Thermal oxidation of coal mine ventilation air methane

نویسندگان

  • J. M. Somers
  • H. L. Schultz
چکیده

Methane is a powerful greenhouse gas and the principal component of natural gas. Coal seams often contain significant quantities of methane, and underground coal mines must ensure that methane released into the mine during coal extraction does not build to dangerous levels. This is accomplished in part through the use of large-volume ventilation systems that remove methane from the mine and release it to the atmosphere. Although the methane concentration exhausted is quite low (typically <1 percent), the volume of air that ventilation systems move is so great that they actually constitute the largest source of methane emissions from underground coal mines. Each year underground coal mines throughout the world emit more than 500 billion cubic feet of methane from their ventilation systems. An air pollution control technology, thermal oxidation using a flow-reversal reactor (TFRR), has emerged as a potential solution to ventilation air methane (VAM) emission mitigation. One manufacturer of TFRRs has demonstrated its oxidizer design (the VOCSIDIZERTM) at coal mines in the United Kingdom and Australia. These demonstrations tested the technology’s effectiveness at oxidizing low-concentration methane, as well as its ability to tap the excess heat to produce steam for electric power generation. In early 2007, the first U.S. demonstration of this technology began operation at an abandoned mine in West Virginia. The project is designed to prove the technology’s operational robustness, its ability to reliably oxidize methane at concentrations typical of mine exhausts, and its safety. If the technology is employed at active underground coal mines, it offers the potential to mitigate substantial quantities of global methane emissions. This paper discusses global VAM emissions, options for the recovery and utilization of VAM, and existing projects such as WestVAMP in Australia and the ongoing U.S. VAM demonstration project. Introduction methane. This could constitute a dangerous situation since methane, the principal component of natural gas, is Methane (CH4) released to the atmosphere from gassy explosive at concentrations ranging from 5 to 15 percent in underground coal mine ventilation systems constitutes a air. major source of greenhouse gas emissions. As concern Coal mines are required to manage methane over climate change grows worldwide, mitigating concentrations underground so that they do not approach ventilation air methane (VAM) emissions is drawing the lower explosive limit of 5 percent, in order to ensure a increasing attention. Field demonstrations of VAM safe environment for mine workers. In the U.S., if methane oxidation technology in the United Kingdom, Australia, concentrations reach 1 percent in mine workings, specific and the U.S. have paved the way for the emergence of a response actions must be taken (per CFR 75.323 – Actions new industry focused on capturing the energy embodied in for Excessive Methane), which can be disruptive to mine VAM exhaust flows and putting it to beneficial use. With productivity. Therefore, controlling methane in deep, gassy supplemental revenues potentially available from domestic underground coal mines is an ongoing concern for mine and international carbon funds, the economics of VAM operators, both in terms of ensuring worker safety as well emission mitigation appear favorable. As a result, interest as maximizing coal production and profitability. in implementing VAM emission mitigation technology in Two methane management approaches are available for the U.S. and elsewhere is growing rapidly. gassy underground coal mines. Large-scale ventilation Methane is formed over geologic time as the systems are employed to bring fresh air into the workings, coalification process converts organic material into coal, where they dilute methane released during coal extraction and may be present both in coal seams as well as in and expel it from the mine into the atmosphere. At very adjacent rock strata. Deep underground coal mines may gassy mines, however, the cost of operating a ventilation encounter substantial reservoirs of methane. Methane is system large enough to handle high methane release rates released into the mine environment as coal is extracted, can be cost prohibitive. In such circumstances, gas unless it has been removed prior to mining through the drainage can be employed to supplement the ventilation application of gas drainage techniques. Deep longwall system. Drainage involves drilling boreholes into the coal operations, which are characterized by high extraction rates seam (from the surface or within the mine), through which of often very gassy coal, can release substantial amounts of methane can be extracted from the coal before it is mined,

برای دانلود متن کامل این مقاله و بیش از 32 میلیون مقاله دیگر ابتدا ثبت نام کنید

ثبت نام

اگر عضو سایت هستید لطفا وارد حساب کاربری خود شوید

منابع مشابه

Coal-Packed Methane Biofilter for Mitigation of Green House Gas Emissions from Coal Mine Ventilation Air

Methane emitted by coal mine ventilation air (MVA) is a significant greenhouse gas. A mitigation strategy is the oxidation of methane to carbon dioxide, which is approximately twenty-one times less effective at global warming than methane on a mass-basis. The low non-combustible methane concentrations at high MVA flow rates call for a catalytic strategy of oxidation. A laboratory-scale coal-pac...

متن کامل

Experimental demonstration and modelling of an adsorption-enhanced reverse flow reactor for the catalytic combustion of coal mine ventilation air methane

Ventilation air methane is a major contributor to the carbon footprint of the coal mining industry. This contribution can be mitigated by combustion of methane to carbon dioxide. The use of efficient combustion devices, such as catalytic reverse flow reactors, can improve the economy of the process. However, the high water content of the ventilation air can inhibit catalysts (such as palladium)...

متن کامل

Numerical Study on Heat Distribution and Transfer Characteristics of a Manifold in a Coal Mine VAM TFRR Oxidation Bed

A thermal flow-reversal reactor is candidate for utilizing low concentration ventilation air methane. In this paper, a numerical study is performed by using the FLUENT software to explore the details of the transient preheating and starting process of the thermal flow-reversal reactor oxidation bed. The bed was heated by hot gas, which was transported and distributed through the holes of manifo...

متن کامل

Development and application of reservoir models and artificial neural networks for optimizing ventilation air requirements in development mining of coal seams

In longwall development mining of coal seams, planning, optimizing and providing adequate ventilation are very important steps to eliminate the accumulation of explosive methane–air mixtures in the working environment. Mine operators usually try to supply maximum ventilation air based on the capacity of the system and the predicted need underground. This approach is neither economical nor safer...

متن کامل

Field study of longwall coal mine ventilation and bleeder performance

Longwall coal mine operators in the U.S. are required to ventilate multipanel longwall districts, but may have little or no knowledge about what happens to the ventilation air between the inlet evaluation points (IEPs), bleeder evaluation points (BEPs) and bleeder fans. The effectiveness of bleeder performance can directly influence the ability of a ventilation system to remove and dilute coal ...

متن کامل

ذخیره در منابع من


  با ذخیره ی این منبع در منابع من، دسترسی به آن را برای استفاده های بعدی آسان تر کنید

برای دانلود متن کامل این مقاله و بیش از 32 میلیون مقاله دیگر ابتدا ثبت نام کنید

ثبت نام

اگر عضو سایت هستید لطفا وارد حساب کاربری خود شوید

عنوان ژورنال:

دوره   شماره 

صفحات  -

تاریخ انتشار 2008