Research on Formability of Size Foaming in Biomass Buffer Composites

Xiao Hui An; Peng Liu; Qiang Meng; Cheng Gong Su; Shuang Zhao

doi:10.4028/www.scientific.net/AMM.694.446

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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vol. 694Research on Formability of Size Foaming in Biomass...

Research on Formability of Size Foaming in Biomass Buffer Composites

Abstract:

In order to explore size formability in the molding process of biomass buffer composites and improve quality of foam molding of composites, this paper designed tests of molding make-up and conducted macroscopic characterization to cavity flow of the size. Test results showed that the effect sequence of various factors to molding performance of the size is the mass ratio of water>the mass ratio of fibers>the mass ratio of sodium lignosulphonate>the mass ratio of starch. The molding make-up and actual molding are the best when the mass ratio of fibers is 10%, the mass ratio of water is 50%, the mass ratio of sodium lignosulphonate is 3% and the mass ratio of starch is 28%.

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Periodical:

Applied Mechanics and Materials (Volume 694)

Pages:

446-449

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.694.446

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Online since:

November 2014

Authors:

Xiao Hui An, Peng Liu*, Qiang Meng, Cheng Gong Su, Shuang Zhao

Keywords:

Biomass, Composite Material, Formability, Mold Foaming

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* - Corresponding Author

References

[1] Marechal V, Rigal L: Industrial Crops and Products Vol. 10 (1999), pp.185-200.

Google Scholar

[2] Rutiaga M O, Galan L J, Morales L H: Journal of Polymers and the Environment Vol. 13 (2005), pp.185-191.

Google Scholar

[3] X Jia, J Li, F Li, in: 2010 International Conference on Advances in Materials and Manufacturing Processes, ICAMMP 2010, November 6, 2010 - November 8, 2010, Shenzhen, China, Trans Tech Publications (2011).

Google Scholar

[4] Binying SHE: Study on properties of cushioning material made plant fiber with network structure [D]. Fujian Agriculture and Forestry University (2007). (In Chinese).

Google Scholar

[5] Haining LU, Xiujie Jia, Jianfeng Li: Die & Mould Industry Vol. 3 (2010), pp.45-49.

Google Scholar

[6] Gang LIU. Research on Optimization Technology for Simulation Model of Biodegradable Production Line [D]. Shandong University (2010). (In Chinese).

Google Scholar