Your search keyword '"High-temperature thermomechanical pulp"' showing total 4 results

1. Composites of High-Temperature Thermomechanical Pulps and Polylactic Acid

Author

Iina Solala, Antti Koistinen, Sanna Siljander, Jyrki Vuorinen, and Tapani Vuorinen

Subjects

Polylactic acid, Wood fiber composites, High-temperature thermomechanical pulp, Thermal properties, Hydrophobic fibers, Mechanical properties, Biotechnology, TP248.13-248.65

Abstract

High-temperature thermomechanical pulps (HT-TMP, defibrated at 150 to 170 °C) were compared to a reference TMP (defibrated at 130 °C) as a reinforcement for polylactic acid (PLA). Composites were prepared by melt compounding, followed by injection molding, gradually increasing the used fiber content from 0 to 20 wt.%. The injection-molded specimens were characterized by tensile and impact strength tests, scanning electron microscopy, water absorption tests, and differential scanning calorimetry. The TMP fiber damage was also characterized before and after melt compounding by optical analysis. At 20% fiber content, the Young’s modulus increased significantly, while the tensile strength remained unchanged and the impact strength decreased slightly. All fibers suffered damage during melt compounding, but the tensile strength remained about the same as in pure PLA. All types of TMP were able to increase the PLA rate of crystallization. The HT-TMP fibers were dispersed more evenly in PLA than the 130 °C TMP. The 170 °C TMP produced composites of lower water absorption than the other two TMP types, probably because of its lower hemicellulose content and its higher surface coverage by lignin.

Published

2015

2. Composites of High-Temperature Thermomechanical Pulps and Polylactic Acid.

Author

Solala, Iina, Koistinen, Antti, Siljander, Sanna, Vuorinen, Jyrki, and Vuorinen, Tapani

Subjects

*COMPOSITE materials, *HEAT resistant materials, *THERMOMECHANICAL treatment, *POLYLACTIC acid, *INJECTION molding, *TENSILE strength, *SCANNING electron microscopy

Abstract

High-temperature thermomechanical pulps (HT-TMP, defibrated at 150 to 170℃) were compared to a reference TMP (defibrated at 130℃) as a reinforcement for polylactic acid (PLA). Composites were prepared by melt compounding, followed by injection molding, gradually increasing the used fiber content from 0 to 20 wt.%. The injection-molded specimens were characterized by tensile and impact strength tests, scanning electron microscopy, water absorption tests, and differential scanning calorimetry. The TMP fiber damage was also characterized before and after melt compounding by optical analysis. At 20% fiber content, the Young's modulus increased significantly, while the tensile strength remained unchanged and the impact strength decreased slightly. All fibers suffered damage during melt compounding, but the tensile strength remained about the same as in pure PLA. All types of TMP were able to increase the PLA rate of crystallization. The HT-TMP fibers were dispersed more evenly in PLA than the 130℃ TMP. The 170℃ TMP produced composites of lower water absorption than the other two TMP types, probably because of its lower hemicellulose content and its higher surface coverage by lignin. [ABSTRACT FROM AUTHOR]

Published

2016

3. Composites of High-Temperature Thermomechanical Pulps and Polylactic Acid

Subjects

Wood fiber composites, Thermal properties, Hydrophobic fibers, POLYPROPYLENE COMPOSITES, Mechanical properties, WOOD, Polylactic acid, High-temperature thermomechanical pulp, FIBER MORPHOLOGY, DEFIBRATION TEMPERATURE, CELL-WALL, LENGTH, BARRIER PROPERTIES, PLA, POLYMER COMPOSITES, ta216, CRYSTALLINITY

Published

2016

4. Composites of High-Temperature Thermomechanical Pulps and Polylactic Acid

Author

Antti E. Koistinen, Sanna Siljander, Iina Solala, Jyrki Vuorinen, Tapani Vuorinen, Department of Forest Products Technology, Tampere University of Technology, Aalto-yliopisto, and Aalto University

Subjects

Thermal properties, Environmental Engineering, Absorption of water, Materials science, lcsh:Biotechnology, Hydrophobic fibers, POLYPROPYLENE COMPOSITES, Mechanical properties, Bioengineering, WOOD, urologic and male genital diseases, Polylactic acid, law.invention, High-temperature thermomechanical pulp, FIBER MORPHOLOGY, chemistry.chemical_compound, Differential scanning calorimetry, DEFIBRATION TEMPERATURE, law, lcsh:TP248.13-248.65, CELL-WALL, Ultimate tensile strength, LENGTH, BARRIER PROPERTIES, heterocyclic compounds, POLYMER COMPOSITES, Fiber, Crystallization, Composite material, Waste Management and Disposal, Wood fiber composites, Izod impact strength test, bacterial infections and mycoses, female genital diseases and pregnancy complications, chemistry, Compounding, PLA, human activities, CRYSTALLINITY

Abstract

High-temperature thermomechanical pulps (HT-TMP, defibrated at 150 to 170 degrees C) were compared to a reference TMP (defibrated at 130 degrees C) as a reinforcement for polylactic acid (PLA). Composites were prepared by melt compounding, followed by injection molding, gradually increasing the used fiber content from 0 to 20 wt.%. The injection-molded specimens were characterized by tensile and impact strength tests, scanning electron microscopy, water absorption tests, and differential scanning calorimetry. The TMP fiber damage was also characterized before and after melt compounding by optical analysis. At 20% fiber content, the Young's modulus increased significantly, while the tensile strength remained unchanged and the impact strength decreased slightly. All fibers suffered damage during melt compounding, but the tensile strength remained about the same as in pure PLA. All types of TMP were able to increase the PLA rate of crystallization. The HT-TMP fibers were dispersed more evenly in PLA than the 130degrees C TMP. The 170 degrees C TMP produced composites of lower water absorption than the other two TMP types, probably because of its lower hemicellulose content and its higher surface coverage by lignin.

Published

2015