• Title/Summary/Keyword: Human Body Current

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Measurement and Estimation of Dynamic Resistance of the Human Body Using Body Current at Low-Voltage Levels (저전압에서의 통전전류를 이용한 인체의 동저항 측정 및 예측)

  • 김두현;강동규;김상철
    • Journal of the Korean Society of Safety
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    • v.16 no.1
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    • pp.37-42
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    • 2001
  • The severity of electric shock is entirely dependent on body resistance. When the human body becomes a part of electric circuit, the body resistance is given as a function of shock scenario. Factors which consist of applied voltage, shock duration, body current path and contact area, etc.. The body resistance is defined as the voltage applied to subjects divided by the body current. To secure safety of the subjects, the experiment is conducted on 10 subjects, the body current is limited to 4mA. And only three factors under many shock scenario conditions are used to determine the body resistance. The three factors are the applied voltage, the current pathway and the contact area. The object of this work is to estimate the dynamic resistance of the human body as a function of applied voltage using the body current at low-voltage levels. The data of the body current at low-voltage levels are extrapolated to high-voltage levels using two analytic functions with specified constants calculated by numerical method. Also we can provide permissible body voltage for various copper electrodes on the basis of the data determined with the dynamic resistance and the body current.

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Analysis on Induced Current Density by Electric Field of Human under the 765 kV Transmission Line Considering Permittivity and Conductivity (유전율 및 도전율을 고려한 765kV 송전선하의 전계에 의한 인체내부 유도 전류밀도 해석)

  • 민석원;송기현;양광호;주문노
    • The Transactions of the Korean Institute of Electrical Engineers A
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    • v.53 no.8
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    • pp.461-465
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    • 2004
  • This paper analysed the induced current density by electric field of human body under the 765 kV transmission line considering permittivity and conductivity. As permittivity of human body is very high as $10^6$ at 60 Hz, special numerical computation technique in Surface Charge Method(SCM) for composite media with extremely different properties is applied to reduce calculation error of induced current density and electric field inside the human body. Calculation results show that the average of the induced current density inside human body is about 3mA/$m^2$, which is less than ICNIRP criterion (10mA/$m^2$).

Detection Algorithm and Characteristics on DC Residual Current based on Analysis of IEC60479 Impedance Model for Human Body (IEC60479 인체 임피던스 모델에 근거한 직류누설전류의 특성 및 검출 알고리즘)

  • Kim, Yong-Jung;Lee, Jinsung;Kim, Hyosung
    • The Transactions of the Korean Institute of Power Electronics
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    • v.23 no.5
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    • pp.305-312
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    • 2018
  • DC distribution systems has recently taken the spotlight. Concerns over human safety and stability facility are raised in DC distribution systems. Std. IEC 60479 provides basic guidance on "the effects of shock current on human beings and livestock" for use in the establishment of electrical safety requirements and suggests an electrical impedance of the human body. This study analyzes impedance spectrums based on the electrical equivalent impedance circuit for the human body; human body impedances measured by experiments are analyzed below the fundamental frequency (60 Hz). The analysis shows that the equivalent impedance circuit for the human body should be modified at least in low-frequency range below the fundamental frequency (60 Hz). The DC residual current detection method that can classify electric shock accidents of humans and electric leakages of facilities is proposed by applying the analysis result. The detection method is verified by experiments on livestock.

Analysis on Induced Current Density inside Human Body by 60 Hz ELF Magnetic Fields (60Hz ELF자계에 의한 인체내부 유도 전류밀도 해석)

  • Min Suk Won;Song Ki Hyun
    • Proceedings of the KIEE Conference
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    • summer
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    • pp.581-583
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    • 2004
  • This paper analysed the induced current density characteristics inside human body by extremely low frequency magnetic fields according to varying conductivities of human model. Human model was composed of several organs and other parts of 곳 human body, whose shapes were spheroids or cylinders. Organs taken into account were the brain, heart, lungs, liver and intestines. Applying the boundary element method to the human model, effects of the organ conductivity difference to the induced current distribution were estimated.

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Analysis on Electric Shock Current in DC Electricity (직류환경에서 인체에 흐르는 감전전류 분석)

  • Lee, Jin-Sung;Kim, Hyosung
    • The Transactions of the Korean Institute of Power Electronics
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    • v.21 no.3
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    • pp.254-259
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    • 2016
  • Recently, DC distribution systems have become a hot issue because of the increase in digital loads and DC generation systems according to the expansion of renewable energy technologies. To obtain the practical usage of DC electricity, safety should be guaranteed. The main concerns for safety are twofold: one side is human protection against electric shocks, and the other is facility protection from short faults. "Effects of current on human beings and livestock" (IEC 60479) defines a human body impedance model in electric shock conditions that consists of resistive components and capacitive components. Although the human body impedance model properly works in AC electricity, it does not well match with the electric shock behavior in DC electricity. In this study, the contradiction of the human body impedance model defined by IEC 60479 in case of DC electricity is shown through experiments for the human body. From the analysis of experimental results, a novel unified human body impedance model in electric shock conditions is proposed. This model consists of resistive components, capacitive components, and an inductance component. The proposed human impedance model matches well for AC and DC electricity environments in simulation and experiment.

