Comparative Life Cycle Assessment of Chinese Radial Passenger Vehicle Tire

Xin Sun; Ji Hu Zheng; Peng Zhang; Ming Nan Zhao; He Xia Wu; Yu Ting Yan

doi:10.4028/www.scientific.net/MSF.898.2432

Paper Titles

Thermal Aging Effects on Fire Performance of the Cross-Linked Polyethylene Insulated Cable
p.2399

Online Measuring Method of Interlaminar Cracks of Laminated Composite Based on Image Processing Technology
p.2405

Allocation of the Environmental Impact in Iron and Steel Industry
p.2413

Life Cycle Assessment of Cathode Copper Production
p.2422

Comparative Life Cycle Assessment of Chinese Radial Passenger Vehicle Tire
p.2432

Materials Flow Analysis of Metallic Titanium in China
p.2446

Substance Flow Analysis of Rare Earth Lanthanum in China
p.2455

Thermal Decomposition Characteristics and Drying Process of Municipal Sludge
p.2464

Extraction of the RO Phase from Steel Slag
p.2470

HomeMaterials Science ForumMaterials Science Forum Vol. 898Comparative Life Cycle Assessment of Chinese...

Comparative Life Cycle Assessment of Chinese Radial Passenger Vehicle Tire

Abstract:

The life cycle environmental impacts of the new model radial passenger vehicle tire product was evaluated and compared. the silicon dioxide was added to replace part of the carbon black as filler, with its previous model tire product. The study covers all relevant life cycle stages: from the acquisition of raw materials to the production, use, and end-of-life. The data collected onsite in 2014 by one of the largest Chinese tire companies were used in the assessment. The evaluation is presented in terms of individual impact category according to the CML model. Five impact categories (i.e., global warming potential (GWP), acidification potential (AP), photochemical oxidant creation potential (POCP), eutrophication potential (EP), and human toxicity potential (HTP)) were considered. The research was conducted in accordance with the ISO 14040/14044 standards. The results showed that In all the five impact categories, new model tire product is lower than the previous model in the whole life cycle. It is mostly due to the reduction of the fuel consumption during the use stage, which resulted in replacing part of the carbon black with silicon dioxide. Fuel (gasoline) consumption represents an important contribution to most impact categories, including the GWP, AP, POCP, and EP, during the use stage. Vehicle fuel consumption and its proportion consumed by the tires during the use stage are key factors that contribute to environmental impact during tire life time. The largest contributor to the HTP category is raw material acquisition, mainly because of the impact of the production of organic chemicals. During the raw material acquisition stage, natural rubber, synthetic rubber, carbon black, and organic chemicals represent the largest contribution to the environmental impact categories, which could be mitigated by reducing the use of raw materials, replacing the aromatic oil with environmental oil in the new model tire product.

You might also be interested in these eBooks

View Preview

Info:

Periodical:

Materials Science Forum (Volume 898)

Pages:

2432-2445

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.898.2432

Citation:

Cite this paper

Online since:

June 2017

Authors:

Xin Sun*, Ji Hu Zheng, Peng Zhang, Ming Nan Zhao, He Xia Wu, Yu Ting Yan

Keywords:

Environmental Impact, Life Cycle Assessment (LCA), New Material Formula, Radial Tire Product

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] Yang, L., The analysis of tire life cycle economic, energy and carbon emissions. 2009, Tongji University.

Google Scholar

[2] LIU, Q., Q. CHEN, and J. YANG, The Impact of Tire Rolling Resistance on the Fuel Economy of Vehicle. Automobile Parts, 2011(8): pp.77-80.

Google Scholar

[3] Qian, B., The present situation and the development tendency of energy-saving tire. Advanced Rubber Technology, 2010. 36(3): pp.1-6.

Google Scholar

[4] EC, Regulation (EC) No 1222/2009 of the European Parliament and of 25 November 2009 on the labelling of tires with respect to fuel efficiency and other essential parameters, T.E.P.A.T.C.O.E. UNION, Editor. 2009, European Commission: Brussels.

Google Scholar

[5] EU. EU parliament passes green tire-labeling law. https: /euobserver. com/environment/ 29052. 2009 [cited 2016 7. 10].

Google Scholar

[6] NAS, Tires and Passenger Vehicle Fuel Economy: Informing Consumers, Improving Performance, in Transportation Research Board Special Report. 2007, National Academy of Sciences, Transportation Research Board: Washington, D. C.

DOI: 10.17226/11620

Google Scholar

[7] Deng, Y., Economic operation situation in 2015&prediction in 2016 of China rubber industry, in 2016 China rubber conference. 2016, China Rubber Industry Association Qingdao. p.4.

Google Scholar

[8] ISO, ISO 14040: 2006 Environmental management-Life cycle assessment-Principles and framework. 2006, International Organization for Standardization: Geneva.

DOI: 10.1065/lca2005.03.001

Google Scholar

[9] Zhang, S., H. Zhang, and Y. Liu, Formulation Study of the Tread Compound for 295/75R22. 5 Low Rolling Resistance Tire. Rubber Science and Technology, 2014(11): pp.26-29.

Google Scholar

[10] Xiong, J., et al., Development and application of new type carbon black in tire industry. CHINA SYNTHETIC RUBBER INDUSTRY, 2004. 27(6): pp.388-390.

Google Scholar

[11] Krömer, S., et al., Life cycle assessment of a car tire. 1999, Continental AG: Hannover, Germany. pp.17-18.

Google Scholar

[12] MIIT, Public announcement of accounting circumstances about China's passenger car corporate average fuel consumption in 2014, M. o.I. a.I.T. o. t.P. s.R. o. China, Editor. 2015: Beijing.

Google Scholar

[13] Li, Z., Research of life cycle assessment and application in the tire industry, in Management Science and Engineering. 2011, Shanghai Jiao Tong University Shanghai.

Google Scholar

[14] Jiang, Z., The present situation and the development of comprehensive utilization of waste tires in China. Advanced Rubber Technology, 2011. 37(3): pp.3-7.

Google Scholar