PEAT International has successfully commissioned a Plasma Thermal Destruction and Recovery (PTDR) systems in Shanghai, China. The system was designed to deconstruct medical waste and oil refinery sludge.

PEAT International, Inc. (PEAT), a plasma-thermal waste destruction company, has installed a PTDR system in Shanghai, China. The 60 kg/hr system was specifically designed for the treatment of medical waste and oil refinery sludge for Abada Plasma Technology Holdings, Ltd.

“This is end-stage technology and sets the standard for clean hazardous waste remediation. Only with plasma can you achieve temperatures high enough for waste destruction in a single-staged process,” said Joseph Rosin, PEAT International chairman. “It’s a 21st century solution that addresses three important needs: significant volume reduction, full pollution control and competitive pricing. We are currently preparing for other projects already under contract.”

PEAT’s PTDR “single stage” plasma-thermal process transforms hazardous waste through molecular dissociation at 1,500°C (2,732°F) into recoverable, non-toxic end-products, synthetic gas and heat (sources for energy recovery), metals, and a vitrified glass matrix. Emissions are below the most stringent environmental standards.

PTDR systems are in operation in California, Taiwan, and China. For more information and to watch a video of operations, please click here.

Northbrook, Illinois & Shanghai, China – October 10, 2013 – PEAT International, Inc., (“PEAT”) a leader in plasma-thermal waste destruction systems, announced the successful commissioning of a Plasma Thermal Destruction and Recovery (“PTDR”) system in Shanghai, China. The 60 kg/hr system – designed for medical waste and oil refinery sludge – was installed for Abada Plasma Technology Holdings, Ltd. – an Asian-based renewable energy project developer.

PEAT’s PTDR “single stage” plasma-thermal process transforms hazardous waste through molecular dissociation at 1,500°C (2,732°F) into recoverable, non-toxic end-products, synthetic gas and heat (sources for energy recovery), metals and a vitrified glass matrix. Emissions are below the most stringent environmental standards used anywhere.

“This is end-stage technology and sets the standard for clean hazardous waste remediation. Only with plasma can you achieve temperatures high enough for waste destruction in a single-staged process,” said Joseph Rosin, PEAT International Chairman. “It’s a 21st century solution that addresses three important needs: significant volume reduction, full pollution control and competitive pricing. We are currently preparing for other projects already under contract.”

PTDR systems are in operation in California, Taiwan and China. Go to http://www.peat.com/chinasystem.html for a video of operations and acceptance test run data.

About PEAT International

PEAT International, Inc., headquartered in Northbrook, Illinois, with offices in China, Taiwan and India, is a waste-to-energy (“WTE”) company with its two proprietary technologies – the Plasma Thermal Destruction and Recovery™ (“PTDR”) technology for the treatment and recycling of industrial, medical and other hazardous waste streams and the Thermal Volume Reduction & Conversion™ (“TVRC”) technology for municipal solid waste. For more information, contact Daniel Ripes, dripes@peat.com, at 847-559-8567 and visit www.peat.com.

All of the high temperature boiler/reactors – a key component of the TVRC technology –  installed and operating to date required an air permit from the applicable regulatory body. Typically, these systems are designed to comply with emissions levels for particulate matter (150 μg/m3), NOx (0.04 PPMV), SOx (0.03 PPMV) and carbon monoxide (9 PPMV), as well as the other typical reference pollutants as they pertain to air emissions.

Below is a summary of the most recent third party emissions testing conducted on a recently commissioned PTDR plasma-arc, plasma gasification. The test was conducted for medical waste treatment. The summary also compares the results to current United States air emission regulations.

The following parameters were also tested but were found to be non detectible (Detectible limit in parentheses) Chlorides as Cl (1.4 mg/m3), Ammonia (5 mg/m3), Hydrogen Sulfide (1.4 mg/m3). With regards to Volatile Organic Compounds (VOCs), the testing for Benzene, Ethyl Benzene, Toluene and Xylene were all below the detectible limit (1 mg/m3). Finally, with regards to heavy metals with the exception of cadmium, which is listed above, all were below the detectible limit of 1 μg/m3 (antimony had a detectible limit of 5 μg/m3).

It is worth noting that the above emissions for the PTDR plasma-arc, plasma gasification were measured when the energy recovery system (gas engine was not operating and thus the syngas was thermally oxidized. It is noted that if the syngas is utilized in a gas engine or other syngas utilization equipment, then the only gas emissions associated with the PTDR plasma-arc, plasma gasification system would be the exhaust from that source.

According to the United States Environmental Protection Agency’s “Solid Waste Management and Greenhouse Gases: A Lifecycle Assessment of Emissions and Sinks”, disposing of 650,000 tons per year in a landfill without gas collection, could reduce its Greenhouse Gas (GHG) emissions by about 260,000 Metric Tons Carbon Equivalent (MTCE) per year by managing waste in a mass burn combustor unit. For this preliminary discussion, this equates to 0.40 MTCE/ton avoided from landfilling.

However, the EPA’s document uses a combustion system efficiency of 550 kWh per ton of mixed MSW. The high temperature boiler/reactor system in the TVRC system, which combines a high temperature boiler/reactor with a plasma-arc, plasma gasification sytem, has an efficiency of approximately 690 kWh per ton – 25% greater efficiency; thus the high temperature boiler/reactor has the potential to generate approximately 0.50 MTCE/ton avoided from landfilling or in total up to 82,500 MTCE, when assuming 500 TPD.

Additionally, the EPA estimates greenhouse gas (GHG) emissions range from 10 to 20 million metric tons, depending on the different methods used to estimate the biogenic fraction of MSW. EPA’s eGrid (a database of information on electrical generators in the United States) indicates about 53% of the energy generated by MSW combustion facilities is from biogenic sources and 47% is fossil-fuel derived power. If we take that 53% and presume the same percent of GHG emissions are from biogenic sources, then MSW combustion facilities generate less GHGs than fossil-fuels.

EPA estimates the GHG savings from WTE to be about 1 on of GHGs saved per ton of MSW combusted.

Any fly ash generated in a Thermal Volume Recovery and Conversion System is converted on-site into a vitrified matrix product, thus converting an unusable by-product from the high temperature boiler/reactor system into a usable end-product.

As previously discussed in this blog section as well as on PEAT’s website, the vitrified matrix could be used in a variety of commercial applications including concrete aggregate, insulation, roadbed/fill construction and even in decorative and non-decorative tiles. Independent laboratory tests (i.e. “TCLP”) have proven that the vitrified matrix does not leach, is totally benign and safe for any re-utilization.

PEAT has conducted a range of testing on this material include Toxicity Characteristic Leaching Procedure (TCLP) tests. A summary of the test results can be seen below when fly ash was processed:

The most recent TCLP results on the vitrified matrix from PEAT’s plasma-arc plasma gasification PTDR system previously located at a China refinery is presented in the below table.