Your search keyword '"Zheng, Chenghang"' showing total 4 results

1. Electrostatic removal of ultrafine carbon black with square-grooved collecting plates: Insights for capturing black carbon emitted from ships.

Author

Wu, Zhicheng, Wang, Yifan, Shao, Lingyu, Zhang, Hao, Dai, Haobo, Fan, Haidong, Zheng, Chenghang, and Gao, Xiang

Subjects

*SOOT, *CARBON-black, *CARBON emissions, *SHIPS, *CARBONACEOUS aerosols

Abstract

Ships and other mobile pollution sources emitted massive ultrafine and low-resistivity particles containing black carbon (BC), which were harmful to human health and were difficult to capture by conventional electrostatic precipitators (ESPs). In this study, nanoscale carbon black was adopted as simulated particles (SP) with similar physicochemical properties for black carbon emitted from ships (SP-BC) to investigate the feasibility of using an ESP with square-grooved collecting plates for the removal of SP-BC at low backpressures. The increased applied voltage significantly improved the total collection of SP-BC whereas may also promote the conversion of relatively larger particle size SP-BC into nano-size below 20 nm. The outlet number concentration of SP-BC under 27 kV at 130°C was three times that of the inlet. While the reduction of the flow rate could strengthen the capture of SP-BC below 20 nm, and under the combined action of low flow rate and maximum applied voltage, the collection efficiency of 20-100 nm SP-BC could exceed 90%. In addition, the escape and capture characteristics of SP-BC under long-term rapping were revealed. The square-grooved collecting plate could effectively restrain the re-entrainment of collected SP-BC generated by rapping, and the nanoscale SP-BC was trapped in the grooves after rapping. The results could provide insights into the profound removal of massive nanoscale black carbon emissions from mobile sources. [ABSTRACT FROM AUTHOR]

Published

2024

2. Technology development and cost analysis of multiple pollutant abatement for ultra-low emission coal-fired power plants in China.

Author

Zhang, Yongxin, Luo, Cong, Lu, Yan, Zhang, You, Zhou, Can, Zhou, Zhiying, Wu, Xuecheng, Zheng, Chenghang, and Gao, Xiang

Subjects

*COAL-fired power plants, *COST analysis, *POLLUTANTS, *POLLUTION control costs, *DIRECT costing, *COST control

Abstract

The implementation of ultra-low emission (ULE) limits (SO 2 : 35 mg/m3, NO x : 50 mg/m3, PM: 10 mg/m3) promoted the development of flue gas treatment technologies in China. Pollutant control technology development for Chinese coal-fired power plants was summarized and an analysis of the applicability and cost of pollutant control technologies was conducted. Detailed data were collected from 30 ultra-low emission coal-fired units across China. Based on a cost analysis model, the average unit power generation incremental costs were 0.0144 and 0.0095 CNY/(kW·hr) for SO 2 and NO x control technologies, respectively. The unit power generation incremental cost of twin spray tower technology was 7.2% higher than that of dual-loop spray tower technology. The effect of key parameters on operating cost was analyzed. The unit power generation incremental cost increased because of increments in the electricity price for SO 2 control technology and the price of the reductant in NO x control technology. With high sulfur content or NO x concentration, the unit power generation incremental cost caused by pollutant control increased, whereas the unit pollutant abatement cost decreased. However, the annual operating hours or load increased, thereby leading to a decline in unit power generation incremental cost and unit pollutant abatement cost. Unit power generation incremental cost of SO 2 and NO x control technologies for different coal-fired units. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2023

3. Advances in air pollution control for key industries in China during the 13th five-year plan.

Author

Wu, Xuecheng, Yang, Yanping, Gong, Yue, Deng, Zhiwen, Wang, Ying, Wu, Weihong, Zheng, Chenghang, and Zhang, Yongxin

Subjects

*AIR pollution control, *POLLUTION control industry, *EMISSIONS (Air pollution), *FLUE gases, *AIR pollution, *INDUSTRIALIZATION, *EMISSION standards

Abstract

Industrial development is an essential foundation of the national economy, but the industry is also the largest source of air pollution, of which power plants, iron and steel, building materials, and other industries emit large amounts of pollutants. Therefore, the Chinese government has promulgated a series of stringent emission regulations, and it is against this backdrop that research into air pollution control technologies for key industrial sectors is in full swing. In particular, during the 13th Five-Year Plan, breakthroughs have been made in pollution control technology for key industrial sectors. A multi-pollutant treatment technology system of desulfurization, denitrification, and dust collection, which applies to key industries such as power plants, steel, and building materials, has been developed. High-performance materials for the treatment of different pollutants, such as denitrification catalysts and desulfurization absorbers, were developed. At the same time, multi-pollutant synergistic removal technologies for flue gas in various industries have also become a hot research topic, with important breakthroughs in the synergistic removal of NO x , SO x , and Hg. Due to the increasingly stringent emission standards and regulations in China, there is still a need to work on the development of multi-pollutant synergistic technologies and further research and development of synergistic abatement technologies for CO 2 to meet the requirements of ultra-low emissions in industrial sectors. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2023

4. Systematic control technologies for gaseous pollutants from non-ferrous metallurgy.

Author

Liu, Hui, Shen, Fenghua, Li, Qingzhu, Wen, Minneng, Zhang, Hongliang, Jiang, Linhua, Zheng, Chenghang, Liu, Yan, Liu, Tao, and Chai, Liyuan

Subjects

*FLUE gases, *SMELTING furnaces, *POLLUTANTS, *METALLURGY, *SUSTAINABLE development, *WASTE recycling, *AIR pollutants

Abstract

Air pollutant emissions represent a critical challenge in the green development of the non-ferrous metallurgy industry. This work studied the emission characteristics, formation mechanisms, phase transformation and separation of typical air pollutants, such as heavy metal particles, mercury, sulfur oxides and fluoride, during non-ferrous smelting. A series of purification technologies, including optimization of the furnace throat and high-temperature discharge, were developed to collaboratively control and recover fine particles from the flue gas of heavy metal smelting processes, including copper, lead and zinc. Significant improvements have been realized in wet scrubbing technology for removing mercury, fluoride and SO 2 from flue gas. Gas-liquid sulfidation technology by applying H 2 S was invented to recycle the acid scrubbing wastewater more efficiently and in an eco-friendly manner. Based on digital technology, a source reduction method was designed for sulfur and fluoride control during the whole aluminum electrolysis process. New desulfurization technologies were developed for catalytic reduction of the sulfur content in petroleum coke at low temperature and catalytic reduction of SO 2 to elemental sulfur. This work has established the technology for coupling multi-pollutant control and resource recovery from the flue gas from non-ferrous metallurgy, which provides the scientific theoretical basis and application technology for the treatment of air pollutants in the non-ferrous metallurgy industry. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2023