Improved flexibility and water resistance of soy protein thermoplastics containing waterborne polyurethane

Industrial Crops and Products

Volumn 32, Issue 1, 2010, Pages 13-20

  Tian, Huafeng ^a   Wang, Yixiang ^a   Zhang, Lina ^a   Quan, Changyun ^a   Zhang, Xianzheng ^a  

^a WUHAN UNIVERSITY   (China)

Author keywords

Bioapplication; Flexibility; Soy protein; Water resistance; Waterborne polyurethane

Indexed keywords

AQUEOUS DISPERSIONS; BIOAPPLICATIONS; BIODEGRADABLE FILM; BIODEGRADABLE MATERIAL; BIOMEDICAL MATERIAL; BLEND FILMS; DYNAMIC MECHANICAL THERMAL ANALYSIS; HYDROGEN BONDING INTERACTIONS; LIGHT TRANSMITTANCE; POTENTIAL APPLICATIONS; SOY PROTEIN; SOY PROTEIN ISOLATES; STRUCTURE AND PROPERTIES; TENSILE TESTS; WATER SENSITIVITY; WATER-RESISTANCES; WATERBORNE POLYURETHANE; WATERBORNE POLYURETHANES; WET CONDITIONS;

BIOMEDICAL ENGINEERING; DYNAMIC MECHANICAL ANALYSIS; FILMS; HYDROGEN BONDS; MECHANICAL PROPERTIES; PROTEINS; SCANNING ELECTRON MICROSCOPY; TENSILE TESTING; THERMOANALYSIS; WATER CONTENT;

FILM PREPARATION;

AQUEOUS SOLUTION; BIODEGRADATION; PERFORMANCE ASSESSMENT; PHYSIOLOGICAL RESPONSE; PROTEIN; SCANNING ELECTRON MICROSCOPY; SOYBEAN; TENSILE STRESS; TRANSMITTANCE;

GLYCINE MAX;

BIODEGRADABILITY; BIOMEDICAL USE; DISPERSION; FILM; FLEXIBILITY; MEASURING; POLYURETHANE; PROTEIN; TENSILE PROPERTY; THERMAL ANALYSIS; THERMOSETTING POLYMER; TOXICITY; WATER RESISTANCE;

EID: 77954860556     PISSN: 09266690     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.indcrop.2010.02.009     Document Type: Article

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