Improved Cell Morphology and Surface Roughness in High-Temperature Foam Injection Molding Using a Long-Chain Branched Polypropylene

Mendoza-Cedeno, Steven; Kweon, Mu Sung; Newby, Sarah; Shivokhin, Maksim; Pehlert, George J.; Lee, Patrick

doi:10.3390/polym13152404

Cited by 14 publications

(7 citation statements)

References 25 publications

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“…Hence, how to improve the melt strength and foaming behavior of the PP is always a research hotspot. In general, the methods of in situ fibrillated, adding nanoclay, and long-chain branches were used to improve the melt strength of the PP matrix. − Moreover, our previous works found that the novel hollow hierarchical structure, which had excellent filtration characteristics, can be prepared through the adjustment of miscible systems like PP copolymer and high melt strength PP (HMSPP), but whether the polymer composites systems can produce the hollow radially gradient porous structures and its functional mechanism still needs to be further studied.…”

Section: Introductionmentioning

confidence: 99%

Lightweight Polypropylene/Polylactic Acid Composite Foams with Controllable Hollow Radially Gradient Porous Structures for Oil/Water Separation

Huang

Zhang

et al. 2022

Ind. Eng. Chem. Res.

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The structural characteristics of the polymer composite foams play an important role in their properties. Herein, the polypropylene/polylactic acid (PP/PLA) composite foams with the controllable hollow radially gradient porous structures are designed and prepared by the supercritical CO 2assisted foam extrusion coupled with postdrawing auxiliary technology. The above structures consist of the dense skin layer, hollow-core, closed-cell, and open-cell. Under the constant extrusion foaming temperature and pressure, the outer diameter of the as-prepared foams can be adjusted from about 9.8 mm to 5.7 mm, while the inner diameter changes from about 5.5 mm to 1.7 mm, by adding the PLA to regulate the viscoelasticity and thermodynamic differences of the polymeric melt. Besides, the formation mechanism of the hollow radially gradient porous structures is theoretically analyzed. The as-prepared PP/PLA composite foams exhibit outstanding oil/water separation performance, which show potential application in wastewater treatment.

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Section: Introductionmentioning

confidence: 99%

Lightweight Polypropylene/Polylactic Acid Composite Foams with Controllable Hollow Radially Gradient Porous Structures for Oil/Water Separation

Huang

Zhang

et al. 2022

Ind. Eng. Chem. Res.

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“…Microcellular injection technology [ 24 , 25 , 26 ] is a special process to overcome some problems that the conventional injection molding cannot. Most of the microcellular foam plus GCP technology [ 27 , 28 ] emphasizes improving surface roughness problems. Very few papers discuss the effect of GCP on the flow length, tensile property, and gas penetration problem.…”

Section: Introductionmentioning

confidence: 99%

“…In this study, the surface quality of microcellular foam is controlled using a pressure–temperature path control method. Prior studies only discussed the effects of temperature [ 27 ] or pressure [ 16 ]. This study investigates combined effects by temperature and pressure, aiming at optimizing parts’ surface quality in the foaming process.…”

Section: Introductionmentioning

confidence: 99%

Effect of Gas Counter Pressure on the Surface Roughness, Morphology, and Tensile Strength between Microcellular and Conventional Injection-Molded PP Parts

et al. 2022

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Microcellular injection-molded parts have surface defect problems. Gas counter pressure (GCP) is one of the methods to reduce surface defects. This study investigated the effect of GCP on the surface roughness, morphology, and tensile strength of foamed and conventional injection-molded polypropylene (PP) products. GCP is generated by filling up the mold cavity with nitrogen during the injection-molding (IM) process. It can delay foaming and affect flow characteristics of microcellular and conventional injection-molding, which cause changes in the tensile strength, flow length, cell morphology, and surface quality of molded parts. The mechanism was investigated through a series of experiments including tuning of GCP and pressure holding duration. Surface roughness of the molded parts decreased with the increase in GCP and pressure holding duration. Compared to microcellular IM, GCP-assisted foaming exhibited much better surface quality and controllable skin layer thickness.

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“…[28] The surface defects of the microcellular injection molded foam make it difficult to use as appearance parts. [29,30] Thus, researchers are trying to withdraw the mold core and open the mold cavity for a distance to prepare the microcellular injection molded PP Glass fiber 20% 64.29% Mechanical property, foam structure [40] BMWD LCB PP UC CBA 2% -Surface roughness, mechanical property [42] PP PTFE 5% 95% Thermal conductivity, foam structure [43] LCB PP POE 20% -Mechanical property [44] co-PP --58% Foam structure, foaming behavior [29] foam with a high expansion ratio, very low density, as well as maintain the characteristics of microcellular injection molding products. [24,31] Wu et al [32] explored mold opening foam with a chemical foaming agent, and investigated the mechanical properties and weight reduction.…”

Section: Introductionmentioning

confidence: 99%

Fabrication of Microcellular Injection‐Molded Polypropylene with Super High Expansion Ratio by Precision Mold Opening Technology

Gao

Zhao

Zhai

et al. 2022

Macro Materials & Eng

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In this study, microcellular injection molding with the combination of the precision mold opening and rapid heat cycle mold technology is conducted to fabricate the 30% glass fiber reinforced polypropylene (PP/GF30) foam. By optimizing supercritical fluid, mold temperature, mold opening distance, and other process conditions, the injection‐molded PP/GF30 foam with a super high expansion ratio, density of 0.32 g cm−3, and porosity of 75%, is fabricated. The crystallization and rheological properties of the PP/GF30 samples are tested to determine the suitable injection molding parameters. The results show that glass fiber promotes the crystallization of polypropylene (PP) while improving its storage modulus and complex viscosity. The fiber distribution and orientation as well as the cellular structure are investigated by scanning electronic microscopy (SEM) and X‐ray computed tomography. Due to the high mold temperature, the shear effect and melt cavity filling are greatly changed. The oriented fibers in the core layer are randomly moved by the cell growth and presented as a scaffold to support the cell wall structure. The glass fiber increases the PP melt stiffness and avoids cell collapse so that the cellular structure with small cell size and even cell distribution is fabricated. The compression properties, surface roughness, and thermal conductivity are examined.

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Improved Cell Morphology and Surface Roughness in High-Temperature Foam Injection Molding Using a Long-Chain Branched Polypropylene

Cited by 14 publications

References 25 publications

Lightweight Polypropylene/Polylactic Acid Composite Foams with Controllable Hollow Radially Gradient Porous Structures for Oil/Water Separation

Lightweight Polypropylene/Polylactic Acid Composite Foams with Controllable Hollow Radially Gradient Porous Structures for Oil/Water Separation

Effect of Gas Counter Pressure on the Surface Roughness, Morphology, and Tensile Strength between Microcellular and Conventional Injection-Molded PP Parts

Fabrication of Microcellular Injection‐Molded Polypropylene with Super High Expansion Ratio by Precision Mold Opening Technology

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