American Journal of Applied Chemistry

Submit a Manuscript

Publishing with us to make your research visible to the widest possible audience.

Propose a Special Issue

Building a community of authors and readers to discuss the latest research and develop new ideas.

Design and Application of Process for Energy-saving and Environmentally Friendly Automotive Painting

The automotive industry has been developing for nearly a century, and the automotive manufacturing process has been gradually improved. In the process of automobile manufacturing, coating production is an indispensable part, but also the most energy-consuming production link. With the decreasing of ore energy, as well as the increasingly stringent requirements for environmental protection in various regions, the high energy consumption, non-environmental protection, low efficiency and other problems that exist in the current automotive body coating process are exposed more obviously, and a new coating process is needed to upgrade the original process. This paper reduces the emission of industrial waste water and waste gas by adopting new materials such as film pretreatment, "wet-on-wet" coating adhesive and high-solids coating, and at the same time optimises the coating on-line method, medium-free coating process and spraying method to improve the production efficiency and reduce the production cost. Through the use of new materials and new processes, a set of new automotive coating processes with low energy consumption and high efficiency has been designed and applied in automotive enterprises.

Automobile, Painting, Wet-on-Wet Process, Film Pretreatment, High Solid Coating

APA Style

Zhang Tianpeng, Huang Qing, Wu Xiaosong, Li Yongli, Rong Guang. (2023). Design and Application of Process for Energy-saving and Environmentally Friendly Automotive Painting. American Journal of Applied Chemistry, 11(5), 116-121.

ACS Style

Zhang Tianpeng; Huang Qing; Wu Xiaosong; Li Yongli; Rong Guang. Design and Application of Process for Energy-saving and Environmentally Friendly Automotive Painting. Am. J. Appl. Chem. 2023, 11(5), 116-121. doi: 10.11648/j.ajac.20231105.11

AMA Style

Zhang Tianpeng, Huang Qing, Wu Xiaosong, Li Yongli, Rong Guang. Design and Application of Process for Energy-saving and Environmentally Friendly Automotive Painting. Am J Appl Chem. 2023;11(5):116-121. doi: 10.11648/j.ajac.20231105.11

Copyright © 2023 Authors retain the copyright of this article.
This article is an open access article distributed under the Creative Commons Attribution License ( which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

1. Wang Lulu, Gao Chengyong. (2009). Environmental Protection & Energy-saving Technology of the Painting Line. Automobile Technology & Materiall (8). doi: 10.3969/j.issn.1003-8817.2009.08.006.
2. Wang Xichun, Song Hua. (2018). The development history and lessons learned of China's automotive painting and coating. Shanghai Coatings (56). doi: 10.3969/j.issn.1009-1696.2018.02.007.
3. Ming G, Ting G. (2013). Talking about painting robot in commercial vehicle engines painting processes in the application. Manufacturing Automation (35). doi: 10.3969/j.issn. 1009-0134.2013.09. 23.
4. Jian Yunjiu, DENG Dao, WANG Feng. (2020). Discussion on manufacturing technology of automobile green coating. Automobile Applied Technology (11). doi: 10.16638/j.cnki.1671-7988.2020.11.059.
5. Miao Tianhao, Liu Chunliang, Zhao Zhiying, et al. (2019). Application of Silane and Zirconium Film Pretreatment Processes. Shanghai Coatings (59). doi: CNKI: SUN: SHTL.0.2019-01-007.
6. Rong G, HUANG Q, LI Y L, et al. (2021). Study on environmentally friendly painting process for cargo body of commercial vehicle. Electroplating & Finishing (40). doi: 10.19289/j.1004-227x.2021.14.013.
7. Wu Guisheng, Xing Wenping & Wu Jixia. (2017). Study on high-throwing power ED mixture Technology. Automobile Applied Technology (10). doi: 10.16638/j.cnki.1671-7988.2017.10.072.
8. Zhang Xinguo, Deng Liexiong, Liao Zhanglong, et al. (2021). The Analysis and Solution of Cracking Problem of Weld Sealant of Body Roof. Auto Time (12). doi: 10.3969/j.issn.1672-9668.2021.12.061.
9. Xiang Bin, Yang Yongfeng, Wei Feng. (2007). Application and Development Trend of High-Solid Coatings. Modern Paint & Finishing (10). doi: 10.3969/j.issn.1007-9548.2007.10.013.
10. Chen Zhengui. (2020). Discussion on the Design and Application of Skid in the Painting Workshop of New Vehicle Models. Mechanical & Electrical Technology (4). doi: 10.19508/j.cnki.1672-4801.2020.02.012.
11. Guo Wentao, Zhang Jiafeng, Wang Juntao, et al. (2014). Energy-saving Technology for Automotive Painting. Henan Science & Technology (12). doi: 10.3969/j.issn.1003-5168.2014.24.020.
12. Guo Dingbang, MA Zheng, CHEN Junjie, et al. (2013). Comprehensive analysis of the no-medium coating process. Shanghai Coatings (51). doi: 10.3969/j.issn.1009-1696.2013.03.014.
13. Zhang Yang, Cheng Fenghong. (2008). On-site management of automotive topcoat quality. Shanghai Coatings (46). doi: 10.3969/j.issn.1009-1696.2008.03.013.
14. Chu Ming, Cui Puwei, Ling Quan. (2018). Coating spraying robot technological parameters and solution of common problems. Automobile Applied Technology (8). doi: 10.16638/j.cnki.1671-7988.2018.08.057.
15. Wang Li. (2015). Analysis of automobile body coating new technology and its application research. Theoretical Research In Urban Construction (5). doi: 10.3969/j.issn.2095-2104.2015.11.0676.
16. Gao Jianlu, Yang Zhi. (2019). Analysis and solutions in The quality of new energy Van floor mass electrophoresis unqualified problem. Automobile Applied Technology (5). doi: 10. 16638/j. cnki. 1671-7988.2019.05.002.
17. He Xizhong. (2021). Influencing Factors and Control Strategies of Automobile Coating Quality. Auto Time (18). doi: 10.3969/j.issn.1672-9668.2021.18.053.