Theoretical analysis and simulation of airflow of super high-speed grinding wheel

Y. D. Gong; H. Li; G. Q. Cai

doi:10.4028/0-87849-416-2.507

Theoretical analysis and simulation of airflow of super high-speed grinding wheel

Y. D. Gong, H. Li, G. Q. Cai

Research output: Journal Publication › Article › peer-review

3 Citations (Scopus)

Abstract

The airflow field of super-high speed grinding was analyzed in the paper and the method of computing and analyzing the distribution of the field has been brought forward by applying boundary layer theory. Adopting the method of finite element, the model of airflow field in the 3-D grinding zone has been built up by using software; the solving strategy and the boundary conditions has been defined, where artificial viscosity coefficient in the repetitive and continuous analysis and the method by applying inertia relaxation have been discussed, which helped to revolve stability. The results of simulation was given and analyzed, which can be validated with experiment by using the equipment of PIV (particle image of velocity).

Original language	English
Pages (from-to)	507-510
Number of pages	4
Journal	Key Engineering Materials
Volume	329
DOIs	https://doi.org/10.4028/0-87849-416-2.507
Publication status	Published - 2007
Externally published	Yes

Keywords

Airflow field
Gas barrier
PIV
Simulation
Super-high speed grinding

ASJC Scopus subject areas

General Materials Science
Mechanics of Materials
Mechanical Engineering

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10.4028/0-87849-416-2.507

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abstract = "The airflow field of super-high speed grinding was analyzed in the paper and the method of computing and analyzing the distribution of the field has been brought forward by applying boundary layer theory. Adopting the method of finite element, the model of airflow field in the 3-D grinding zone has been built up by using software; the solving strategy and the boundary conditions has been defined, where artificial viscosity coefficient in the repetitive and continuous analysis and the method by applying inertia relaxation have been discussed, which helped to revolve stability. The results of simulation was given and analyzed, which can be validated with experiment by using the equipment of PIV (particle image of velocity).",

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AU - Gong, Y. D.

AU - Li, H.

AU - Cai, G. Q.

PY - 2007

Y1 - 2007

N2 - The airflow field of super-high speed grinding was analyzed in the paper and the method of computing and analyzing the distribution of the field has been brought forward by applying boundary layer theory. Adopting the method of finite element, the model of airflow field in the 3-D grinding zone has been built up by using software; the solving strategy and the boundary conditions has been defined, where artificial viscosity coefficient in the repetitive and continuous analysis and the method by applying inertia relaxation have been discussed, which helped to revolve stability. The results of simulation was given and analyzed, which can be validated with experiment by using the equipment of PIV (particle image of velocity).

AB - The airflow field of super-high speed grinding was analyzed in the paper and the method of computing and analyzing the distribution of the field has been brought forward by applying boundary layer theory. Adopting the method of finite element, the model of airflow field in the 3-D grinding zone has been built up by using software; the solving strategy and the boundary conditions has been defined, where artificial viscosity coefficient in the repetitive and continuous analysis and the method by applying inertia relaxation have been discussed, which helped to revolve stability. The results of simulation was given and analyzed, which can be validated with experiment by using the equipment of PIV (particle image of velocity).

KW - Airflow field

KW - Gas barrier

KW - PIV

KW - Simulation

KW - Super-high speed grinding

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VL - 329

SP - 507

EP - 510

JO - Key Engineering Materials

JF - Key Engineering Materials

ER -

Theoretical analysis and simulation of airflow of super high-speed grinding wheel

Abstract

Keywords

ASJC Scopus subject areas

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