A DNN based Intelligent Protective Relaying Scheme for Microgrids

Microgrid mandates a highly accurate and reliable protection measure for safe and secure operation. Reliability of the protecting system becomes a serious concern when the microgrid operates with various types of DG units which includes synchronous, induction and inverter based DGs with different topology and modes of operation. This paper demonstrates an intelligent protection scheme using deep neural network (DNN) to perform the task of fault detection and classification. Fault currents retrieved at the relaying points are given to the proposed protection scheme to perform the desired task. The performance of the scheme is measured with wide variations in system parameters such as modes of operation and network topologies of the microgrid. The scheme is extensively tested on a large dataset even by varying types of inputs and different deep neural network structures. The test results and response time show that the proposed algorithm can be used in real time for protective measures of microgrid.

[1]  A. Akhil The CERTS MicroGrid Concept , 2002 .

[2]  Walid G. Morsi,et al.  A New Approach for Fault Classification in Microgrids Using Optimal Wavelet Functions Matching Pursuit , 2018, IEEE Transactions on Smart Grid.

[3]  G. Venkataramanan,et al.  A larger role for microgrids , 2008, IEEE Power and Energy Magazine.

[4]  H J Laaksonen,et al.  Protection Principles for Future Microgrids , 2010, IEEE Transactions on Power Electronics.

[5]  Mohsen Guizani,et al.  Deep Multi-Layer Perceptron Classifier for Behavior Analysis to Estimate Parkinson’s Disease Severity Using Smartphones , 2018, IEEE Access.

[6]  Victor O. K. Li,et al.  Intelligent Fault Detection Scheme for Microgrids With Wavelet-Based Deep Neural Networks , 2019, IEEE Transactions on Smart Grid.

[7]  Sukumar Brahma,et al.  Development of adaptive protection scheme for distribution systems with high penetration of distributed generation , 2004 .

[8]  Nikhil Ketkar,et al.  Deep Learning with Python , 2017 .

[9]  Bill Rose,et al.  Microgrids , 2018, Smart Grids.

[10]  Tarlochan S. Sidhu,et al.  A Protection Strategy and Microprocessor-Based Relay for Low-Voltage Microgrids , 2011, IEEE Transactions on Power Delivery.

[11]  Wei Lee Woon,et al.  A Differential Sequence Component Protection Scheme for Microgrids With Inverter-Based Distributed Generators , 2014, IEEE Transactions on Smart Grid.

[12]  Martin D. Judd,et al.  A Convolutional Neural Network-Based Deep Learning Methodology for Recognition of Partial Discharge Patterns from High-Voltage Cables , 2019, IEEE Transactions on Power Delivery.

[13]  Geza Joos,et al.  Differential energy based microgrid protection against fault conditions , 2012, 2012 IEEE PES Innovative Smart Grid Technologies (ISGT).

[14]  S. R. Samantaray,et al.  Data-Mining Model Based Intelligent Differential Microgrid Protection Scheme , 2017, IEEE Systems Journal.

[15]  Tarlochan S. Sidhu,et al.  A Communication-Assisted Protection Strategy for Inverter-Based Medium-Voltage Microgrids , 2012, IEEE Transactions on Smart Grid.

[16]  Geza Joos,et al.  A Combined Wavelet and Data-Mining Based Intelligent Protection Scheme for Microgrid , 2016, IEEE Transactions on Smart Grid.

[17]  A.A. Girgis,et al.  Development of adaptive protection scheme for distribution systems with high penetration of distributed generation , 2003, IEEE Transactions on Power Delivery.

[18]  Joydeep Mitra,et al.  Microgrid protection using communication-assisted digital relays , 2010, IEEE PES General Meeting.

[19]  Xiaoqing Han,et al.  Review on the research and practice of deep learning and reinforcement learning in smart grids , 2018, CSEE Journal of Power and Energy Systems.

[20]  H. Nikkhajoei,et al.  Microgrid Protection , 2007, 2007 IEEE Power Engineering Society General Meeting.

[21]  Chenglin Wen,et al.  Fault diagnosis based on deep learning , 2016, 2016 American Control Conference (ACC).

[22]  Seyed Hossein Hesamedin Sadeghi,et al.  An overview of microgrid protection methods and the factors involved , 2016 .