Energy conservation and emission reduction of China’s electric power industry

Recently, energy saving and emission reduction get more attention in the world, electric power industry is one of the major sectors of energy consumption. The national government has issued a series of related policies and regulations to change the power structure and control pollutant emissions, in order to improve the level of energy conservation and emission reduction. Some problems exist in the current policies and regulations. This paper puts forward measures and suggestions to strengthen energy conservation and emission reduction.

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Evaluation of Energy-Saving a Emission Reduction Performance of Chinese Electric Power Industry

Proceedings of the 2016 5th International Conference on Energy and Environmental Protection (ICEEP 2016) ◽

10.2991/iceep-16.2016.72 ◽

2016 ◽

Author(s):

Yin Chen ◽

Taihua Yang

Keyword(s):

Energy Saving ◽

Electric Power ◽

Emission Reduction ◽

Electric Power Industry ◽

Power Industry

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Waste heat management in the electric power industry: issues of energy conservation and station operation under environmental constraints. Progress report, June 1, 1977--December 31, 1977

10.2172/5057103 ◽

1978 ◽

Author(s):

Not Given Author

Keyword(s):

Energy Conservation ◽

Electric Power ◽

Waste Heat ◽

Electric Power Industry ◽

Power Industry ◽

Progress Report ◽

Environmental Constraints ◽

Heat Management

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The Sustainability of Energy Substitution in the Chinese Electric Power Sector

Sustainability ◽

10.3390/su12135463 ◽

2020 ◽

Vol 12 (13) ◽

pp. 5463

Author(s):

Ying Li ◽

Yue Xia ◽

Yang-Che Wu ◽

Wing-Keung Wong

Keyword(s):

Human Capital ◽

Energy Conservation ◽

Cost Function ◽

Electric Power ◽

Electric Power Industry ◽

Power Industry ◽

Power Sector ◽

Capital Input ◽

Energy Substitution ◽

Electric Power Sector

The Chinese electric power industry, including its coal industry and other energy industries that are not efficient, contributes to China’s serious energy shortages and environmental contamination. The governing authority considers energy conservation to be one of the most prominent national targets, and has formulated various plans for decarbonizing the power system. Applying the trans-log cost function, this paper examined the trans-log cost function to analyze the potential inter-factor substitution among energy, capital and labor. We also investigated what role human capital played in energy substitution for the electric power sector during the period from 1981 to 2017. Three key results were derived: (1) energy is price-insensitive, (2) there exists large substitution sustainability between both capital and labor with energy, and (3) human capital input not only enhances the extent of energy substitutability with capital and labor but also is a substitute to energy itself. These findings imply that the liberalization of the electric price mechanism is conducive to lessening energy use and augmenting non-energy intensiveness, and that energy conservation technology could become more sustainable by investing more capital in the electricity sector, thereby achieving a capital–energy substitution and a decrease of CO2 emissions. We further suggest that the priority for the Chinese electric power industry should be to attach more importance to increasing human capital input.

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An Analysis of Simulation System of CO2 Emission and Emission Reduction Paths in Chongqing’s Electric Power Industry

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.700.431 ◽

2014 ◽

Vol 700 ◽

pp. 431-436

Author(s):

Min Tang ◽

Shi Yong Zhang ◽

Li Ping Wang

Keyword(s):

Electric Power ◽

Emission Reduction ◽

Electricity Generation ◽

Goodness Of Fit ◽

Historical Data ◽

Electric Power Industry ◽

Power Industry ◽

Simulation System ◽

Dynamics Simulation ◽

To Come

This paper predicts and analyzes the output, energy consumption and CO2emission in Chongqing’s electric power industry in 16 years to come using a dynamics simulation system of carbon emission. A comparison with historical data indicates a desirable goodness of fit of the simulated results, which show that the power generation in Chongqing will reach the peak of about 180 billion KWH in 2020 and 378 billion KWH in 2030, followed by a steady rise in the following 15 years; the per capita power consumption will reach 5350 KWH in 2020 and 12,000 KWH in 2030; the CO2emission will reach about 102,200,000 tons in 2020 and about 232,600,000 tons in 2030; the CO2emission per unit electricity generation will reach 570gco2/kwh in 2020 and about 620gco2/kwh in 2030. Based on the data, this paper analyzes the influence of different technical paths and policy options on emission in various developmental scenarios, and proposes specific paths for emission reduction.

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Detecting and Understanding Synergies and Co-Benefits of Low Carbon Development in the Electric Power Industry in China

Sustainability ◽

10.3390/su12010297 ◽

2019 ◽

Vol 12 (1) ◽

pp. 297 ◽

Cited By ~ 2

Author(s):

Ping Jiang ◽

Adila Alimujiang ◽

Hongjia Dong ◽

Xiaoyu Yan

Keyword(s):

Electric Power ◽

Air Pollutants ◽

Emission Reduction ◽

Power Plants ◽

Fine Particles ◽

Electric Power Industry ◽

Power Industry ◽

Control Measures ◽

Air Pollution Control ◽

Carbon Reduction

China’s electric power industry contributes a significant amount of carbon emissions as well as air pollutants such as SO2, NOx, and fine particles. In order to detect co-benefits of carbon reduction and air pollution control, this study analyzed the emission reduction, emission reduction factors, and synergistic effect factors of technical and structural emission reduction measures in the electric power industry in the Jiangsu, Zhejiang, and Yunnan provinces and Shanghai City. The main findings are: (1) the structural emission reduction measures in all four regions had positive co-control effects. Therefore, promoting renewables can achieve remarkable co-benefits; (2) the result demonstrated that the direct removal ability of pollutants by technical emission reduction measures was better than the structural emission reduction measures in all four case studies. However, there were no or few carbon reduction co-benefits associated with their utilization; (3) in all cases, CO2 had the highest emission factor value, which means that there is still room for synergistic carbon reduction; (4) air pollutants and CO2 emission intensity from the Yunnan power plants were much higher than that of the other three regions. In order to achieve the overall co-benefits, co-control measures should be promoted and strengthened in western areas such as Yunnan.

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