Engineering:Bioreactor landfill

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Short description: Dump with fast microbial decomposition

Landfills are the primary method of waste disposal in many parts of the world, including United States and Canada. Bioreactor landfills are expected to reduce the amount of and costs associated with management of leachate, to increase the rate of production of methane (natural gas) for commercial purposes and reduce the amount of land required for land-fills.[1][2] Bioreactor landfills are monitored and manipulate oxygen and moisture levels to increase the rate of decomposition by microbial activity.

Traditional landfills and associated problems

Landfills are the oldest known method of waste disposal.[3][4] Waste is buried in large dug out pits (unless naturally occurring locations are available) and covered. Bacteria and archaea decompose the waste over several decades producing several by-products of importance, including methane gas (natural gas), leachate, and volatile organic compounds (such as hydrogen sulfide (H2S), N2O2, etc.).

Methane gas, a strong greenhouse gas, can build up inside the landfill leading to an explosion unless released from the cell.[5] Leachate are fluid metabolic products from decomposition and contain various types of toxins and dissolved metallic ions.[6] If leachate escapes into the ground water it can cause health problems in both animals and plants.[7][8] The volatile organic compounds (VOCs) are associated with causing smog and acid rain.[9] With the increasing amount of waste produced, appropriate places to safely store it have become difficult to find.[10]

Working of a bioreactor landfill

There are three types of bioreactor: aerobic, anaerobic and a hybrid (using both aerobic and anaerobic method). All three mechanisms involve the reintroduction of collected leachate supplemented with water to maintain moisture levels in the landfill. The micro-organisms responsible for decomposition are thus stimulated to decompose at an increased rate with an attempt to minimise harmful emissions.[11]

In aerobic bioreactors air is pumped into the landfill using either vertical or horizontal system of pipes. The aerobic environment decomposition is accelerated and amount of VOCs, toxicity of leachate and methane are minimised.[12] In anaerobic bioreactors with leachate being circulated the landfill produces methane at a rate much faster and earlier than traditional landfills. The high concentration and quantity of methane allows it to be used more efficiently for commercial purposes while reducing the time that the landfill needs to be monitored for methane production. Hybrid bioreactors subject the upper portions of the landfill through aerobic-anaerobic cycles to increase decomposition rate while methane is produced by the lower portions of the landfill.[11] Bioreactor landfills produce lower quantities of VOCs than traditional landfills, except H2S. Bioreactor landfills produce higher quantities of H2S. The exact biochemical pathway responsible for this increase is not well studied [1]

Advantages of bioreactor landfills

Bioreactor landfills accelerate the process of decomposition.[13] As decomposition progresses, the mass of biodegradable components in the landfill declines, creating more space for dumping garbage. Bioreactor landfills are expected to increase this rate of decomposition and save up to 30% of space needed for landfills. With increasing amounts of solid waste produced every year and scarcity of landfill spaces, bioreactor landfill can thus provide a significant way of maximising landfill space. This is not just cost effective, but since less land is needed for the landfills, this is also better for the environment.[1]

Furthermore, most landfills are monitored for at least 3 to 4 decades to ensure that no leachate or landfill gases escape into the community surrounding the landfill site. In contrast, bioreactor landfill are expected to decompose to level that does not require monitoring in less than a decade. Hence, the landfill land can be used for other purposes such as reforestation or parks, depending on the location at an earlier date.[14] In addition, re-using leachate to moisturise the landfill filters it. Thus, less time and energy is required to process the leachate, making the process more efficient.[11]

Disadvantages of bioreactor landfills

Bioreactor landfills are a relatively new technology. For the newly developed bioreactor landfills initial monitoring costs are higher to ensure that everything important is discovered and properly controlled. This includes gases, odours and seepage of leachate into the ground surface.

The increased moisture content of bioreactor landfill may reduce the structural stability of the landfill by increasing the pore water pressure within the waste mass.[15]

Since the target of bioreactor landfills is to maintain a high moisture content, gas collection systems can be affected by the increased moisture content of the waste.