Experimental investigation of electric currents flowing through human body in electirc shock (전기충격시인체에 흐르는 전류의 실험적 고찰)

  • 김완배;안광윤;윤태원
    • 전기의세계
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    • v.29 no.1
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    • pp.21-27
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    • 1980
  • The effect of electric shock on human body is enormousness, which leads to warmth, tingling, and even death. The mean values of perception currents obtained on 91 men and 39 women are about 0.77(mA) for men and 0.57(mA) for women. The mean value for women is approximately seven tenths that of men. An individual can tolerate, with no adverse effects, repeated exposure to the reactions associated with currents of his let-go level, and the mean value of let-go currents obtained from 27 normal men is 6.29(mA). Lethal currents flowing human body is very dangerous even for a short time. So, it is necessary to have recourse to animal experiments ot determine lethal current for human. An analysis of experimental data indicates that body weight and shock duration are important factors in determining the lethal current. It is suggested that the relationship between current and shock duration is given by I=K/.root.T, and lethal current is proportional to body weight, where I is the current in milliampere, and T is the time in seconds.

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Analysis on Induced Current Density Inside Human Body of Hot-Line Worker for 765kV Double Circuit Transmission Line (765 kV 2회선 송전선의 활선 작업자 인체내부 유도전류 밀도 해석)

  • Min, Suk-Won;Song, Ki-Hyun
    • Proceedings of the KIEE Conference
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    • 2004.11b
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    • pp.46-50
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    • 2004
  • This paper analysed the induced current density inside human body of hot-line worker for 765kV double circuit transmission line according to locations of human body Human was modelled by several organs, which included brain, heart, lungs, liver and intestines. We applied the 3 dimensional boundary element method to calculate induced electric fields.

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The Calculation of Induced Current at the Human Body due to Magnetic Field around Power System Equipment (송변전 설비주변에서의 자기장에 의한 인체에의 유도 전류 계산)

  • Han, In-Su;Park, Jong-Keun;Myung, Sung-Ho;Lee, Byeong-Yoon;Kim, Eung-Sik;Min, Suk-Won
    • Proceedings of the KIEE Conference
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    • 1997.07e
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    • pp.1755-1757
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    • 1997
  • In this paper, a current calculation method based on Kirchhof's Current Law(KCL) and Kirchhof's Voltage Law(KVL) which is necessary to calculate magnetic fields and induced current around the human body is proposed in this paper. Using this method, we can solve the current values of the finite lines comprising the power system equipment. In the assumption that the current values induced in the human body are same, we calculate the induced current values.

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Analysis on Current Density Induced Inside Body of Hot-Line Worker for 765kV Double Circuit Transmission Line (765 kV 2회선 송전선 활선 작업자 인체내부 유도전류 밀도 해석)

  • Song, Ki-Hyun;Min, Suk-Won
    • The Transactions of the Korean Institute of Electrical Engineers C
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    • v.55 no.5
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    • pp.231-238
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    • 2006
  • This paper analysed the induced current density inside human body of hot-line worker for 765kV double circuit transmission line according to locations of human body. Human model was composed of several organs and other parts, whose shapes were expressed by spheroids or cylinders. Organs such as the brain, heart, lungs, liver and intestines were taken into account. Applying the 3 dimensional boundary element method, we calculated induced current density in case a worker was located inside and outside a lowest phase of 765 kV transmission line in which a 60% current of maximum load flowed. As results of study, we found a maximum induced current density in all organs was less than $10mA/m^2$ when a wonder was outside. As one in brain and heart was higher than $10mA/m^2$ when a worker was inside, we propose a method for lowering current density.

Analysis on Induced Current Density Inside Human Body by 60 Hz ELF Magnetic Fields (60Hz ELF 자계에 의한 인체내부 유도 전류밀도 해석)

  • Min Suk-Won;Song Ki-Hyun
    • The Transactions of the Korean Institute of Electrical Engineers C
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    • v.55 no.2
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    • pp.76-81
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    • 2006
  • This paper analysed the characteristics of current density induced inside human body by 60 Hz extremely low frequency magnetic fields according to varying conductivities of human model. Human model was composed of several organs and other parts, whose shapes were expressed by spheroids or cylinders. Organs such as the brain, heart, lungs, liver and intestines were taken into account. Applying the boundary element method to the human model, we estimated effects on the induced current distribution due to differences of the organ conductivity and shape. We find organ conductivity influences most and a cross section area and a position of organ also gives effects.