The determination of the electrical resistance of the human body under conditions to be met within underground mining

Smith, Duncan S. Coaske, Paul E.

January 1911

Thesis (B.S.)--University of Missouri, School of Mines and Metallurgy, 1911. / Discrepancy in page numbering - there is no page 5. The entire thesis text is included in file. Typescript. Illustrated by authors. Title from title screen of thesis/dissertation PDF file (viewed February 26, 2009) Includes bibliographical references (p. [ii]).

Electric shock Electrical injuries.

Ground fault detection for human safety utilizing a differential transformer sensor

Williams, Lynn Edward,

January 1968

Thesis (M.S.)--University of Wisconsin--Madison, 1969. / eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references.

Ultrastructural changes in electrically damaged x-enopus laevis sciatic nerve

Margand, Paul Marcus Buchanan

01 January 1991

Electrical injury is known to alter the normal physiological function of nerves. In most cases, the change in function is only minor, but in severe instances the physiological function may be lost entirely. The changes in function involve the ability of the nerve to transmit an impulse, which is a function of the nerve's ability to create and maintain an electrical gradient across its membrane. When the nerve is exposed to an electrical current, the ability to maintain an electrical gradient across the membrane is reduced or lost. This change may be transient or permanent. The changes in the gradient hinder the nerve from propagating the impulse, which is the means of information transfer to and from the CNS (central nervous system). Due to the manner in which human victims are typically exposed to an electric shock, the peripheral axons usually display the greatest change in physiological function.

Sciatic nerve Wounds and injuries

Electrical injuries

Nervous system Wounds and injuries

A study of the causes of industrial accidents in an electricity supply company.

January 1989

by Chan Man Shing, Ho Chak Chong Philip. / Thesis (M.B.A.)--Chinese University of Hong Kong, 1989. / Bibliography: leaves 91-92.

Industrial safety

Industrial safety--China--Hong Kong

Industrial accidents

Industrial accidents--China--Hong Kong

Electrical injuries

Electrical injuries--China--Hong Kong

The simulated effect of the lightning first short stroke current on a multi-layered cylindrical model of the human leg

Lee, Yuan-chun Harry

January 2015

A dissertation submitted to the Faculty of Engineering and the Built Environment, University of the Witwatersrand, Johannesburg, in ful lment of the requirements for the degree of Master of Science in Engineering. Johannesburg, 2015 / This research investigates the e ects of the frequency components of the lightning First Short Stroke (FSS) on the current pathway through human tissues using frequency domain analysis. A Double Exponential Function (DEF) is developed to model the FSS with frequency components in the range 10 Hz 100 kHz. Human tissues are simulated using Finite Element Analysis (FEA) in COMSOL and comprises of two types of models: Single Layer Cylindrical Model (SLCM) and Multi-layered Cylindrical Model (MLCM). The SLCM models 54 human tissues independently and the MLCM models the human leg with ve tissue layers: bone marrow, cortical bone, muscle, blood and fat. Three aspects are analysed: current density, complex impedance and power dissipation. From the SLCM results, aqueous tissues have the lowest impedances and tissue heat dissipation is proportional to tissue impedance. Results from the MLCM show that 85% of the FSS current ows through muscle, 11% ows through blood, 3:5% through fat and the rest through cortical bone and bone marrow. From the results, frequency dependent equivalent circuit models consisting of resistors and capacitors connected in series are proposed. The simulation results are correlated with three main clinical symptoms of lightning injuries: neurological, cardiovascular and external burns. The results of this work are applicable to the analysis of High Voltage (HV) injuries at power frequencies. / MT2017

Tissue engineering

Tissue engineering--Simulation methods

Human engineering--Computer simulation

Electrical injuries

Computational biology