Your search keyword '"Hsin-Shu Peng"' showing total 9 results

1. Influence of low-fracture-fiber mechanism on fiber/melt-flow behavior and tensile properties of ultra-long-glass-fiber-reinforced polypropylene composites injection molding

Author

Chao-Tsai Huang, Hsin Shu Peng, Po Wei Huang, and Sheng Jye Hwang

Subjects

0209 industrial biotechnology, Materials science, Polymers and Plastics, General Chemical Engineering, Polypropylene composites, Glass fiber, 02 engineering and technology, Molding (process), 021001 nanoscience & nanotechnology, 020901 industrial engineering & automation, Ultimate tensile strength, Materials Chemistry, Fracture (geology), Fiber, Composite material, 0210 nano-technology, Melt flow index

Abstract

In this study, an injection molding machine with a low-fracture-fiber mechanism was designed with three stages: a plasticizing stage, an injection stage, and a packing stage. The fiber-fracture behavior is observed under the screw (plasticizing stage) of low-compression/shear ratio for the ultra-long fiber during the molding process. The molding material employed in this study was 25-mm-ultra-long-glass-fiber-reinforced polypropylene (PP/U-LGF). In addition, a thickness of 3 mm and a width of 12 mm spiral-flow-mold were constructed for studying the melt flow length and flow-length ratio through an experiment. The experimental results showed that the use of an injection molding machine with a three-stage mechanism decreased the fiber length when the screw speed was increased. On average, each fiber was shortened by 50% (>15 mm on average) from its original length of 25 mm. Longer glass fibers were more resistant to melt filling, and as the fiber length was reduced, the mixing between the melt and glass fibers was improved. Thus, the melt fluidity and fiber ratios were increased. In addition, the mixing/flow direction of the melt had an impact on the dispersion and arrangement of glass fibers, thus the tensile strength of PP/U-LGF increased.

Published

2020

2. Effects of high-efficiency infrared heating on fiber compatibility and weldline tensile properties of injection-molded long-glass-fiber-reinforced polyamide-66 composites

Author

Hsin-Shu Peng and Po-Wei Huang

Subjects

Materials science, 010304 chemical physics, Polymers and Plastics, General Chemical Engineering, Glass fiber, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, 0103 physical sciences, Ultimate tensile strength, Polyamide, Compatibility (mechanics), Materials Chemistry, Infrared heater, Composite material, 0210 nano-technology

Abstract

Glass fiber composites are prevalent molded materials used in various fields, including aviation engineering, automobile manufacturing, and medical equipment production. The length of a glass fiber affects the mechanical properties of a glass fiber composite. Studies have reported that breakage occurs in long fibers subjected to screw plasticization, injection processes, and geometrical changes in injection molding. Moreover, multigate injection molding can result in weldlines on the final product, consequently reducing its strength. Further exploration is required to determine how product strength is affected by weldlines generated through injection molding with glass fiber composites and how product tensile properties associated with weldlines can be improved. Therefore, this study designed a mold with a vent area and a plug-in mold-surface-heating device to examine changes in the weldlines and tensile properties of long-glass-fiber composite specimens fabricated through injection molding using two melts. The results revealed that fiber length decreased with increasing screw speed; such declines in fiber length affected the tensile strength of the long-glass-fiber-reinforced polyamide-66 composites. In addition, because the arrangement and distribution of the glass fibers were affected by the melt flow rate, melt flow direction, and changes in mold cavity volume, the weldline tensile strength varied with the depth of the vent area. Mold surface heating improved the specimen surface roughness by 5.79% and effectively improved the interfacial adhesion between the fibers and melts, thereby resulting in more favorable weldline tensile strength. This also notably reduced the depth of weldlines produced by the adhesion of two melts.

