998). Cranes Today, 289, 63.
Rodriguez-Ramos, W., and Francis, R. (1983). “Single crane location optimization.” J. Constr. Eng. Manage., 387–397.
Rosenfeld, Y. (1995). “Automation of existing cranes: From concept to prototype.” Autom. Constr., 4(2), 125–138.
Rosenfeld, Y., and Shapira, A. (1998). “Automation of existing tower cranes: Economic and technological feasibility.” Autom. Constr., 7(4), 285–298.
Sacks, R., Navon, R., Brodetskaia, I., and Shapira, A. (2005). “Feasibility of automated monitoring of lifting equipment in support of project control.” J. Constr. Eng. Manage., 604–614.
Sailer, J. (2012). “Personnel hoists on tower cranes: Current and future thinking.” 2nd Int. Tower Cranes Conf. ITC 2012, 〈http://www.khl.com/events/itc2012/speaker-presentations〉 (May 6, 2013).
Shapira, A., Lucko, G., and Schexnayder, C. (2007). “Cranes for building construction projects.” J. Constr. Eng. Manage., 690–700.
Shapira, A., and Lyachin, B. (2009). “Identification and analysis of factors affecting safety on construction sites with tower cranes.” J. Constr. Eng. Manage., 24–33.
Shapira, A., Rosenfeld, Y., and Mizrahi, I. (2008). “Vision system for tower cranes.” J. Constr. Eng. Manage., 320–332.
Shapira, A., and Simcha, M. (2009). “Measurement and risk scales of crane-related safety factors on construction sites.” J. Constr. Eng. Manage., 979–989.
Standards Australia (SA). (2004). “Cranes, hoists and winches—Safe use, Part 4: Tower cranes.” AS 2550.4, Sydney, Australia.
Tam, C., Leung, A., and Liu, D. (2002). “Nonlinear models for predicting hoisting times of tower cranes.” J. Comput. Civ. Eng., 76–81.
Tam, C., Tong, T., and Chan, W. (2001). “Genetic algorithm for optimizing supply locations around tower crane.” J. Constr. Eng. Manage., 315–321.
Tam, C. M., and Tong, T. K. L. (2003). “GA-ANN model for optimizing the locations of tower crane and supply points for high-rise public housing construction.” Constr. Manage. Econ., 21(3), 257–266.
“Towers above.” (2001). Cranes Today, 315, 38–41.
“Under control.” (2012). Cranes Today, 453, 53–56.
Xu, F., Song, Y., and Hu, H. (2012). “Application of cycle-based simulation to estimate loss of logistics productivity on construction sites.” Proc., 3rd Int. Conf. on Computational Logistics ICCL 2012, Springer, Berlin, 159–170.
Yang, J., Vela, P., Teizer, J., and Shi, Z. (2014). “Vision-based tower crane tracking for understanding construction activity.” J. Comput. Civ. Eng., 103–112.
Zhang, P., Harris, F., Olomolaiye, P., and Holt, G. (1999). “Location optimization for a group of tower cranes.” J. Constr. Eng. Manage., 115–122.
Zhang, P., Harris, F. C., and Olomolaiye, P. O. (1996). “A computer-based model for optimizing the location of a single tower crane.” Build. Res. Inf., 24(2), 113–123.
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© 2014 American Society of Civil Engineers.
History
Received: Jul 23, 2013
Accepted: Jun 2, 2014
Published online: Jul 8, 2014
Published in print: Dec 1, 2014
Discussion open until: Dec 8, 2014
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