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Abstract

At present, there is growing concern with climate change and environmental impacts arising from textiles. The carbon footprint measures the total amount of greenhouse gas emissions generated directly and indirectly by human activities. Among silk home textiles, mulberry silk quilts occupy a significant proportion, but there has been no carbon footprint accounting for silk quilt products. In order to identify the key emission processes during the production of mulberry silk quilts and further explore the improvement opportunities, this study calculated and evaluated the carbon footprints of mulberry silk quilts with nine specifications. The results showed that the carbon footprint result was influenced by product weight and size. The larger the size and weight of the product, the larger the carbon footprint result would be. By examining the carbon footprint of a representative piece of mulberry silk quilt (1 kg, 180 cm × 220 cm) throughout the production process, the study found that the carbon footprint result was concentrated in the white silk yarn production stage, exceeding 44.87%. Further, steam was the largest emission source of the carbon footprint, at over 39.56%. In addition, this study compared and analyzed the differences between fresh and dry cocoon reeling technologies. In terms of carbon footprint, the dry cocoon reeling technology produces a larger carbon footprint than the fresh cocoon reeling technology for the same weight of white silk. The findings in this study provide valuable insights into the greenhouse effect impact of mulberry silk quilt production and contribute to sustainable manufacturing practices in the silk industry.

Keywords

Carbon footprint mulberry silk quilt life cycle assessment textiles reeling technology

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References

Masson-Delmotte

Zhai

Pirani

, et al. IPCC 2021: climate change 2021: the physical science basis. Contribution of working group I to the sixth assessment report of the intergovernmental panel on climate change. Cambridge: Cambridge University Press, 2021.

Wang

Analysis of the carbon footprint assessment for textile products based on PAS 2395. Adv Text Technol 2018; 26: 44–46.

Leal Filho

Perry

Heim

, et al. An overview of the contribution of the textiles sector to climate change. Front Environ Sci 2022; 10: 973102.

UNFCCC. UN helps fashion industry shift to low carbon. United Nations: United Nations Framework Convention on Climate Change 2018, https://unfccc.int/news/un-helps-fashion-industry-shift-to-low-carbon. (2018, accessed 10 July 2023).

Ellen Mac Arthur Foundation. Fashion and the circular economy 2017, https://archive.ellenmacarthurfoundation.org/explore/fashion-and-the-circular-economy. (2017, accessed 10 July 2023).

Galli

Wiedmann

Ercin

, et al. Integrating ecological, carbon and water footprint into a “footprint family” of indicators: definition and role in tracking human pressure on the planet. Ecol Indicat 2012; 16: 100–112.

Peters

Svanström

Roos

, et al. Carbon footprints in the textile industry. In: SS Muthu (ed) Muthu SS (ed) Handbook of life cycle assessment (LCA) of textiles and clothing. Cambridge: Woodhead Publishing, 2015, pp. 3–30.

Wang

Liu

, et al. Carbon footprint of textile throughout its life cycle: a case study of Chinese cotton shirts. J Clean Prod 2015; 108: 464–475.

ISO 14067:2018. Greenhouse gases-carbon footprint of products-requirements and guidelines for quantification.

10.

Wang

Ding

, et al. Case study on industrial carbon footprint and industrial water footprint of cotton knits. China Dye Finish 2012; 38: 43–46.

11.

Yao

Carbon footprint evaluation on raw materials stage of textile and garment carbon emission reduction measures: in case of cotton. J Tianjin Polytech Univ 2014; 33: 70–76.

12.

Amin

Mahmud

Anannya

Assessment of carbon footprint of various cotton knitwear production processes in Bangladesh. AATCC J Res 2021; 8: 47–57.

13.

Luo

Ding

Carbon and water footprints assessment of cotton jeans using the method based on modularity: a full life cycle perspective. J Clean Prod 2022; 332: 130042.

14.

Chen

Feng

Liu

, et al. Review on environmental performance evaluation of cotton textile and clothing products in life cycle. Zhejiang Fash Inst Technol 2022; 21: 19–25 + 45.