Published

2020

3. Mold-Face Heating Mechanism, Overflow-Well Design, and Their Effect on Surface Weldline and Tensile Strength of Long-Glass-Fiber-Reinforced Polypropylene Injection Molding

Author

Po-Wei Huang, Wei-Huang Choong, and Hsin-Shu Peng

Subjects

Materials science, Polymers and Plastics, Glass fiber, 02 engineering and technology, Molding (process), 010402 general chemistry, 01 natural sciences, Article, lcsh:QD241-441, chemistry.chemical_compound, lcsh:Organic chemistry, Ultimate tensile strength, Surface roughness, Fiber, Composite material, Polypropylene, General Chemistry, 021001 nanoscience & nanotechnology, long-glass-fiber-reinforced polypropylene, 0104 chemical sciences, mold-face heating, weldline, Creep, chemistry, tensile strength, surface roughness, 0210 nano-technology, Size effect on structural strength

Abstract

Long-fiber polymers offer the advantage of a lower production cost because specific tool designs are required for conventional injection molding equipment to produce long-fiber polymer parts. The use of long fibers allows relatively high fiber aspect ratios to be obtained, thereby enhancing composite stiffness, strength, creep endurance, and fatigue endurance. However, the multigate design of the injection-molded part can result in weldline formation during the molding process, which reduces the structural strength of the molded part. Therefore, in this study, the surface quality, fiber compatibility, and structural strength of long-glass-fiber-reinforced polypropylene (PP/LGF) injection-molded samples were compared in the use versus nonuse of a mold-cavity overflow-well area and the mold-face infrared heating method. The experimental results indicate that the mold-cavity overflow-well area more greatly improved the surface roughness of the PP/LGF molded samples. Moreover, the infrared heating of the mold-face decreased the weldline depth of the samples. Optical-microscopy images and mold-cavity pressure distributions indicated that the weldline tensile strength and the interface compatibility between fibers and melts at the weldline region during the molding stage were higher in the use than in the nonuse of the mold-cavity overflow-well and mold-face infrared heating method.

Published

2020

4. Number of Times Recycled and Its Effect on the Recyclability, Fluidity and Tensile Properties of Polypropylene Injection Molded Parts

Author

Hsin-Shu Peng and Po-Wei Huang

Subjects

Materials science, Geography, Planning and Development, TJ807-830, Molding (process), Management, Monitoring, Policy and Law, TD194-195, Crystallization rate, Renewable energy sources, Crystallinity, chemistry.chemical_compound, Ultimate tensile strength, GE1-350, Composite material, Cavity pressure, Melt flow index, Polypropylene, Environmental effects of industries and plants, Renewable Energy, Sustainability and the Environment, material flow ability and properties, Environmental sciences, reduce–recover–recycle, tensile strength, chemistry, circular manufacturing of plastic injection molding, Viscosity index, sustainability performance of polypropylene

Abstract

The ease with which modern plastics can be injection molded makes them very suitable for the production of many different products and, today, plastics are often used as substitutes for metal. Polypropylene (PP) is one of the most widely used thermoplastics globally since it is very useful, cost-effective and flexible for molding. However, the amount of harm to the environment caused by plastic waste has become phenomenal and the recycling of plastics has become a serious aspect of environmental protection. PP, as the most commonly used plastic material, was selected for use in this study. It has a melt flow index of 15 g/min and its recyclability, fluidity, and physical properties, as well as manufacturing conditions, were explored in relation to the number of times the material could be recycled (TR). A cavity pressure sensor was used to measure the viscosity index of the recycled plastic after multiple cycles of plasticizing and injection, part molding, scrap-recycling, and crushing. A paperclip-shaped test specimen was used to determine PP fluidity and crystallinity of specimens with different TRs. Tensile tests were used to detect differences in the tensile strength between specimens made from Raw-PP and recycled PP. The results showed that PP that had been recycled several times had a higher melt flow index, material fluidity, melting peak area, crystallinity, crystallization rate, and crystallization temperature. Repeated injection and recycling of the material had reduced the length of the molecular chains and broadened the molecular weight distribution. This improved the fluidity and increased crystallinity. The increase in fluidity made cavity filling easier, reducing the cavity pressure as well as the viscosity index. The results of this study showed that the recycling of the PP could improve the physical properties of the products to a degree and also went some way to further the benefits of a circular economy. The recycling of injection-molded PP material can be added to renewable energy technologies and used in environmental impact assessment.

