The program involves the application of a novel gasification concept, termed a modular allothermal gasifier (MAG) to produce syngas from coal, biomass, and waste slurries. The MAG employs a steam-driven gasification process using a pressurized entrained flow reactor wherein the external wall surfaces are catalytically heated to 1000 °C via heterogeneous combustion of a portion of the produced syngas. The MAG can be fed by a hydrothermal treatment reactor for biomass and waste feedstocks, which employs well-developed hydrothermal processing technology using the addition of heat and water to provide a uniform slurry product. The hydrothermal treatment reactor requires no preprocessing and a clean syngas is produced at high cold gas efficiency (80%). Importantly, the MAG can operate over a wide range of positive pressures up to 3 MPa (30 bar) which provides process control to vary the output to match end-use needs or feedstock rate. The system produces minimal emissions and operates at significantly higher efficiency and lower energy requirements than pyrolysis, plasma gasification, and carbonization systems. The system is compact and modular, making it easily transportable, for example, to a variety of sites, including those where remoteness, inaccessibility, and space limitations would preclude competing systems. The system can be applied to small gasification systems without the increase in heat losses that plague conventional small scale gasifiers. Test results and model simulations are presented on a single tube system and analyses of a variety of configurations presented.
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January 2019
Research-Article
Advanced Concepts in Modular Coal and Biomass Gasifiers
John P. Dooher,
John P. Dooher
Physics Department,
Adelphi University Chairman,
One South Avenue,
Garden City, NY 11530
e-mail: dooher@adelphi.edu
Adelphi University Chairman,
One South Avenue,
Garden City, NY 11530
e-mail: dooher@adelphi.edu
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Marco J. Castaldi,
Marco J. Castaldi
Mem. ASME
Chemical Engineering Department,
The City College of New York,
City University of New York,
140th Street | Convent Avenue Steinman Hall,
Room 307,
New York, NY 10031
e-mail: mcastaldi@ccny.cuny.edu
Chemical Engineering Department,
The City College of New York,
City University of New York,
140th Street | Convent Avenue Steinman Hall,
Room 307,
New York, NY 10031
e-mail: mcastaldi@ccny.cuny.edu
Search for other works by this author on:
Dean P. Modroukas
Dean P. Modroukas
Mem. ASME
Innoveering, LLC,
100 Remington Blvd.,
Ronkonkoma, NY 11779,
e-mail: Dean.Modroukas@Innoveering.net
Innoveering, LLC,
100 Remington Blvd.,
Ronkonkoma, NY 11779,
e-mail: Dean.Modroukas@Innoveering.net
Search for other works by this author on:
John P. Dooher
Physics Department,
Adelphi University Chairman,
One South Avenue,
Garden City, NY 11530
e-mail: dooher@adelphi.edu
Adelphi University Chairman,
One South Avenue,
Garden City, NY 11530
e-mail: dooher@adelphi.edu
Marco J. Castaldi
Mem. ASME
Chemical Engineering Department,
The City College of New York,
City University of New York,
140th Street | Convent Avenue Steinman Hall,
Room 307,
New York, NY 10031
e-mail: mcastaldi@ccny.cuny.edu
Chemical Engineering Department,
The City College of New York,
City University of New York,
140th Street | Convent Avenue Steinman Hall,
Room 307,
New York, NY 10031
e-mail: mcastaldi@ccny.cuny.edu
Dean P. Modroukas
Mem. ASME
Innoveering, LLC,
100 Remington Blvd.,
Ronkonkoma, NY 11779,
e-mail: Dean.Modroukas@Innoveering.net
Innoveering, LLC,
100 Remington Blvd.,
Ronkonkoma, NY 11779,
e-mail: Dean.Modroukas@Innoveering.net
1Corresponding author.
Contributed by the Advanced Energy Systems Division of ASME for publication in the JOURNAL OF ENERGY RESOURCES TECHNOLOGY. Manuscript received September 10, 2016; final manuscript received May 29, 2018; published online August 9, 2018. Assoc. Editor: Ronald Breault.
J. Energy Resour. Technol. Jan 2019, 141(1): 012001 (10 pages)
Published Online: August 9, 2018
Article history
Received:
September 10, 2016
Revised:
May 29, 2018
Citation
Dooher, J. P., Castaldi, M. J., and Modroukas, D. P. (August 9, 2018). "Advanced Concepts in Modular Coal and Biomass Gasifiers." ASME. J. Energy Resour. Technol. January 2019; 141(1): 012001. https://doi.org/10.1115/1.4040526
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