Effectiveness of Scrap Tire Chips as Sorptive Drainage Material
Publication: Journal of Environmental Engineering
Volume 130, Issue 7
Abstract
Scrap tire disposal is a problem of growing concern. One solution to this problem is innovative methods for the reuse and recycling of scrap tires. Based on batch isotherm tests, scrap tire chips have been identified to be good sorbents of volatile organic compounds (VOCs) and could be used as leachate drainage layer material in solid waste landfills and in other similar applications. To demonstrate the effects of tire chips on the leachate they come in contact with in a drainage layer over a liner, large-scale tank tests simulating the drainage layer and the clay liner and also field tests were performed. Two cells were constructed in a landfill: one with scrap tire chips and the other with gravel leachate collection layer. According to the results of the large-scale tank tests and field tests, shredded tire chips have a significantly positive impact on the quality of the leachate with which they come in contact. The use of scrap tires in landfills would reduce the magnitude of the current tire disposal problem (a 1 ha landfill requires approximately 300,000 tires to fill 0.3 m of a leachate collection layer) and convert one waste into a beneficial construction material and simultaneously mitigate the problem of VOC transport from through landfill liners.
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References
Battista, J. R., and Connelly, J. P. (1994). “VOCs at Wisconsin landfills: Recent findings.” Proc., 17th Int. Madison Waste Conf., Madison, Wis., 67–86.
Brown, K., and Thomas, J.(1998). “A comparison of the convective and diffusive flux of organic contaminants through landfill liner systems.” Waste Manage. Res., 16(3), 296–301.
Crooks, V. E., and Quigley, R. M.(1984). “Saline leachate migration through clay: A comparative laboratory and field investigation.” Can. Geotech. J., 21, 349–362.
Edil, T. B., Fox, P. J., and Ahl, S. W. (1992). “Hydraulic conductivity and compressibility of waste tire chips.” Proc., 15th Annual Madison Waste Conf., Madison, Wis., 49–61.
Edil, T. B., Park, J. K., and Heim, D. P.(1994). “Large-size test for transport of organics through clay liners.” ASTM Spec. Tech. Publ., 1142, 353–374.
Edil, T. B., Wambold, W. S., and Park, J. K. (1995). “Partitioning of VOCs in clay liner materials.” Geoenvironment 2000, Vol. 1, ASCE, New York, 775–790.
Foose, G. J., Benson, C. H., and Edil, T. B.(2002). “Comparison of solute transport in three composite liners.” J. Geotech. Geoenviron. Eng., 128(5), 391–403.
Gibbons, R. D., Dolan, D., Keough, H., O’Leary, K., and O’Hara, R. (1992). “A comparison of chemical constituents in leachate from industrial hazardous waste & municipal solid waste landfills.” Proc., 15th Annual Madison Waste Conf., Madison, Wis., 251–276.
Haxo, H. E., and Lahey, T. P.(1988). “Transport of dissolved organics from dilute aqueous solutions through flexible membrane liners.” Hazard. Waste Hazard. Mater., 5(4), 275–294.
Heim, D. P. (1992). “Adventive and diffusive transport of three volatile organic compounds through a compacted clay.” MS thesis, Univ. of Wisconsin-Madison, Madison, Wis.
House of Representatives. (1990). “Scrap tire management and recycling opportunities.” Committee on Small Business Rep., U.S. House of Representatives, Washington, D.C.
Humphrey, D. N. (1996). “Investigation of exothermic reaction in tire shred fill located on SR 100 in Ilwaco, Washington.” Rep. to the Federal Highway Administration, Washington, D.C.
Jaca Corporation. (1988). “Shredded tires for landfills as flow-zone material.” Rep. Prepared for Domino Salvage Inc., Fort Washington, Pa.
Kalbe, U., Muller, W., Berger, W., and Eckardt, J.(2002). “Transport of organic contaminants within composite liner systems.” Appl. Clay Sci., 21, 67–76.
Kim, J. Y. (1996). “Retardation of volatile organic compound movement in landfills using scrap tires.” PhD thesis, Univ. of Wisconsin-Madison, Madison, Wis.
