• Journal of the Korean Institute of Illuminating and Electrical Installation Engineers
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• v.17 no.1
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• pp.61-67
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• 2003

This paper presents a power transfer capability calculation algorithm considering initial maximum power transfer capability. In this method initial maximum power transfer capability is calculated first. Then, the initial value of active power outputs of generators is gotten for power transfer capability calculation. The proposed method is applied to IEEE-24 Reliability Test System and the results show the effectiveness of the method.

• Journal of the Korean Institute of Illuminating and Electrical Installation Engineers
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• v.17 no.3
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• pp.18-24
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• 2003

This paper presents a power transfer capability calculation algorithm considering voltage stability margin. In this method, voltage stability margin constraints are incorporated into a power transfer capability formulation to guarantee adequate voltage security levels in an interconnected power system The proposed method is applied to IEEE-24 reliability test systems and the results show the effectiveness of the method.

• The Transactions of the Korean Institute of Electrical Engineers A
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• v.48 no.7
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• pp.872-880
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• 1999

This paper presents an algorithm that can calculate the evaluation index of power system from the transfer capability point of view. The algorithm adopts a successive linear programming skill to solve an optimal solution. Two indices which are transfer margin index and economic matching index have been developed. Prior to calculating these indices, Maximum Load supplying Capability(MLSC) and Economic Load Supplying Capability(ELSC) are utilized as basic data. For man-machine interface, graphical user interface has been implemented so that an unified software package PSTCP(Power System Transfer Capability Program) has been developed. KEPCO systems planned up to 2006 year have been tested to show effectiveness and usefulness of the PSTCP for power system planning stages.

• Journal of Energy Engineering
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• v.7 no.2
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• pp.172-179
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• 1998

In this paper, an alternative method which can evaluate a marginal power exceeding yearly peak load for each load bus is proposed. The proportion of the marginal power to yearly peak load for each load bus is defined as Local Marginal Power Rate (LMPR). Furthermore, the composite system is separated base on the LMPR. The bottleneck facilities could be found, while the LMPR is estimated. Then, it is possible to provide information concerning improvement in the system reliability by bottleneck facilities. The IEEE Reliability Test System (RTS) is used to demonstrate the effectiveness of the proposed algorithm.

• Journal of the Korean Institute of Illuminating and Electrical Installation Engineers
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• v.18 no.5
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• pp.169-173
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• 2004

This paper presents the basic application idea of superconductor cable for voltage stability limited power system. In bulk power system, the transfer capability of transmission line is often limited by the voltage stability, and superconductor cable could be one of the countermeasure to enhance heat transfer limit as well as voltage stability limit. Steady state voltage stability approach by P-V curve is used to calculate the maximum transfer capability of initial system and superconductor applied system. IEEE-14 bus system is used to demonstrate its applicability.

• The Transactions of the Korean Institute of Electrical Engineers A
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• v.49 no.4
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• pp.161-167
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• 2000

This paper presents a new methodology that can evaluate transfer capability of composite power systems from the adequacy point of view in power system planning stages. First of all, to evaluate practical load supplying capability, nonlinear optimization problems of maximum load supplying capability(MLSC) and economic load supplying capability(ELSC) are formulated and solved by nonlinear primal-dual interior point method. Here, physical constraints considered in the optimization problems are the limits of bus voltage, line overloading, and real & reactive power generation. Also, an evaluation method of transfer capability is presented based on margins calculated by the MLSC and ELSC. Especially, to evaluate transfer capability flexibly, simple indices such as expected MLSC, transfer capability margin, and power not supplied are respectively proposed by considering (N-1) line outage probability. Numerical results on IEEE RTS 24, IEEE 118, and IEEE 300 bus system show that the proposed algorithm is effective and useful for power system planning stages.

• Proceedings of the KIEE Conference
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• 2006.07a
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• pp.190-191
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• 2006

전력수요의 급속한 증가에 따라 우리나라 전력계통은 수송밀도가 증가되고 광역화되어 과거에는 가능성이 비교적 낮았던 미국 등 구미 선진국 형 전압안정도 문제의 출현의 가능성이 점차 높아지고 있다. 본 논문에서는 전력계통의 안정도 확보를 위한 무효전력 성능시험의 추진내용과 진상/지상 무효전력의 제한기능 및 실제 운전 중인 발전소의 발전기를 대상으로 성능시험을 통한 무효전력의 공급가능 능력을 검증한 내용을 기술하고자 한다.

• Proceedings of the Korean Institute of Electrical and Electronic Material Engineers Conference
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• 2009.06a
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• pp.341-341
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• 2009

초전도 케이블의 대용량 전력수송능력을 실계통에 적용하기 위해서는 정상상태 뿐 아니라 계통운용상 발생하는 비정상 상태에 대해서도 안정된 성능을 나타내야 한다. 계통운영시 가장 일반적으로 발생하는 비정상 상태의 하나인 계통불평형부하 상태에서의 초전도 케이블의 특성을 실증적으로 확인하기 위해 한전 고창전력시험센터에서 신뢰성시험을 실시하였다. 삼상 송전계통에서 각 상 도체전류는 각 상의 부하량에 의해 결정이 되므로 과도상태라 해도 상당한 시간동안 도체전류가 불평형일 경우 자기적으로 결합된 차폐층전류의 불평형상태가 발생한다. 차폐층전류는 삼상 순환회로의 중성도체가 존재하지 않는 경우 도체전류와의 차이가 발생하게 되어 자기차폐 실패의 원인이 됨으로서 AC손실 증가요인으로서 영향이 커진다. 본 논문에서는 도체전류의 불평형 상태를 실증적으로 모의 발생시켜 연관된 차폐층 순환전류의 형태 및 특성을 검토함으로서 삼상 초전도 케이블의 불평형 부하특성에 대한 연구 진행경과를 요약한다.

• Proceedings of the KIEE Conference
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• 2006.07a
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• pp.365-367
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• 2006

송전망은 전력수송을 가능하게 함으로써, 경쟁적 전력시장을 지지하는 하부구조의 역할을 한다. 하지만 송전망은 여러 제약조건에 의해 수송 한계에 다다를 수 있고 이렇게 공급능력의 한계를 벗어남으로써 발생한 송전혼잡은 전체 계통운영에 있어서 비용 상승을 일으킨다. 본고에서는 송전선로 내 혼잡이 가격에 미치는 영향을 알고 그로 인한 각 모선의 LMP(Locational Marginal Price) 형성에 대해 세부적으로 연구하였다. 그리고 입찰방법을 단순히 이상적인 상창이 아닌 송전 혼잡으로 인해 전력 공급자가 시장지배력을 갖게 되었을 경우에 대하여 적절한 입찰전략의 필요성을 언급하고 가능한 방법을 생각해 보았다.

• Proceedings of the KIEE Conference
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• 1999.07c
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• pp.1514-1516
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• 1999

This paper presents a sequential framework that calculates the total transfer capabilities of power transmission systems. The proposed algorithm enhances the Power System Transfer Capability Program (PSTCP) in conjunction with the Continuation Power Flow(CPF) that is used for steady-state voltage stability analysis and modified Arnoldi-Chebyshev method that calculates rightmost eigenvalues for small signal stability analysis. The proposed algorithm is applied to IEEE 39-bus test system to calculate TTC.