The Experts below are selected from a list of 360180 Experts worldwide ranked by ideXlab platform
L Skoczylas - One of the best experts on this subject based on the ideXlab platform.
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a comparative analysis of the geometrical surface texture of a real and virtual Model of a tooth flank of a cylindrical gear
Journal of Materials Processing Technology, 2008Co-Authors: Jacek Michalski, L SkoczylasAbstract:The paper presents the methodology of Modelling tooth flanks of cylindrical gears in the CAD environment. The Modelling consists in a computer simulation of gear generation. A Model of tooth flanks is an envelope surface of a family of envelopes that originates from the rolling motion of a Solid tool Model in relation to a Solid Model of the cylindrical gear. The surface stereometry and topography of the tooth flanks, hobbed and chiselled by Fellows method, are compared to their numerical Models. Metrological measurements of the real gears were carried out using a coordinated measuring machine and a two-dimensional profilometer. A computer simulation of the gear generation was performed in the Mechanical Desktop environment.
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a comparative analysis of the geometrical surface texture of a real and virtual Model of a tooth flank of a cylindrical gear
arXiv: Computational Engineering Finance and Science, 2006Co-Authors: Jacek Michalski, L SkoczylasAbstract:The paper presents the methodology of Modelling tooth flanks of cylindrical gears in the Cad environment. The Modelling consists in a computer simulation of gear generation. A Model of tooth flanks is an envelope curve of a family of envelopes that originate from the rolling motion of a Solid tool Model in relation to a Solid Model of the cylindrical gear. The surface stereometry and topography of the tooth flanks, hobbed and chiselled by Fellows method, are compared to their numerical Models. Metrological measurements of the real gears were carried out using a coordinated measuring machine and a two - and a three-dimensional profilometer. A computer simulation of the gear generation was performed in the Mechanical Desktop environment.
Jacek Michalski - One of the best experts on this subject based on the ideXlab platform.
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a comparative analysis of the geometrical surface texture of a real and virtual Model of a tooth flank of a cylindrical gear
Journal of Materials Processing Technology, 2008Co-Authors: Jacek Michalski, L SkoczylasAbstract:The paper presents the methodology of Modelling tooth flanks of cylindrical gears in the CAD environment. The Modelling consists in a computer simulation of gear generation. A Model of tooth flanks is an envelope surface of a family of envelopes that originates from the rolling motion of a Solid tool Model in relation to a Solid Model of the cylindrical gear. The surface stereometry and topography of the tooth flanks, hobbed and chiselled by Fellows method, are compared to their numerical Models. Metrological measurements of the real gears were carried out using a coordinated measuring machine and a two-dimensional profilometer. A computer simulation of the gear generation was performed in the Mechanical Desktop environment.
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a comparative analysis of the geometrical surface texture of a real and virtual Model of a tooth flank of a cylindrical gear
arXiv: Computational Engineering Finance and Science, 2006Co-Authors: Jacek Michalski, L SkoczylasAbstract:The paper presents the methodology of Modelling tooth flanks of cylindrical gears in the Cad environment. The Modelling consists in a computer simulation of gear generation. A Model of tooth flanks is an envelope curve of a family of envelopes that originate from the rolling motion of a Solid tool Model in relation to a Solid Model of the cylindrical gear. The surface stereometry and topography of the tooth flanks, hobbed and chiselled by Fellows method, are compared to their numerical Models. Metrological measurements of the real gears were carried out using a coordinated measuring machine and a two - and a three-dimensional profilometer. A computer simulation of the gear generation was performed in the Mechanical Desktop environment.
Jinshi Lu - One of the best experts on this subject based on the ideXlab platform.
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numerical simulation of Solid liquid two phase flow field for shellfish precooking processing machine
Australian journal of mechanical engineering, 2020Co-Authors: Xindan Zhang, Yiran Feng, Xu Zhang, Jinshi LuAbstract:In this study, a new type of shellfish precooking processing machine is designed. The corresponding three-dimensional Solid Model is constructed using SOLWORKS, which also introduces basic structur...
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analysis of Solid liquid two phase flow field for shellfish precooking processing machine
International Journal of Mechanical Engineering and Applications, 2017Co-Authors: Xindan Zhang, Xu Zhang, Jinshi LuAbstract:A new type of shellfish precooking processing machine is designed. The corresponding three-dimensional Solid Model are constructed by use of SOLWORKS. It also introduces basic structure and working principle of shellfish precooking machine. Solid-liquid two-phase flow field for shellfish precooking processing machine is simulated by ANSYS FLUENT 15.0, which simulated the distribution of liquid flow and volume fraction of Solid in the pot. The reasons of flow field distribution and the Solid particle volume fraction of the liquid phase flow in the vertical and horizontal planes were analyzed under different mixing speeds. The results show that the Solid-liquid two-phase flow field distribution is reasonable and turbulent region can be formed in the pot. The distribution of flow field and the texture properties of abalone were compared at three different speeds, and the more reasonable mixing speed was determined. The results of the analysis provide references for the optimization of mixer in the future.
Xindan Zhang - One of the best experts on this subject based on the ideXlab platform.
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numerical simulation of Solid liquid two phase flow field for shellfish precooking processing machine
Australian journal of mechanical engineering, 2020Co-Authors: Xindan Zhang, Yiran Feng, Xu Zhang, Jinshi LuAbstract:In this study, a new type of shellfish precooking processing machine is designed. The corresponding three-dimensional Solid Model is constructed using SOLWORKS, which also introduces basic structur...
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analysis of Solid liquid two phase flow field for shellfish precooking processing machine
International Journal of Mechanical Engineering and Applications, 2017Co-Authors: Xindan Zhang, Xu Zhang, Jinshi LuAbstract:A new type of shellfish precooking processing machine is designed. The corresponding three-dimensional Solid Model are constructed by use of SOLWORKS. It also introduces basic structure and working principle of shellfish precooking machine. Solid-liquid two-phase flow field for shellfish precooking processing machine is simulated by ANSYS FLUENT 15.0, which simulated the distribution of liquid flow and volume fraction of Solid in the pot. The reasons of flow field distribution and the Solid particle volume fraction of the liquid phase flow in the vertical and horizontal planes were analyzed under different mixing speeds. The results show that the Solid-liquid two-phase flow field distribution is reasonable and turbulent region can be formed in the pot. The distribution of flow field and the texture properties of abalone were compared at three different speeds, and the more reasonable mixing speed was determined. The results of the analysis provide references for the optimization of mixer in the future.
Edward J Anthony - One of the best experts on this subject based on the ideXlab platform.
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a discrete pore size distribution based gas Solid Model and its application to the cao co2 reaction
Chemical Engineering Science, 2008Co-Authors: Joh R Grace, Jim C Lim, Edward J AnthonyAbstract:Abstract Experimental data obtained in both atmospheric and pressurized thermogravimetric reactors indicate that carbonation is insensitive to the CO 2 partial pressure in terms of final conversion and apparent carbonation rate. A new gas–Solid Model is formulated to describe the entire experimental carbonation history, with measured rate constant and pore size distribution data as input. The effective diffusivity in the product layer is the only fitting parameter, dependent on the evolution of the pores. The Model is able to predict atmospheric and pressurized thermogravimetric reactor carbonation data with fitted activation energies of 215 and 187 kJ/mol for the limestone and dolomite tested.
