Resource Mining for a Bioreactor Landfill

Current Environmental Engineering Pub Date : 2019-03-31 DOI:10.2174/2212717805666181031122517

J. Meegoda, Ameenah Soliman, P. Hettiaratchi, Michael Agbakpe

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引用次数: 5

Abstract

Background: A new generation of the sustainable landfill is designed to achieve sustainable Municipal Solid Waste (MSW) management. It is hybrid anaerobic/aerobic biodegradation landfill followed by landfill mining. However, there is limited information on landfill mining, especially the criteria and process for the practitioner to determine the end of the landfill biodegradation to commence landfill mining. Hence the overall objective of this research was to develop a comprehensive resource mining plan for bioreactor landfills. Method: When waste decomposition becomes slower or stopped, the landfill can be mined to recover resources and utilize the recovered space. The amount of the gas generated, landfill temperature and landfill settlement are indirect measures of landfill activity. Also, the concentration of cellulose (C), hemicelluloses (H), and lignin (L) can describe the biodegradable fractions of waste. Hence the biodegradation in landfills can be monitored by recording the change in methane production, temperature, settlement and the (C+H)/L ratio of waste. Once methane recovery is minimal, landfill reaches a maximum settlement and, ambient temperature plus the (C+H)/L value reaches a stable value of 0.25 indicating end of biodegradation. At this point landfill resources including compost material, non-recoverable waste, and recyclables such as plastics, metal and glass can be mined and recovered. Compost and recyclables can be sold at market value and the non-recovered waste with high energy content can be used as refuse-derived fuel. Once the landfill has been mined space can be reused thus eliminating the need to allocate valuable land for new landfills. Result: The landfill mining detailed in this manuscript utilizes principles from single stream type recycling facilities to ensure feasibility. The first landfill will be excavated and screened to separate the biodegraded soil and compost fraction from the recyclables. Then the screened recyclable materials are transported for further processing in a single stream type separation facility where they will be separated, bundled and sold. A cost calculation was performed for the resource mining of Calgary Biocell and if the mined resources are sold at market values, then the mining of Calgary Biocell would generate approximately $4M.

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生物反应器填埋场资源开采

背景:新一代可持续垃圾填埋场旨在实现可持续的城市固体废物(MSW)管理。它是厌氧/好氧混合生物降解填埋，然后填埋开采。然而，关于垃圾填埋场采矿的信息有限，特别是从业者确定垃圾填埋场生物降解结束以开始垃圾填埋场采矿的标准和过程。因此，本研究的总体目标是为生物反应器垃圾填埋场制定一个全面的资源开采计划。方法:当垃圾分解变慢或停止时，可以对垃圾填埋场进行开采，回收资源并利用回收的空间。产生的气体量、堆填区温度和堆填区沉降量是衡量堆填区活动的间接指标。此外，纤维素(C)、半纤维素(H)和木质素(L)的浓度可以描述废物的可生物降解部分。因此，可以通过记录甲烷产量、温度、沉降和废物(C+H)/L比的变化来监测垃圾填埋场的生物降解。一旦甲烷回收率达到最低，垃圾填埋场达到最大沉降，环境温度加上(C+H)/L值达到0.25的稳定值，表明生物降解结束。在这一点上，垃圾填埋场的资源，包括堆肥材料，不可回收的废物，和可回收的，如塑料，金属和玻璃可以开采和回收。堆肥可回收物可按市价出售，而未回收的高能量废物可用作垃圾衍生燃料。一旦垃圾填埋场被开采出来，空间就可以重新利用，从而消除了为新的垃圾填埋场分配宝贵土地的需要。结果:本文详细介绍的填埋采矿利用了单流型回收设施的原理，确保了可行性。第一个垃圾填埋场将被挖掘和筛选，从可回收物中分离出生物降解的土壤和堆肥部分。然后，经过筛选的可回收材料被运输到一个单流类型分离设施进行进一步处理，在那里它们将被分离、捆绑和出售。对卡尔加里生物电池的资源开采进行了成本计算，如果开采的资源按市场价值出售，那么卡尔加里生物电池的开采将产生大约400万美元的收益。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Current Environmental Engineering

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