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Analysis of Smart Grid Voltage Stability with Integration of Demand Load Variation in Smart Energy Network

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Abstract

Loading system of conventional grid is usually overpriced. The assessment of power network in smart grid is very critical to find out by mathematical modeling tools becoming progressively significant. In overall efficiency of grid system is a fundamental aspect of affecting the demand response in particular time limit of a smart grid. Without depending upon a more precise problem representation, this proposed model may also curtail the time schedule concern as well as total costs. This paper set up to determine the voltage stability of IEEE 14 bus power modeling network applying for West Bengal monthly data of demand respond Power scheme and validates its practicability. The acquired result is authenticated with the typical available issues. In our paper we shortly compile the physical conception, calculation process and relevance prospects of a selective stability index that is expressed in illustrating the reference module. When demand requires being shifted point of response, load models are also used our results to examine the revealing value and the indices of different reliability. The observation method was an index values comparison which was acquired by numerical time domain simulation of practical model pattern. Our paper target is to develop process by the cases of stability analysis for development planning of smart network and to maintain a probability of monitoring real-time stability for dispatcher utilize in power network.

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  1. Department of Electrical Engineering, Indian Institute of Engineering Science and Technology, Shibpur, Howrah, 711103, India

    Shouvik Kumar Samanta & Chandan Kumar Chanda

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  1. Shouvik Kumar Samanta
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  2. Chandan Kumar Chanda
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Correspondence to Shouvik Kumar Samanta.

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Samanta, S.K., Chanda, C.K. Analysis of Smart Grid Voltage Stability with Integration of Demand Load Variation in Smart Energy Network. J. Inst. Eng. India Ser. B 103, 341–350 (2022). https://doi.org/10.1007/s40031-021-00672-9

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  • DOI: https://doi.org/10.1007/s40031-021-00672-9

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