Effect of Drying Temperature on Performance of Soybean Protein-Isolate/Carboxymethyl Cellulose/Stearic Acid Composite Films

Chao Zhang; Xiao Fei Guo; Yue Ma; Xiao Yan Zhao

doi:10.4028/www.scientific.net/AMR.1092-1093.1529

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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 1092-1093Effect of Drying Temperature on Performance of...

Effect of Drying Temperature on Performance of Soybean Protein-Isolate/Carboxymethyl Cellulose/Stearic Acid Composite Films

Abstract:

Drying is important for the matrix formation of composite films. A low drying temperature guarantees the compact matrix, while a higher temperature strengthens the crosslinking of ingredients. A balance point of the compact matrix and higher crosslinking degree was the key to enhance the performance of a composite film. The temperature of 30, 60, 90, and 120 oC was used to dry the soybean protein-isolate/carboxymethyl cellulose/stearic acid composite films. When being dried at 90 oC, the tensile strength of the composite films was 2.63 times higher than that of the control, and the water vapor permeability of the composite films was 77.6 % of that of the control. Hence the temperature of 90 oC was the balance point of the composite films.

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Periodical:

Advanced Materials Research (Volumes 1092-1093)

Pages:

1529-1532

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.1092-1093.1529

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Online since:

March 2015

Authors:

Chao Zhang*, Xiao Fei Guo, Yue Ma, Xiao Yan Zhao

Keywords:

Carboxymethyl Cellulose, Drying Temperature, Soybean Protein-Isolate, Tensile Strength, Water Vapor Permeability

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References

[1] N. Diftis and V. Kiosseoglou: Food Chem. Vol 81 (2003), p.1.

Google Scholar

[2] J.F. Su, Z. Huang, X.Y. Yuan, X.Y. Wang and M. Li: Carbohyd. Polym. Vol 79 (2010), p.145.

Google Scholar

[3] G. Denavi, D.R. Tapia-Blacido, M.C. Anon, P.J.A. Sobral, A.N. Mauri and F.C. Menegalli: J. Food Eng. Vol 90 (2009), p.341.

Google Scholar

[4] G.A. Denavi, M. Perez-Mateos, M.C. Anon, P. Montero, A.N. Mauri and M.C. Gomez-Guillen: Food Hydrocolloid. Vol 23 (2009), p.23 (8) (2094).

Google Scholar

[5] C. Zhang, Y. Ma, D. Ma, X. Yue and X. Zhao: J. Food Sci. Vol 75 (2009), p. C493.

Google Scholar

[6] C. Schmitt, C. Sanchez, S. Desobry-Banon and J. Hardy: Cri. Rev. Food Sci. Nut. Vol 38 (1998), p.689.

Google Scholar

[7] X. Mo, X.S. Sun and Y. Wang: J. App. Polym. Sci. Vol 73 (1999), p.2995.

Google Scholar

[8] C. Zhang, Y. Ma, K. Guo and X. Zhao: J. Agric. Food Chem. Vol 60 (2012), p.2219.

Google Scholar

[9] S.Y. Xu, X.F. Chen and D.W. Sun: J. Food Eng. Vol 50 (2001), p.211.

Google Scholar

[10] X. Li, K. Guo and X. Zhao: Adv. Mat. Res. Vol 150-151 (2010), p.1396.

Google Scholar

[11] C. Zhang, K. Guo, Y. Ma, D. Ma, X. Li and X. Zhao: Int. J. Food Sci. Technol. Vol 45 (2010), p.1801.

Google Scholar

[12] ASTM E 96-93, Annual Book of ASTM Standards, American Society for Testing and Materials, Philadelphia, PA (1993).

Google Scholar

[13] J. Gonzalez-Gutierrez, P. Partal, M. Garcia-Morales and C. Gallegos: Bioresource Technol. Vol 101 (2010), p. (2007).

Google Scholar

[14] A. Jangchud and M.S. Chinnan: LWT Vol 32 (1999), p.89.

Google Scholar

[15] E. Molina, A. Papadopoulou and D.A. Ledward: Food Hydrocolloid. Vol 15 (2001), p.263.

Google Scholar