Published

2021

5. Investigations of the Effects of Cavity-Surface Temperature and Fiber Compatible on Weldline Tensile Strength of Long Glass Fiber Reinforced PA66 Injection Molded Parts

Author

Po-Wei Huang, Wei-Jie Su, Hsin-Shu Peng, Kai-Fu Liew, and Wei-Huang Choong

Subjects

Materials science, Ultimate tensile strength, Glass fiber, Compatibility (mechanics), Infrared heater, Composite material, Cavity pressure

Abstract

This study used the cavity-surface infrared rapid-heating method and tensile specimens (ASTM-D638) to test the fiber compatibility and tensile characteristics of long glass fiber reinforced PA66 (LGF-PA66) composites. The weldline molding experiment on the injected specimen was conducted using a double-gate. In addition, the integration of infrared heating and cavity pressure measurement were developed to achieve cavity-surface heating and observe the effect of with/without cavity-surf ace heating on weldline tensile strength variation and correlated pressure distribution near the weldline region. On the other hand, a vent -well was designed in the center position of the specimen (vent-well depths are 0.9 mm, 1.8 mm, and 3.6 mm), in order to discuss the effect of the two-melts on fiber and melt compatibility in the compatible process. The experimental results show that vent-well provides better weldline tensile strength; moreover, infrared heating cavity -surface also provides the better weldline tensile strength of LGF-PA66 composites molded parts. In addition, from SEM images and cavity pressure distributions, considering in presence or absence of vent-well design and cavity-surface heating, it provides better weldline tensile strength and interfaces compatibility between fiber and resin at weldline region during molding stage.

Published

2019

6. Study of CAE predictive analytics on structure design, molding and improved strength of plastic injection molded parts

Author

Pai-Cheng Chien, Wei-Jie Su, Po-Wei Huang, Hsin-Shu Peng, and Kai-Fu Liew

Subjects

chemistry.chemical_classification, Engineering drawing, Materials science, Compression molding, 02 engineering and technology, Molding (process), Polymer, 021001 nanoscience & nanotechnology, Corrosion, Stress (mechanics), 020303 mechanical engineering & transports, 0203 mechanical engineering, Flexural strength, chemistry, Ultimate tensile strength, Composite material, 0210 nano-technology, Size effect on structural strength

Abstract

In recent years, due to the raising of green manufacturing and environmental consciousness, the industrial equipment and molded product request toward energy saving, reducing cycle time and secondary process procedure. With high strength, high stiffness, high design possibility, better fatigue life and better corrosion resistance capability, PA66 polymer composite materials are gaining more and more attention in functional products. In this study, PA66 polymer composites material used in slide components molding to replace the original metal material. The results indicated that PA66 polymer composites add 2%wt MoS2 result higher tensile strength and flexural strength than the original polymer material. The value of increased strength of tensile strength is 8% and flexural strength is 27%. In addition, the CAE simulated results are successful to predictive molding characteristics and improve structural strength of molded parts.

Published

2017

7. Effects of Processing Parameters on Tensile Strength of Thin-Wall HDPE Parts Injection Molded by Ultra High-Speed Process

Author

Shia-Chung Chen, Hsin-Shu Peng, Pe-Ming Hsu, and Hai-Mei Li

Subjects

Materials science, Polymers and Plastics, General Chemical Engineering, Materials Science (miscellaneous), Molding (process), Polyethylene, medicine.disease_cause, chemistry.chemical_compound, chemistry, Mold, Ultimate tensile strength, Materials Chemistry, medicine, High-density polyethylene, Composite material, Spiral, Tensile testing, Melt flow index

Abstract

This study explores how ultra high-speed processing parameters affect the melt flow length and tensile strength of thin-wall injection molded parts. A spiral shaped mold with a specimen thickness of 0.4 mm and a width of 6 mm was first constructed to test the melt flow length as an index of process capability for ultra high-speed injection molding. It was observed that the flow length increases with increasing injection speed. High-density polyethylene (HDPE) tensile test specimens with different thicknesses (0.6 mm and 2 mm) were also molded for tensile tests. Both single gate and double gates were used to form parts without and with weldlines. Injection molding trials were executed by systematically adjusting related parameters setting including mold temperature, melt temperature, and injection speed. The parts’ tensile strengths were measured experimentally. It was found that tensile strengths of 0.6 mm thick parts both with and without weldlines were higher than those of 2 mm thick parts. The tensile ...

