Rupesh Dugad scite author profile

In this work, microcellular acrylonitrile-butadiene-styrene foams were developed with utilization of water as a co-blowing agent and CO2 as the primary blowing agent through the solid-state batch foaming process. The effect of saturation parameters with the content of the co-blowing agent has been studied extensively for various foaming attributes. The co-blowing agent enhanced the average cell size and the expansion ratio which are useful for better thermal insulation. The maximum expansion ratio of 29.9 obtained from the effect of saturation temperature and co-blowing agent, 23.6 from the effect of saturation pressure and co-blowing agent, and 22.4 from the effect of saturation time and co-blowing agent. The co-blowing agent significantly affects the cell morphology of polymeric foam with saturation parameters.

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Solid-state foaming of acrylonitrile butadiene styrene through microcellular 3D printing process

Dugad

Radhakrishna

Gandhi

2021

Journal of Cellular Plastics

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The lightweight products with superior specific strength are in great demand in numerous applications such as automotive, aerospace, biomedical, sports, etc. This work focussed on the manufacturing of lightweight products using the cellular three dimensional (3D) printing process. In this work, the continuous microcellular morphology has been developed in a single foamed filament using 3 D printing of carbon-di-oxide (CO2) saturated acrylonitrile butadiene styrene (ABS) filaments. The microcellular structures with average cell size in the range of 6–1040 µm were developed. The influence of printing parameters; nozzle temperature, feed rate, and flow rate on the foam characteristics and cell morphology at different levels were investigated. The different kinds of observed foamed extrudate irregularities were discussed.

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Morphological evaluation of microcellular foamed composites developed through gas batch foaming integrating Fused Deposition Modeling (FDM) 3D printing technique

2021

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In this article, the development of microcellular structure foams has developed by integrating the two successful and existing technologies, namely CO2 gas batch foaming and Fused Deposition Modeling (FDM) 3D printing technique. It is a novel approach to manufacture complex design porous products for customized applications. The eventual cell morphologies of the extruded 3D printing filament depends on the process parameters pertaining to both microcellular foaming and 3D printing processes. Further, morphological study has been conducted to evaluate the cell morphologies of the 3D printing filament developed through customized FDM setup. During this process, the significance of various process parameters including saturation pressure, saturation time, desorption time, feed rate and extrusion temperature were thoroughly studied. To pursue this study base material used was acrylonitrile butadiene styrene (ABS). The 3D printed filaments consisted of cells with an average cell size in the range of 2.3–276 µm and the average cell density in the range of 4.7 × 104 to 4.3 × 109 cells/cm3. Finally, it has found that by controlling the process parameters different cell morphologies can be developed as per the end application.

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Bimodal Microcellular Morphology Evaluation in ABS‐Foamed Composites Developed Using Step‐Wise Depressurization Foaming Process

Radhakrishna

Dugad

Gandhi

2019

Polymer Engineering & Sci

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In this article, the fabrication of bimodal type of cellular structures and multimodal type of cellular structures of acrylonitrile–butadiene–styrene foams has been reported using solid‐state batch foaming process by distinct, stepwise depressurization technique. Each depressurization step induces a distinct nucleation phenomenon, which leads to the development of multimodal cellular microstructures. The significance of crucial process parameters, which includes saturation pressure, holding pressure, holding time and holding steps, was studied in the development of bimodal and multimodal cellular structures. Further, the influence of the depressurization rate on the volume ratio of small cells to large cells vice versa was also studied. The morphological attributes, which includes cell size, cell density, and cell morphologies, were investigated in detail. This study puts forward a basic mechanism to develop and simultaneously control bimodal and multimodal cellular microstructures by altering the crucial process parameters. POLYM. ENG. SCI., 60:113–131, 2020. © 2019 Society of Plastics Engineers

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Rupesh Dugad

Recent advancements in manufacturing technologies of microcellular polymers: a review

Morphological evaluation of ultralow density microcellular foamed composites developed through CO₂-induced solid-state batch foaming technique utilizing water as co-blowing agent

Solid-state foaming of acrylonitrile butadiene styrene through microcellular 3D printing process

Morphological evaluation of microcellular foamed composites developed through gas batch foaming integrating Fused Deposition Modeling (FDM) 3D printing technique

Bimodal Microcellular Morphology Evaluation in ABS‐Foamed Composites Developed Using Step‐Wise Depressurization Foaming Process

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Rupesh Dugad

Recent advancements in manufacturing technologies of microcellular polymers: a review

Morphological evaluation of ultralow density microcellular foamed composites developed through CO2-induced solid-state batch foaming technique utilizing water as co-blowing agent

Solid-state foaming of acrylonitrile butadiene styrene through microcellular 3D printing process

Morphological evaluation of microcellular foamed composites developed through gas batch foaming integrating Fused Deposition Modeling (FDM) 3D printing technique

Bimodal Microcellular Morphology Evaluation in ABS‐Foamed Composites Developed Using Step‐Wise Depressurization Foaming Process

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Morphological evaluation of ultralow density microcellular foamed composites developed through CO₂-induced solid-state batch foaming technique utilizing water as co-blowing agent