15.

Feng

Zhang

Ding

Calculation of industrial carbon footprint of worsted wool fabric. Wool Text J 2015; 43: 62–65.

16.

Eady

Carre

Grant

Life cycle assessment modelling of complex agricultural systems with multiple food and fibre co-products. J Clean Prod 2012; 28: 143–149.

17.

Wiedemann

Yan

Herry

, et al. Resource use and greenhouse gas emissions from three wool production regions in Australia. J Clean Prod 2016; 122: 121–132.

18.

Chen

Qian

Yang

, et al Carbon footprint and water footprint of cashmere fabrics. Fibres Text East Eur 2021; 29: 94–99.

19.

Sun

Liu

, et al. Research review on environmental performance assessment of wool and cashmere products. Text Dye Finish J 2023; 45: 1–5.

20.

Barcelos

Salvador

Guedes

, et al. Opportunities for improving the environmental profile of silk cocoon production under Brazilian conditions. Sustainability 2020; 12: 3214.

21.

Astudillo

Thalwitz

Vollrath

Life cycle assessment of Indian silk. J Clean Prod 2014; 81: 158–167.

22.

Ren

Yin

Wang

Life cycle assessment of silk textiles. Consum Guide 2016; 66: 33–35.

23.

Jiang

Chen

Yao

, et al. Product carbon footprint (PCF) assessment of gambiered Canton silk. China Dye Finish 2012; 38: 39–41.

24.

Liu

Huang

, et al. Carbon footprint calculation and assessment of greige and silk wadding products. China Dye Finish 2023; 49: 54–57.

25.

Liu

Zhu

Qiu

, et al. Research progress in environmental performance assessment of silk products. J Silk 2021; 58: 5–9.

26.

Luo

Zhou

, et al. Carbon footprint calculation and assessment of jeans products based on process modularity. Adv Text Technol 2022; 30: 204–210.

27.

International Silk Union. China’s silk consumption pattern and prospect for 2023, https://www.sohu.com/a/721877397_802768. (2023, accessed 6 March 2024).

28.

Liu

Analysis of online reviews about silk quilts based on text mining: a case of Jingdong Mall. J Silk 2023; 60: 11–20.

29.

Wang

Ding

Research progress of textile carbon footprint. J Text Res 2013; 34: 113–119.

30.

Luo

Jin

, et al. Process optimization of novel silk reeling technique. J Text Res 2023; 44: 46–54.

31.

Chen

Liu

, et al. Quality comparison of raw silk made from fresh cocoon and dry cocoon before and after impregnation. J Silk 2018; 55: 13–17.

32.

Liang

Long

Discussion of some quality problems of fresh cocoon reeling. China Fiber Inspect 2015; 13: 40–43.

33.

Huang

Feng

Tao

, et al. Comparative analysis of silk reeling results between mulberry silkworm fresh cocoons and dry cocoons. J South Agric 2014; 45: 887–890.

34.

Zhu

Wei

, et al. Research application and prospect of Guangxi fresh cocoon reeling and related technologies. Guangxi Sericult 2022; 59: 29–37.

35.

Zhu

Comparison of use of fresh cocoon silk and dry cocoon silk in woven weft. J Silk 2014; 51: 15–17.

36.

Zhang

Jiang

Research on differences of fresh cocoon raw silk and dried cocoon raw silk in structure and performance. Adv Text Technol 2015; 23: 1–5.

37.

Gai

Jiang

Chen

, et al. Quality analysis of fresh cocoon silk. J Silk 2015; 52: 25–29.

38.

Cheng

Chen

, et al. Research of the process and production quality of decompressed cooking of fresh cocoons. J Silk 2022; 59: 10–16.

39.

, et al. Study on improving the cohesion performance of fresh cocoon cooking processing. Text Wide Watch 2015; Z1: 125–127.

Carbon footprint calculation and evaluation of mulberry silk quilts

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