Mechanical Analysis of the Energy Cycling Control for Further Smart Grid

Bing Qi; Hong Wei Xie; Li Kun Zhang; Li Li Wang; Song Song Chen

doi:10.4028/www.scientific.net/AMR.804.378

Paper Titles

The Study on Dynamic Characteristics for Heald Frame Designed by New Type Composite of Carbon-Fibre
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Applying Hilbert Curve in Facilities Layout
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A Research Method and its Realization of Machine Tool Ergonomic Design
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Incentive Mechanism to Promote Supplier's R&D of Green Technology in Supply Chain
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Mechanical Analysis of the Energy Cycling Control for Further Smart Grid
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Micro Grid Technology Research Based on the Distributed Generation
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The Design and Implementation of Virtual Simulation Experiment Platform
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Minimum Operating Cost Planning for Micro-Grid Power Source Based on Multi-Energy Source Hybrid Power Supply
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Cutting Force Prediction and Simulation for Quasi-Symmetric Milling of the Stator's Inner Helicoid
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HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 804Mechanical Analysis of the Energy Cycling Control...

Mechanical Analysis of the Energy Cycling Control for Further Smart Grid

Abstract:

Power electronic devices always consume a lot of energy, and this energy is then converted into heat, so that the device temperature rises. It will not only affect the device performance in full cycling, but also may result in damage, if the problem of heat dissipation can not be solved. In this paper, we propose an energy cycle approach that can provide a full utilization of the reused energy from the expansion tank to distributed pump. The Power distribution analysis of the controlling cabinet is presented together with the component in power cabinet. With the capacity of power electronic devices and power levels increasing rapidly, the thermal performance of the cooling system can be improved and higher requirements can be obtained.

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Periodical:

Advanced Materials Research (Volume 804)

Pages:

378-382

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.804.378

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Online since:

September 2013

Authors:

Bing Qi, Hong Wei Xie, Li Kun Zhang, Li Li Wang, Song Song Chen

Keywords:

Energy Conservation, Grid-Side, Machine-Side, Mechanical Cycle

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