Carbon footprint calculation for thermoformed starch-filled polypropylene biobased materials

M.-M. Pang; M.-Y. Pun; W.-S. Chow; Z. A. M. Ishak

doi:10.1016/j.jclepro.2013.07.026

Carbon footprint calculation for thermoformed starch-filled polypropylene biobased materials

M.-M. Pang, M.-Y. Pun, W.-S. Chow, Z. A. M. Ishak

School of Engineering & Physical Sciences

Research output: Contribution to journal › Article › peer-review

18 Citations (Scopus)

Abstract

Thermoformed trays made from biobased materials were prepared from agricultural waste (seeds or tubers), plasticizer and polypropylene (PP). A talc-filled PP thermoformed tray was used for comparison. The carbon footprint of the thermoformed trays was calculated according to PAS 2050. System boundaries were established according to a business-to-business approach, based on data collected regarding the raw material production, transportation and processing. Biobased trays yield a lower carbon footprint than talc-filled polypropylene trays as a result of renewable resource input, a lower processing temperature and shorter thermoforming cycle. The carbon footprint reduction could be achieved through optimization of the thermoforming process and the use of low-footprint raw materials.

Original language	English
Pages (from-to)	602-608
Number of pages	7
Journal	Journal of Cleaner Production
Volume	64
DOIs	https://doi.org/10.1016/j.jclepro.2013.07.026
Publication status	Published - 1 Feb 2014

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10.1016/j.jclepro.2013.07.026

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abstract = "Thermoformed trays made from biobased materials were prepared from agricultural waste (seeds or tubers), plasticizer and polypropylene (PP). A talc-filled PP thermoformed tray was used for comparison. The carbon footprint of the thermoformed trays was calculated according to PAS 2050. System boundaries were established according to a business-to-business approach, based on data collected regarding the raw material production, transportation and processing. Biobased trays yield a lower carbon footprint than talc-filled polypropylene trays as a result of renewable resource input, a lower processing temperature and shorter thermoforming cycle. The carbon footprint reduction could be achieved through optimization of the thermoforming process and the use of low-footprint raw materials.",

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AU - Pang, M.-M.

AU - Pun, M.-Y.

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AU - Ishak, Z. A. M.

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N2 - Thermoformed trays made from biobased materials were prepared from agricultural waste (seeds or tubers), plasticizer and polypropylene (PP). A talc-filled PP thermoformed tray was used for comparison. The carbon footprint of the thermoformed trays was calculated according to PAS 2050. System boundaries were established according to a business-to-business approach, based on data collected regarding the raw material production, transportation and processing. Biobased trays yield a lower carbon footprint than talc-filled polypropylene trays as a result of renewable resource input, a lower processing temperature and shorter thermoforming cycle. The carbon footprint reduction could be achieved through optimization of the thermoforming process and the use of low-footprint raw materials.

AB - Thermoformed trays made from biobased materials were prepared from agricultural waste (seeds or tubers), plasticizer and polypropylene (PP). A talc-filled PP thermoformed tray was used for comparison. The carbon footprint of the thermoformed trays was calculated according to PAS 2050. System boundaries were established according to a business-to-business approach, based on data collected regarding the raw material production, transportation and processing. Biobased trays yield a lower carbon footprint than talc-filled polypropylene trays as a result of renewable resource input, a lower processing temperature and shorter thermoforming cycle. The carbon footprint reduction could be achieved through optimization of the thermoforming process and the use of low-footprint raw materials.

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Carbon footprint calculation for thermoformed starch-filled polypropylene biobased materials

Abstract

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