Reeved Tooling Design and Finite Element Analysis on Stators of a 400MW Generator

Shao Jie Xin

doi:10.4028/www.scientific.net/AMM.455.593

Paper Titles

Experimental Research in Wind Tunnel of Aerodynamic Characters for New-Type Energy-Saving Conductor
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Degradation Mode Recognition for Battery of Electric Vehicle Based on ART2 Network
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Development of a CAD/CAPP Integrated System for Metal Bellows Expansion Joints
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Design of Shipborne Reducer Box Damping in Reducing Vibration
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Reeved Tooling Design and Finite Element Analysis on Stators of a 400MW Generator
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3D Design and Performance Analysis of Weft Insertion Mechanism of Carbon Fiber Multi-Layer Loom
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Design and Analysis of the Weft Accumulator of the Angle Interlocking Multilayer Loom of Carbon Fiber
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Design and Analysis of the Traction Mechanism of the Angle Interlocking Multilayer Loom of Carbon Fiber
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Process Management Evaluation on Machinery Manufacturing Enterprises
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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vol. 455Reeved Tooling Design and Finite Element Analysis...

Reeved Tooling Design and Finite Element Analysis on Stators of a 400MW Generator

Abstract:

Aiming at the time and labor issues that exist when reeved tools are used to reeve stator cores of different sizes in the case of 400MW gas generator, this article gives a new tooling structure design based on parallel double-crank mechanism for 400MW generators. The tooling enables fast transition between reeving internal and external stators of two different sizes. Three-dimensional modeling and virtual assembly are completed based on software UG, and finite element analysis of tooling structure is performed using software ABAQUS. The results indicate that this newly-designed reeved tooling has a reasonable mechanical structure and its mechanical behaviors meet the design requirements.