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Successful demonstration of advanced hyperbaric centrifuge technology for recovering fine coal particles from waste slurries

A full-scale test of advanced hyperbaric centrifuge technology at a Jim Walter Resources Inc. coal-cleaning plant in Alabama successfully reduced moisture from ultrafine coal waste.

The test builds on an eight-year cooperative effort between the Department of Energy’s (DOE) Office of Fossil Energy’s (FE) National Energy Technology Laboratory (NETL) and the Virginia Polytechnic Institute and State University (Virginia Tech) to use the patented process to effectively remove water from very fine coal slurries (a mixture of waste coal fines and water).

US coal producers each year discard large amounts of moisture-laden fines (small, coarse coal particles) that are typically deposited in containment ponds or impoundments as a slurry. In some cases the water is evaporated to stabilize the deposits before they are recovered in surface reclamation; in others, the waste coal is not recovered for a variety of technological, operational, market, or other reasons.

The hyperbaric centrifuge technology is aimed at separating the fine coal particles from water, allowing their recovery for energy while simultaneously cleaning up the environment and providing jobs in the coal cleaning industry. The technology represents a major step forward in clean coal separation, according to the DOE, and could pave the way not only for the use of billions of tons of waste, but also the 70 million to 90 million tons of fine coal refuse added to slurry impoundments by the US coal industry each year.

As a result of support by NETL through FE’s Hydrogen and Fuels Program, researchers at Virginia Tech developed and patented the hyperbaric centrifuge, as well as other related technologies. Virginia Tech’s Center for Advanced Separation Technologies (CAST) successfully tested its prototype technology at a variety of coal-cleaning plants.

Virginia Tech subsequently sublicensed the technology to Decanter Machine Inc., of Johnson City, Tenn., which built the initial prototype unit that successfully dewatered fine coal to a level of 13 to 19% moisture at a rate of 30 gallons per minute. Coal recovery from the sludge was greater than 97%.

Decanter Machine then constructed a full-scale commercial unit capable of handling 600 gallons of slurry per minute. Jim Walter Resources successfully tested the full-scale commercial unit at the greater rate, again dewatering the ultrafine coal to less than 20% moisture by applying a combination of air pressure and centrifugal force to significantly reduce moisture.

The success of the hyperbaric centrifuge has addressed a variety of issues associated with the coal-cleaning process. In the past, removing moisture from very fine coal particles had been difficult. Methods typically used, such as thermal dryers or mechanical dewatering, had either proven too costly or had been unable to dewater ultrafine coal particles of 0.1 millimeters or less.

Through the cooperative agreement with NETL, Virginia Tech’s development of the hyperbaric centrifuge, in combination with its related developments such as a technology called Microcel, has been able to remove both water and ash from fine coal discarded at impoundments. The Microcel technology uses microbubbles to separate fine coal mineral matter that subsequently becomes ash during coal combustion. As a successful example of technology transfer, the Microcel process has been widely used in Australian coal clean plants.



IMO, this will end up being one of the most significant energy stories of the next five years. A google search brings up a study done in 1991 that indicates that dewatering and filtration technologies, such as those mentioned here, could double the recoverable emission compliant coal reserves here in the U.S.

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