Kim, J. Y., Edil, T. B., and Park, J. K.(1997a). “Effective porosity and seepage velocity in column tests on compacted clay.” J. Geotech. Geoenviron. Eng., 123(12), 1135–1142.
Kim, J. Y., Edil, T. B., and Park, J. K.(2001). “Volatile organic compound (VOC) transport through compacted clay.” J. Geotech. Geoenviron. Eng., 127(2), 126–134.
Kim, J. Y., Park, J. K., and Edil, T. B.(1997b). “Sorption of organic compounds in the aqueous phase onto tire rubber.” J. Environ. Eng., 123(9), 827–835.
Mueller, W., Jakob, R., Tatzky-Gerth, R., and August, H. (1998). “Solubilities, diffusion and partition coefficients of organic pollutants in HDPE geomembranes: Experimental results and calculations.” Proc., 6th Int. Conf. on Geosynthetics, Industrial Fabrics Association International, St. Paul, Minn., 239–248.
Park, J. K., Kim, J. Y., and Edil, T. B.(1996b). “Mitigation of organic compound movement in landfills by shredded tires.”Water Environ. Res., 68(1), 4–10.
Park, J. K., Kim, J. Y., Edil, T. B., Huh, M., Lee, S. H., and Lee, J. J.(2003). “Suitability of shredded tires as a substitute for a landfill leachate collection medium.” Waste Manage. Res., 21(3), 278–289.
Park, J. K., and Nibras, M.(1993). “Mass flux of organic chemicals through polyethylene geomembranes.” Water Environ. Res., 65(3), 227–237.
Park, J. K., Sakti, J. P., and Hoopes, J. A.(1996a). “Transport of organic compounds in thermoplastic geomembranes I: Mathematical model.” J. Environ. Eng., 122(9), 800–806.
Plumb, R. H., and Pitchford, A. M. (1985). “Volatile organic scans: Implications for groundwater monitoring.” Proc., NWWA/API Conf. on Petroleum Hydrocarbons and Organic Chemicals in Ground Water-Prevention, Detection and Restoration, Houston, 207–222.
Rowe, R. K., Hrapovic, L., and Kosaric, N.(1995). “Diffusion of chloride and dichloromethane through an HDPE geomembrane.” Geosynthet. Int., 2(3), 507–536.
Rügge, K., Bjerg, P. L., and Christensen, T. H.(1995). “Distribution of organic compounds from municipal solid waste in the groundwater downgradient of a landfill (Grindsted, Denmark).” Environ. Sci. Technol., 29(5), 1395–1400.
Rubber Manufacturers Association. (1989). “A report on the RMT TCLP assessment project.” LEA-006, Washington, D.C.
Rubber Manufacturers Association. (2002). “U.S. scrap tire markets 2001.” Mar-021, Washington, D.C.
Shackelford, C. D. (1990). “Transit-time design of earthen barriers.” Engineering geology, Vol. 29, Elsevier, Amsterdam, The Netherlands, 79–94.
Tatlisoz, N., Edil, T. B., Benson, C. H., Park, J. K., and Kim, J. Y. (1996). “Review of environmental suitability of scrap tires.” Environmental Geotechnics Rep. No. 96-7, Dept. of Civil and Environmental Engineering, Univ. of Wisconsin, Madison, Wis.
United States Environmental Protection Agency (U.S. EPA). (2000). “Drinking water standards and health advisories.” EPA 822-B-00-001, Office of Water 4304, Athens, Ga.
Vashisth, P., Wayne Lee, K., and Wright, R. M. (1998). “Assessment of water pollutants from asphalt pavement containing recycled rubber in Rhode Island. Environmental and social effects of transportation.” Transportation Research Record 1626, Transportation Research Board, Washington, D.C.
Waste Management of Pennsylvania. (1990). “Use of tire chips in liner protective cover.” Rep. Prepared by J & L Testing Co. (Canonsburg, Pa.), Morrisville, Pa.
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Copyright © 2004 American Society of Civil Engineers.
History
Received: Nov 28, 2001
Accepted: Jun 2, 2003
Published online: Jun 15, 2004
Published in print: Jul 2004
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