Maksimum bağlanabilirlik kapasitesi hesabına yönelik geliştirilen yeni bir matematiksel model

Purpose: Distributed generation is the power generation which is realized by being integrated into powersystems from the consumption side. DG promises high potential in terms of reducing environmental andeconomic concerns by increasing power systems efficiency and enabling renewable energy sources to be usedin power generation. On the other hand, DG is contrary to the centralized generation infrastructure of theconventional power systems, and excessive DG penetration in the systems may cause serious problems.Therefore, planning is an essential issue in DG integrations. Theory and Methods:Distributed generation increases voltage around the point they are integrated into the system Voltage variationsare limited within certain values to protect power systems components and the consumers connected to thesystem from damage caused by these voltage increases. The voltages above those limits referred asovervoltage. In order to determine the maximum DG integration capacity from a point into a system withoutcausing overvoltage risks, an analytical approach has been adopted within the consideration of voltageconstraints. Consequently, a mathematical model, which is defined over the characteristic values of theintegration point and the generator, is proposed. Although there are similar mathematical models in theliterature, the contribution of the study is the proposition of a new mathematical model that can fully evaluatethe problem without accepting various assumptions, unlike other mathematical modelsResults: The maximum permissible DG integration capacity calculation is performed on a 34-Bus test system. The results obtained from the proposed mathematical model are compared with those obtained with othermathematical models. The proposed mathematical model has always been able to give the highest and themost consistent results than other mathematical models. Conclusion: Accurate calculation of maximum permissible integration capacity increase the consistency of DG planning studies. With the proposed mathematical model, the most accurate results can be obtained regardless of the integration point and the conditions of the integratio

Harmoniklerin elektromekanik aşırı akım röleleri üzerindeki etkileri

The electromechanical overcurrent protection relays are designed to operate with sinusoidal current. The operation of protective relay with harmonic currents is not reliable. The literature on harmonics and relays covers mostly the theoretical studies. In this paper, the harmonic effects on operation of electromechanical inverse time overcurrent relay (ITOCR) were examined. Not common in existing studies, the behaviour of ITOCR was analysed with laboratory experiments for distorted waveforms. A type of induction disc relay was used as an electromechanical ITOCR in the experiments. The non-sinusoidal load currents that consist of different harmonic spectra were applied to ITOCR and these nonlinear-load currents were processed by a data acquisition card and a harmonic analysis programme in the computer environment. According to the experiment results, the pick up current and the operating time of the ITOCR increase proportionally to the total harmonic distortion (THD) value of the non-sinusoidal current. It is concluded that, this type of relay cannot protect the system reliably due to the harmonic components of current.Elektromekanik aşırı akım koruma röleleri sinüsoidal akım altında çalışmak üzere tasarlanmıştır. Bu rölelerin harmonikli akımda çalışmaları güvenilir değildir. Literatürde harmonikler ve rölelerle ilgili pek çok teorik çalışma bulunmaktadır. Bu makalede, harmoniklerin elektromekanik ters zamanlı aşırı akım rölesinin (TZAAR) çalışmasına etkileri incelenmiş ve TZAAR’nin bozulmuş dalga şekilleri için davranışı deneysel çalışma ile analiz edilmiştir. Deneyde, elektromekanik TZAAR olarak, indüksiyon disk yapısında bir röle kullanılmıştır. Değişik harmonik spektrumlara sahip, sinüsoidal olmayan yük akımları TZAAR’a uygulanmış ve bu yük akımları data toplama kartı ve harmonik analiz programı ile bilgisayar ortamında işlenmiştir. Deney sonuçları gözönüne alındığında, TZAAR’ın çalışma akımı ve çalışma zamanının, sinüsoidal olmayan akımın toplam harmonik distorsiyonu (THD) ile orantılı olarak arttığı görülmüştür. Bu yapıda olan bir rolenin, akımın harmonik içermesi durumunda sistemi güvenli bir şekilde koruyamayacağı sonucu elde edilmiştir

Maximum Permissible Integration Capacity of Renewable DG Units Based on System Loads

Increasing demand for electricity, as well as rising environmental and economic concerns have resulted in renewable energy sources being a center of attraction. Integration of these renewable energy resources into power systems is usually achieved through distributed generation (DG) techniques, and the number of such applications increases daily. As conventional power systems do not have an infrastructure that is compatible with these energy sources and generation systems, such integration applications may cause various problems in power systems. Therefore, planning is an essential part of DG integration, especially for power systems with intermittent renewable energy sources with the objective of minimizing problems and maximizing benefits. In this study, a mathematical model is proposed to calculate the maximum permissible DG integration capacity without causing overvoltage problems in the power systems. In the proposed mathematical model, both the minimum loading condition and maximum generation condition are taken into consideration. In order to prove the effectiveness and the consistency of the proposed mathematical model, it is applied to a test system with different case studies, and the results are compared with the results obtained from other models in the literature

Adaptive protection scheme for a distribution system considering grid-connected and islanded modes of operation

The renewable energy-based distributed generation (DG) implementation in power systems has been an active research area during the last few decades due to several environmental, economic and political factors. Although the integration of DG offers many advantages, several concerns, including protection schemes in systems with the possibility of bi-directional power flow, are raised. Thus, new protection schemes are strongly required in power systems with a significant presence of DG. In this study, an adaptive protection strategy for a distribution system with DG integration is proposed. The proposed strategy considers both grid-connected and islanded operating modes, while the adaptive operation of the protection is dynamically realized considering the availability of DG power production (related to faults or meteorological conditions) in each time step. Besides, the modular structure and fast response of the proposed strategy is validated via simulations conducted on the IEEE 13-node test system

Adaptive Protection Scheme for a Distribution System Considering Grid-Connected and Islanded Modes of Operation

The renewable energy-based distributed generation (DG) implementation in power systems has been an active research area during the last few decades due to several environmental, economic and political factors. Although the integration of DG offers many advantages, several concerns, including protection schemes in systems with the possibility of bi-directional power flow, are raised. Thus, new protection schemes are strongly required in power systems with a significant presence of DG. In this study, an adaptive protection strategy for a distribution system with DG integration is proposed. The proposed strategy considers both grid-connected and islanded operating modes, while the adaptive operation of the protection is dynamically realized considering the availability of DG power production (related to faults or meteorological conditions) in each time step. Besides, the modular structure and fast response of the proposed strategy is validated via simulations conducted on the IEEE 13-node test system