Implementation of bioreactor landfills

Bioreactor landfills being a novel technology are still in the development phase and are being studied in the laboratory-scale.[16] Pilot projects for bioreactor landfills are showing promise and more are being experimented with in different parts of the world. Despite the potential benefits of bioreactor landfills there are no standardised and approved designs with guidelines and operational procedures. Following is a list of bioreactor landfill projects which are being used to collect data for forming these needed guidelines and procedures:[17]

United States

  • California
    • Yolo County
  • Florida
    • Alachua County Southeast Landfill
    • Highlands County
    • New River Regional Landfill, Raiford
    • Polk County Landfill, Winter Haven
  • Kentucky
    • Outer Loop Landfill
  • Michigan
    • Saint Clair County
  • Mississippi
    • Plantation Oaks Bioreactor Demonstration Project, Sibley
  • Missouri
    • Columbia
  • New Jersey
    • ACUA's Haneman Environmental Park, Egg Harbor Township
  • North Carolina
    • Buncombe County Landfill Project
  • Virginia
    • Maplewood Landfill and King George County Landfills
    • Virginia Landfill Project XL Demonstration Project

Canada

  • Sainte-Sophie Bioreactor demonstration Project, Quebec

Australia

  • New South Wales
    • WoodLawn, Goulburn
  • Queensland
    • Ti Tree Bioenergy, Ipswich

See also

References

  1. 1.0 1.1 1.2 The Hinkley Center For Solid and Hazardous Waste Management, The Department of Environmental Engineering Sciences, University of Florida, The Civil and Environmental Engineering Department, University of Central Florida. (2008). Florida Bioreactor Landfill Demonstration Project: Executive Summary. Retrieved February 03, 2010, from [1]
  2. Berge, Nicole D.; Reinhart, Debra R.; Batarseh, Eyad S. (2009-05-01). "An assessment of bioreactor landfill costs and benefits". Waste Management. First international conference on environmental management, engineering, planning and economics 29 (5): 1558–1567. doi:10.1016/j.wasman.2008.12.010. PMID 19167875. 
  3. "Landfills | Encyclopedia.com". https://www.encyclopedia.com/environment/energy-government-and-defense-magazines/landfills. 
  4. Tammemagi, Hans (1999). The Waste Crisis : Landfills, Incinerators, and the Search for a Sustainable Future. Oxford: Oxford University Press. pp. 4. ISBN 9780195351682. OCLC 466431800. https://archive.org/details/wastecrisislandf00tamm. 
  5. Christensen, T. H. (1999). Landfilling of waste: Biogas
  6. Washington State Department of Ecology. (n.d.). Solid Waste Landfill Design Manual. Retrieved February 3, 2010, from [2]
  7. Abdel-Shafy, Hussein I.; Mansour, Mona S. M. (2018-12-01). "Solid waste issue: Sources, composition, disposal, recycling, and valorization" (in en). Egyptian Journal of Petroleum 27 (4): 1275–1290. doi:10.1016/j.ejpe.2018.07.003. ISSN 1110-0621. 
  8. Kjeldsen, P. M. (2002). Present and Long-Term Composition of MSW Landfill Leachate: A Review. Critical Reviews in Environmental Science and Technology , 297-336.
  9. Brosseau, J. H. (1994). Trace gas compound emissions from municipal landfill sanitary sites; Atmospheric-Environment. Atmospheric Environment, pp. 285-293.
  10. Abdel-Shafy, Hussein I.; Mansour, Mona S. M. (2018-12-01). "Solid waste issue: Sources, composition, disposal, recycling, and valorization" (in en). Egyptian Journal of Petroleum 27 (4): 1275–1290. doi:10.1016/j.ejpe.2018.07.003. ISSN 1110-0621. 
  11. 11.0 11.1 11.2 Hinkley Center For Solid and Hazardous Waste Management. (2006). Bioreactor.org - General Info. Retrieved February 3, 2010, from Bioreactor.org: [3]
  12. Murphyb, S. R. (1992). A lysimeter study of the aerobic landfill concept . Waste Management & Research , 485-503.
  13. Reinhart, Debra R., and Timothy G. Townsend. Landfill Bioreactor Design and Operation. Boca Raton, Fla: Lewis, 1998. Print.
  14. Bard, S. (2002). Voices from the Past: Hong Kong. HK University Press , 1842-1918.
  15. Sustainable Practices for Landfill Design and Operation. Waste Management Principles and Practice. Springer. 2015. ISBN 9781493926619. https://www.springer.com/us/book/9781493926619. 
  16. Nair, V.V., Dhar, H., Kumar, S., Thalla, A.K., Mukherjee, S., Wong, J.W.C. (2016). Artificial neural network based modeling to evaluate methane yield from biogas in a laboratory-scale anaerobic bioreactor. Bioresource Technology 217, 90 – 99. doi: https://dx.doi.org/10.1016/j.biortech.2016.03.046
  17. Kjeldsen, P. M. (2002). Present and Long-Term Composition of MSW Landfill Leachate: A Review. Critical Reviews in Environmental Science and Technology , pp. 297-336

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