• Title/Summary/Keyword: current loss

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Eddy-Current Loss Analysis in Rotor of Surface-Mounted Permanent Magnet Machines Using Analytical Method (해석적 방법을 이용한 표면부착형 영구자석 기기의 회전자 와전류 손실해석)

  • Choi, Jang-Young;Choi, Ji-Hwan;Jang, Seok-Myeong;Cho, Han-Wook;Lee, Sung-Ho
    • The Transactions of The Korean Institute of Electrical Engineers
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    • v.61 no.8
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    • pp.1115-1122
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    • 2012
  • This paper analyzes eddy-current loss induced in magnets of surface-mounted permanent magnet (SPM) machines by using an analytical method such as a space harmonic method. First, on the basis of a two-dimensional (2D) polar coordinate system and a magnetic vector potential, the analytical solutions for the flux density produced by armature winding current are obtained. By using derived field solutions, the analytical solutions for eddy current density distribution are also obtained. Finally, analytical solutions for eddy current loss induced in rotor magnets are derived by using equivalent electrical resistance calculated from magnet volume and analytical solutions for eddy-current density distribution. In particular, the influence of time harmonics in armature current on the eddy current loss is fully investigated and discussed. All analytical results are validated extensively by finite element analysis (FEA).

Effects of Crystal Grain Size and Particle Size on Core Loss For Fe-Si Compressed Cores

  • Takemoto, Satoshi;Saito, Takanobu
    • Proceedings of the Korean Powder Metallurgy Institute Conference
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    • 2006.09b
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    • pp.1183-1184
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    • 2006
  • Core loss of soft magnetic powder cores have been focused on to achieve high efficiency of power supplies. In this study the effects of crystal grain size on core loss were investigated by changing heat treatment conditions. It was found that core loss is influenced by crystal grain size because eddy current loss decreased and hysteresis loss increased by making crystal grain size smaller, and it is also influenced by particle size.

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Iron Loss Analysis Considering Excitation Conditions Under Alternating Magnetic Fields

  • Hong, Sun-Ki;Koh, Chang-Seop
    • Journal of the Korean Institute of Illuminating and Electrical Installation Engineers
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    • v.24 no.3
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    • pp.33-38
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    • 2010
  • In this paper, the nature of iron loss in electrical steel during alternating field excitation is investigated more precisely. The exact definition of AC iron loss is cleared by accurately measuring the iron loss for conditions of both the sinusoidal magnetic field and sinusoidal magnetic flux density. The results of this approach to iron loss calculations in electrical steel are compared to experimentally-measured losses. In addition, an inverse hysteresis model considering eddy current loss was developed to analyze the iron loss when the input is the voltage source. With this model, the inrush current in the inductor or transformer as well as the iron loss can be calculated.

Analysis of Eddy Current Loss in Brushless DC Motor according to the Swiching Frequency of the PWM Inverter (PWM 인버터의 스위칭 주파수에 따른 브러시레스 DC 모터에서의 와전류 손실 특성 해석)

  • Kim, Wa-Sung;Choi, Tae-Sik;Kim, Youn-Hyun;Lee, Ju
    • Proceedings of the KIEE Conference
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    • 2000.07b
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    • pp.675-677
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    • 2000
  • In the paper the eddy current loss in brushless DC motor due to switching frequency supplied by PWM inverter, is analyzed. The compensated conductivity is used in order to analyze the eddy current loss in brushless DC motor which has lamination structure. The eddy current loss is deceased when switching frequency supplied by PWM inverter is gradually increased from 1.2kHz up to 12kHz. The high switching frequency of PWM inverter make the output wave into a similar sine wave and this leads to the decreasing eddy current loss.

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Current Distribution and Loss Calculation of a Multi-layer HTS Transmission Cable (다층 고온 초전도케이블에서의 전류분류 및 손실 계산)

  • 이승욱;차귀수;이지광;한송엽
    • Proceedings of the Korea Institute of Applied Superconductivity and Cryogenics Conference
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    • 2000.02a
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    • pp.29-32
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    • 2000
  • Superconducting transmission cable is one of interesting part in power application using high temperature super-conducting wire as transformance. One important parameter in HTS cable design is transport current distribution because it is related with current transmission capacity and loss. In this paper, we present the calculation theory of current distribution for multi-layer cable using the electric circuit model and in example, calculation results of current distribution and AC loss in each layer of 4-layer HTS transmission cable.

