Life cycle energy use and GHG emission assessment of coal-based SNG and power cogeneration technology in China

Abstract Life cycle energy use and GHG emissions are assessed for coal-based synthetic natural gas (SNG) and power cogeneration/polygenereation (PG) technology and its competitive alternatives. Four main SNG applications are considered, including electricity generation, steam production, SNG vehicle and battery electric vehicle (BEV). Analyses show that if SNG is produced from a single product plant, the lower limits of its life cycle energy use and GHG emissions can be comparable to the average levels of coal-power and coal-BEV pathways, but are still higher than supercritical and ultra supercritical (USC) coal-power and coal-BEV pathways. If SNG is coproduced from a PG plant, when it is used for power generation, steam production, and driving BEV car, the life cycle energy uses for PG based pathways are typically lower than supercritical coal-power pathways, but are still 1.6–2.4% higher than USC coal-power pathways, and the average life cycle GHG emissions are lower than those of all coal-power pathways including USC units. If SNG is used to drive vehicle car, the life cycle energy use and GHG emissions of PG-SNGV-power pathway are both much higher than all combined coal-BEV and coal-power pathways, due to much higher energy consumption in a SNG driven car than in a BEV car. The coal-based SNG and power cogeneration technology shows comparable or better energy and environmental performances when compared to other coal-based alternatives, and is a good option to implement China’s clean coal technologies.

[1]  Xiaosong Zhang,et al.  Techno-economic performance and cost reduction potential for the substitute/synthetic natural gas and power cogeneration plant with CO2 capture , 2014 .

[2]  Paulina J Aramillo,et al.  Comparative life-cycle air emissions of coal, domestic natural gas, LNG, and SNG for electricity generation. , 2007 .

[3]  Souman Rudra,et al.  Process analysis of a biomass-based quad-generation plant for combined power, heat, cooling, and synthetic natural gas production , 2015 .

[4]  Xiaosong Zhang,et al.  Exergy analysis and the energy saving mechanism for coal to synthetic/substitute natural gas and power cogeneration system without and with CO2 capture , 2014 .

[5]  Sheng Li,et al.  Cogeneration of substitute natural gas and power from coal by moderate recycle of the chemical unconverted gas , 2013 .

[6]  Erik Dahlquist,et al.  Feasibility study on combining anaerobic digestion and biomass gasification to increase the production of biomethane , 2015 .

[7]  G. Braccio,et al.  Synthetic natural gas SNG production from biomass gasification – Thermodynamics and processing aspects , 2015 .

[8]  Hongguang Jin,et al.  Full chain energy performance for a combined cooling, heating and power system running with methanol and solar energy , 2013 .

[9]  Z Ma,et al.  GREENHOUSE GAS EMISSION FACTOR FOR COAL POWER CHAIN IN CHINA AND THE COMPARISON WITH NUCLEAR POWER CHAIN , 1999 .

[10]  Yanjun Ding,et al.  Coal-based synthetic natural gas (SNG): A solution to China’s energy security and CO2 reduction? , 2013 .

[11]  Li Xu-jun Progresses in USC Thermal Power Generation Technology and Domestic Construction , 2007 .

[12]  Sheng Li,et al.  Coal Based Cogeneration System for Synthetic/Substitute Natural Gas and Power With CO2 Capture After Methanation: Coupling Between Chemical and Power Production , 2014 .

[13]  Xiaosong Zhang,et al.  Coal to SNG: Technical progress, modeling and system optimization through exergy analysis , 2014 .

[14]  Sha Yi-rao Make Great Effects on the Operational Optimization of Long Distance Oil & Gas Transportation Pipelines for Low Costs and Energy Saving , 2006 .

[15]  Ye Jian-qing Operation Optimization and Energy-saving Retrofit for a 109FA Gas-Steam Combined Cycle Unit , 2011 .

[16]  Linghong Zhang,et al.  Overview of recent advances in thermo-chemical conversion of biomass. , 2010 .