Hazardous Proximity Zone Design for Heavy Construction Excavation Equipment
Publication: Journal of Construction Engineering and Management
Volume 142, Issue 6
Abstract
The construction industry continues to be among the leading industries for workplace fatalities in the United States. After experiencing 824 fatal injuries in 2013, the construction industry ranks as one of the most dangerous work environments when compared with other private industrial sectors in the United States. Conditions of construction sites often produce hazardous proximity situations by requiring pedestrian workers and heavy equipment to operate at close proximity. Injury and fatality statistics indicate that current safety practices of construction workers have proven inadequate. The research aims to design hazard zone around pieces of heavy construction equipment in which site personnel should not enter during construction operations. The scope is limited to construction sites and equipment at a horizontal grade and hazards between heavy construction excavation equipment and workers-on-foot. A framework for creating the hazard zone around a piece of construction equipment is presented including detailed methodology discussions for each step. A user interface is also presented that automatically creates a hazard zone around select pieces of construction equipment based on user-defined parameters. The hazard zone for a dump truck, excavator, and backhoe are shown using the created framework. Results indicate that hazard zones for pedestrian workers can be created around construction equipment to increase hazard awareness for workers. Contributions for this research include a user-friendly hazard zone creation tool and database for safety managers and scientific evaluation data of the created hazard zone framework. Safety standards can be formulated based on the design and implement hazard zones on equipment.
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References
BLS (Bureau of Labor Statistics). (2015). “Injuries, illnesses, and fatalities.” 〈http://www.bls.gov/iif/oshsum.htm〉 (Dec. 14, 2014).
Caterpillar. (2011). “Caterpillar performance handbook.” 〈http://www.cashmanequipment.com〉 (May 1, 2014).
CFOI (Census of Fatal Occupational Injuries). (2011). “Current and revised data.” 〈http://www.bls.gov/news.release/osh2.htm〉 (May 7, 2014).
CFOI (Census of Fatal Occupational Injuries). (2014). “Current and revised data.” 〈http://www.bls.gov/iif/oshcfoi1.htm#2014〉 (Oct. 7, 2015).
Chae, S. (2009). “Development of warning system for preventing collision accident on construction sites.” 26th Int. Symp. on Automation and Robotics in Construction, Elsevier, Philadelphia.
Cheng, T., Venugopal, M., Teizer, J., and Vela, P. (2011). “Performance evaluation of ultra wideband technology for construction resource location tracking in harsh environments.” Autom. Constr., 20(8), 1173–1184.
CRC (Cooperative Research Center). (2013). “Shovel load assist program.” 〈http://www.crcmining.com.au/breakthrough-solutions/shovel-load-assist-project/〉 (Nov. 23, 2015).
Duchon, J. C., and Laage, L. W. (2011). “The consideration of human factors in the design of a backing-up warning system.” Proc., Human Factors and Ergonomics Society Annual Meeting, SAGE, Thousand Oaks, CA.
Fosbroke, D. E. (2004). “NIOSH reports! Studies on heavy equipment blind spots and internal traffic control.” 〈https://www.workzonesafety.org/files/documents/news_events/wz_conference_2004/heavy_equipment.pdf〉 (May 16, 2014).
Fullerton, C., Allread, B., and Teizer, J. (2009). “Pro-active real-time personnel warning system.” Proc., Construction Research Congress, ASCE, Reston, VA, 31–40.
Goldenhar, L., Moran, S., and Colligan, M. (2001). “Health and safety training in a sample of open-shop construction companies.” J. Saf. Res., 32(2), 237–252.
Harwood, D., Torbic, D., Richard, K., Glavz, W., and Elefteriadou, L. (2003). “Review of truck characteristics as factors in roadway design.” Transp. Res. Rec., 505(1), 1–194.
Hinze, J., and Coates, W. (2011). “Trends in construction work fatalities.” Proc., Int. Council for Building W099 Prevention: Means to the End of Injuries, Illnesses, and Fatalities, International Council for Building, Washington, DC.
Hinze, J., and Teizer, J. (2011). “Visibility-related fatalities related to construction equipment.” Saf. Sci., 49(5), 709–718.
HSE (Health and Safety Executive). (2009). The safe use of vehicles on construction sites, London.
Huang, X., and Hinze, J. (2006). “Owner’s role in construction safety.” J. Constr. Eng. Manage., 164–173.
Kim, C., Haas, C., Liapi, K., and Caldas, C. (2006). “Human-assisted obstacle avoidance system using 3D workspace modeling for construction equipment operation.” J. Comput. Civ. Eng., 177–186.
Luo, X., O’Brien, W., Leite, F., and Goulet, J. (2014). “Exploring approaches to improve the performance of autonomous monitoring with imperfect data in location-aware wireless sensor networks.” Adv. Eng. Inf., 28(4), 287–296.
Marks, E., and Teizer, J. (2013). “Method for testing proximity detection and alert technology for safe construction equipment operation.” Constr. Manage. Econ., 31(6), 636–646.
MUTCD (Manual on Uniform Traffic Control Devices). (2013). “2009 edition chapter 2C. Warning signs and object markers.” 〈http://mutcd.fhwa.dot.gov/htm/2009/part2/part2c.htm〉 (May 30, 2014).
OSHA (Occupational Safety and Health Administration). (2013a). “Occupational safety and health administration.” 〈https://www.osha.gov〉 (Jun. 2, 2014).
OSHA (Occupational Safety and Health Administration). (2013b). “Personal protective equipment (PPE).” 〈https://www.osha.gov/SLTC/personalprotectiveequipment〉 (Sep. 5, 2014).
OSHA (Occupational Safety and Health Administration). (2014). “Regulations (standards29 CFR) table of contents.” 〈https://www.osha.gov/pls/oshaweb/owasrch.search_form?p_doc_type=STANDARDS&p_toc_level=1&p_keyvalue=1910〉 (May 28, 2014).
Pegula, S. (2010). “Fatal occupational injuries at road construction sites, 2003-07.” 〈http://www.bls.gov/opub/mlr/2013/article/an-analysis-of-fatal-occupational-injuries-at-road-construction-sites-2003-2010.htm〉 (May 12, 2014).
Peterbilt. (2014). “Multi-dimensional workhorse 348.” 〈http://www.peterbilt.com/products/medium-duty/348/〉 (Apr. 24, 2014).
Pradhananga, N., and Teizer, J. (2014). “Congestion analysis for construction site layout planning using real-time data and cell-based simulation model.” 2014 Int. Society for Computing in Civil and Building Engineering (ISCCBE) Conf., Nottingham University Press, Nottingham, England.
Ruff, T. (2007). “Recommendations for evaluating and implementing proximity warning systems on surface mining equipment.” 〈http://www.cdc.gov/niosh/mining/works/coversheet202.html〉 (Dec. 1, 2014).
Teizer, J., Allread, B., Fullerton, C., and Hinze, J. (2010). “Autonomous pro-active real-time construction worker and equipment operator proximity safety alert system.” Autom. Constr., 19(5), 630–640.
Vasenev, A., et al. (2014). “An information fusion approach for filtering GNSS data sets collected during construction operations.” Adv. Eng. Inf., 28(4), 297–310.
Information & Authors
Information
Published In
Journal of Construction Engineering and Management
Volume 142 • Issue 6 • June 2016
Copyright
© 2016 American Society of Civil Engineers.
History
Received: May 15, 2015
Accepted: Oct 19, 2015
Published online: Jan 6, 2016
Published in print: Jun 1, 2016
Discussion open until: Jun 6, 2016
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