CFD study of flow and heat transfer in miniature mixers for nanocomposites

U. Sundararaj; Yun Bai; K. Nandakumar

CFD study of flow and heat transfer in miniature mixers for nanocomposites

U. Sundararaj, Yun Bai, K. Nandakumar

Research output: Contribution to conference › Paper › peer-review

Abstract

The Alberta Polymer Asymmetric Mixer (APAM, 2ml) and a mini-batch mixer (MBM, 3ml), which is scaled down from the commercial Haake batch mixer, were built in our lab and used for polymer blends and nanocomposites processing. Previous experimental study has shown that the APAM is effective in mixing polymer blends and nanocomposites. Here we use CFD software, Polyflow from Fluent Inc, to model the transient non-isothermal processing of polystyrene in APAM and in MBM. The flow fields inside MBM and APAM were characterized by velocity profiles, which show the co-existence of shear flow, converging flow and recirculation. The temperature inside both mixers increased due to viscous dissipation. Thermal steady state was reached after 12s and 25s respectively for MBM and APAM. The simulation results were verified by experiment for the MBM by measuring the melt temperature. Finally, the mixing performance of the miniature mixers was characterized using the spatial distribution of shear rate, and shear stress.

Original language	English
Pages	5552
Number of pages	1
State	Published - 2005
Externally published	Yes
Event	05AIChE: 2005 AIChE Annual Meeting and Fall Showcase - Cincinnati, OH, United States Duration: 30 Oct 2005 → 4 Nov 2005

Conference

Conference	05AIChE: 2005 AIChE Annual Meeting and Fall Showcase
Country/Territory	United States
City	Cincinnati, OH
Period	30/10/05 → 4/11/05

Cite this

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title = "CFD study of flow and heat transfer in miniature mixers for nanocomposites",

abstract = "The Alberta Polymer Asymmetric Mixer (APAM, 2ml) and a mini-batch mixer (MBM, 3ml), which is scaled down from the commercial Haake batch mixer, were built in our lab and used for polymer blends and nanocomposites processing. Previous experimental study has shown that the APAM is effective in mixing polymer blends and nanocomposites. Here we use CFD software, Polyflow from Fluent Inc, to model the transient non-isothermal processing of polystyrene in APAM and in MBM. The flow fields inside MBM and APAM were characterized by velocity profiles, which show the co-existence of shear flow, converging flow and recirculation. The temperature inside both mixers increased due to viscous dissipation. Thermal steady state was reached after 12s and 25s respectively for MBM and APAM. The simulation results were verified by experiment for the MBM by measuring the melt temperature. Finally, the mixing performance of the miniature mixers was characterized using the spatial distribution of shear rate, and shear stress.",

author = "U. Sundararaj and Yun Bai and K. Nandakumar",

year = "2005",

language = "英语",

pages = "5552",

note = "05AIChE: 2005 AIChE Annual Meeting and Fall Showcase ; Conference date: 30-10-2005 Through 04-11-2005",

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TY - CONF

T1 - CFD study of flow and heat transfer in miniature mixers for nanocomposites

AU - Sundararaj, U.

AU - Bai, Yun

AU - Nandakumar, K.

PY - 2005

Y1 - 2005

N2 - The Alberta Polymer Asymmetric Mixer (APAM, 2ml) and a mini-batch mixer (MBM, 3ml), which is scaled down from the commercial Haake batch mixer, were built in our lab and used for polymer blends and nanocomposites processing. Previous experimental study has shown that the APAM is effective in mixing polymer blends and nanocomposites. Here we use CFD software, Polyflow from Fluent Inc, to model the transient non-isothermal processing of polystyrene in APAM and in MBM. The flow fields inside MBM and APAM were characterized by velocity profiles, which show the co-existence of shear flow, converging flow and recirculation. The temperature inside both mixers increased due to viscous dissipation. Thermal steady state was reached after 12s and 25s respectively for MBM and APAM. The simulation results were verified by experiment for the MBM by measuring the melt temperature. Finally, the mixing performance of the miniature mixers was characterized using the spatial distribution of shear rate, and shear stress.

AB - The Alberta Polymer Asymmetric Mixer (APAM, 2ml) and a mini-batch mixer (MBM, 3ml), which is scaled down from the commercial Haake batch mixer, were built in our lab and used for polymer blends and nanocomposites processing. Previous experimental study has shown that the APAM is effective in mixing polymer blends and nanocomposites. Here we use CFD software, Polyflow from Fluent Inc, to model the transient non-isothermal processing of polystyrene in APAM and in MBM. The flow fields inside MBM and APAM were characterized by velocity profiles, which show the co-existence of shear flow, converging flow and recirculation. The temperature inside both mixers increased due to viscous dissipation. Thermal steady state was reached after 12s and 25s respectively for MBM and APAM. The simulation results were verified by experiment for the MBM by measuring the melt temperature. Finally, the mixing performance of the miniature mixers was characterized using the spatial distribution of shear rate, and shear stress.

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M3 - 论文

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T2 - 05AIChE: 2005 AIChE Annual Meeting and Fall Showcase

Y2 - 30 October 2005 through 4 November 2005

ER -

CFD study of flow and heat transfer in miniature mixers for nanocomposites

Abstract

Conference

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