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Analysis of Eddy Current Distribution and Loss in Metal Sheath of 154 kV Single Power Cable (154 kV 단상 전력 케이블의 금속 Sheath에서 발생하는 와전류 분포 및 손실 분석)

  • Im, Sang Hyeon;Kim, Kyoung Youn;Kim, Ki Byung;Park, Gwansoo
    • KEPCO Journal on Electric Power and Energy
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    • v.6 no.2
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    • pp.115-118
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    • 2020
  • As interest in the reduction of energy loss has increased in recent years, analysis of losses in power cables is becoming more important. The overall loss in the transmission system can be measured, but there are many difficulties in researching the loss in each internal structure. There are various factors in the type of loss, and the loss of external factors by previous research has been studied. However, there is little research on the cable internal loss. Since the metal sheath inside the cable is made of aluminum having a high conductivity, an eddy current is generated due to the current flowing in the conductor, thereby causing an eddy current loss inevitably. In this paper, the eddy current loss in metal sheath of 154 kV Cable was researched through FEM (Finite Element Method) electromagnetic analysis.

Effect of the Neighboring Tape′s AC Currents on Transport Current Loss of a Bi-2223 Tape (인접 교류전류가 Bi-2223테이프의 통전손실에 미치는 영향)

  • 류경우;최병주
    • Journal of the Korean Institute of Electrical and Electronic Material Engineers
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    • v.14 no.3
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    • pp.251-256
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    • 2001
  • Bi-2223 tapes have been developed for low-field power applications at liquid nitrogen temperature. When the Bi-2223 tapes are used in an application such as a power transmission cable or a power transformer, they are supplied with an AC transport current simultaneously. AC loss taking into account such real applications is a crucial issue for power applications fo the Bi-2223 tapes to be feasible. In this paper, the transport losses for different AC current levels and arrangements of the neighboring tapes have been measured in a 1./5 m long Bi-2223 tape. The significant increase of the transport losses due to neighboring tape's AC currents is observed. An increase of the transport losses caused by a decrease of the Bi-2223 tape's critical current is a minor effect. The measured trasprot losses could not be explained by a dynamic resistance loss based on DC voltage-current characteristics in combination with the neighboring tape's AC currents.The trasport losses do not depend on the frequency of the neighboring tape's AC currents but is arrangements in the range of small current especially.

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Loss characteristics analysis of HTS DC cable using FEM (FEM을 이용한 초전도 직류 케이블의 손실 특성 분석)

  • Kim, Sung-Kyu;Kim, Seok-Ho;Kim, Jin-Geun;Park, Min-Won;Yu, In-Keun
    • Proceedings of the KIEE Conference
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    • 2011.07a
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    • pp.822-823
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    • 2011
  • The authors analyzed harmonic current based loss of a high temperature superconducting (HTS) DC model cable. The loss in HTS DC cable is generated due to the variation of magnetic field caused by harmonic current in a HVDC transmission system. The authors designed and fabricated two meters of HTS DC model cable for verification of real loss characteristic. In this paper, the loss characteristics caused by harmonic current in the HTS DC model cable are analyzed using commercial finite element method software package. The loss of the HTS DC cable is much less than the loss of the HTS AC cable but the loss should be considered to decide a proper capacity of cooling system.

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Loss Minimization of DFIG for Wind Power Generation

  • Abo-Khalil, Ahmed G.;Park, Hong-Geuk;Lee, Dong-Choon;Lee, Se-Hyun
    • Proceedings of the KIPE Conference
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    • 2007.07a
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    • pp.315-317
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    • 2007
  • This paper proposes a loss minimization algorithm for doubly-fed induction generator (DFIG) by controlling the stator reactive power. The proposed strategy directly controls the rotor current to achieve the operating point of minimum generator loss and maximum power point tracking. The maximum power is obtained by tracking the q-axis rotor current with generator speed variation and the minimum generator loss is achieved by controlling the d-axis rotor current. Experimental results are shown to verify the validity of the proposed scheme.

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Measurement & Analysis of Transport Current AC loss in Coated Conductor Bifilar Structure (Coated Conductor의 Bifilar 구조에서의 통전 교류 손실 측정 및 해석)

  • Bang, J.S.;Park, D.K.;Sim, K.D.;Jang, K.S.;Yang, S.E.;Ahn, M.C.;Kang, H.K.;Seok, B.Y.;Ko, T.K.
    • Progress in Superconductivity and Cryogenics
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    • v.9 no.1
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    • pp.22-26
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    • 2007
  • Superconductor is weak in AC condition. Bifilar geometry provides a solution to reduce AC loss. Bifialr geometry is piled up or wound with more than two layers. When a layer of superconductor abuts on other layers, AC loss is affected by not only self-field, but also magnetic field induced by adjacent layers. In this study, two superconductors are piled up as a series connection so that current flows in different directions. By this method, magnetic field is cancelled. If magnetic field is cancelled, AC loss is reduced. To compare AC loss with respect to piling method, we measured the AC loss difference between the case facing each other with substrate side and the case facing with YBCO side. Measured AC loss is compared with one-way current flow single layer AC loss. In addition, we analyzed how much AC loss was increased, or reduced. All results were compared with those calculated with Norris equation. By this experiment, we concluded that distance between two wires is the important cause of AC loss. The distance between two wires affects magnetic field reduction in YBCO and induced current flow on substrate side.