Published

2011

8. Investigations on the Weldline Tensile Strength of Thin-wall Injection Molded Parts

Author

Shia-Chung Chen, Rean Der Chien, Hsin-Shu Peng, Pao-Lin Su, and Chun-Sheng Chen

Subjects

Materials science, Polymers and Plastics, Mechanical Engineering, 02 engineering and technology, 021001 nanoscience & nanotechnology, 020303 mechanical engineering & transports, 0203 mechanical engineering, Mechanics of Materials, Thin wall, Ultimate tensile strength, Mechanical strength, Materials Chemistry, Ceramics and Composites, Composite material, 0210 nano-technology

Abstract

It is known that the weldline reduces the mechanical strength of the conventional injection molded parts. Systematic studies on the weldline strength of thin-wall molded parts were not yet reported. This study investigates the effect of processing conditions including melt temperature, mold temperature, injection speed and packing pressure on the weldline strength of thin-wall parts. Tensile test specimen of 2.5, 1 and 0.8 mm thick were injection molded under specified conditions. Both single gate and double gates were used to form parts with and without weldlines. Part tensile strengths were measured experimentally. From the experimental results, it was found that higher melt temperature and mold temperature as well as faster injection speed will increase weldline strength whereas higher packing pressure would decrease weldline strength. Melt temperature and mold temperature are two parameters that affect weldline strength most significantly within the current molding window. Higher melt and mold temperatures not only lower the residual stress but also help the diffusion of molecular chains leading to a higher degree of bonding at the weldline interface. On the other hand, high packing pressure leads to higher residual stress formation and reduces the molecular bonding rate. Part thickness also exhibits significant effect on weldline strength reduction. Thinner parts resulting in higher percentage of frozen layer in filling process thus limit the bonding rate at weldline interface. From the regression analysis, the KIM model with corrected terms in the fitting coefficient was found to correlate process conditions and weldline strength reduction quite well.

Published

2004

9. Investigations of the Tensile Properties on Polycarbonate Thin-Wall Injection Molded Parts

Author

Lei-Ti Huang, Hsin-Shu Peng, Ming-Shiu Chung, and Shia-Chung Chen

Subjects

Materials science, Polymers and Plastics, Mechanical Engineering, Modulus, 02 engineering and technology, Molding (process), 021001 nanoscience & nanotechnology, medicine.disease_cause, 020303 mechanical engineering & transports, 0203 mechanical engineering, Mechanics of Materials, Residual stress, Mold, Thin wall, visual_art, Ultimate tensile strength, Materials Chemistry, Ceramics and Composites, medicine, visual_art.visual_art_medium, Composite material, Polycarbonate, 0210 nano-technology, Tensile testing

Abstract

Effect of processing conditions including injection speed, melt temperature, mold temperature and packing pressure on tensile properties of polycarbonate (PC) thin-wall parts were investigated. Tensile test specimen with thickness of 2.5, 1.0 and 0.8 mm were injection molded under specified conditions. Tensile properties and residual stresses were measured experimentally. It was found that the residual stress plays a more significant role in influencing part tensile properties than flow-induced molecular orientation. Part thickness and injection speed are two key factors that affect residual stress most significantly within the current molding window. As part thickness decreases, residual stress increases resulting in the greater influence in reduction of part tensile strength, yield stress as well as Young’s modulus. Higher melt temperature and higher mold temperature would reduce residual stress whereas higher injection speed and higher packing pressure would increase residual stress. Associated with the decrease of residual stress, part’s tensile strength, yield strength and Young’s modulus increase with increased melt temperature, mold temperature and injection speed. On the other hand, higher packing pressure results in a decrease of part mechanical strength.

Published

2003