RU2012004C1 - Method for testing protective properties of shielding outfit - Google Patents

Abstract

FIELD: electrical instrumentation engineering. SUBSTANCE: with the aim of testing protective properties of a shielding outfit the use made of a model provided with electric field pickups, the conductance of which approximates that of a human body; the model is introduced into an electric field, in turn being dressed in the shielding outfit and without it; the coefficient of reduction of the electric field on the model surface is determined from the data obtained by measuring pickup signals; the model is introduced into the electric field by placing it on one of capacitor plates, the size of the plate being larger than that of the model. When the model is tested without the shielding outfit, the model is electrically connected to the plate; when model is tested dressed in the shielding outfit, the outfit is electrically connected to the plate; measurements are taken of pickup signals when the model presents in turn the face and the back to the plate; measurements are taken again following the exchange of connections of the capacitor plates with a power source. EFFECT: enhanced test accuracy, reduced test cost.

Description

 The invention relates to electrical measurements and relates to the protection of a person from the harmful effects of an electric field created by ultra-high voltage electrical installations, including when working under voltage on the potential of the wires of overhead power lines (VL) using shielding kits.

 A known method of controlling the protective properties of shielding kits by evaluating the protective properties of shielding fabrics from which shielding kits are made [1]. The specified method is used practically, however, it is impossible to limit it to testing shielding kits, since the quality of the product is not evaluated.

 The closest technical solution to the invention is a method for monitoring the protective properties of the shielding kit, which consists in determining the coefficient of decrease in electric field strength on the surface of an electrically conductive mannequin placed in a real electric field, using a shielding kit and without it, and in comparison with the normalized smallest of the measured values for each of the sensors [2]. The main disadvantages of this method are low accuracy and high cost of control. To implement the method by reproducing real conditions, test stands are needed, including overhead lines of all voltages, for which a shielding kit of this type is designed. Twice (in the shielding kit and without it) placing the manikin in a strictly identical position relative to the overhead lines is almost impossible. This causes a significant error in determining the coefficient of decrease in electric field strength. The low utilization of expensive stands determines the high cost of implementing the method. Universal shielding kits designed to operate both on the potential of the wires of unconnected overhead lines and on the ground potential, require additional testing on the ground, on the poles of the overhead lines and on disconnected switchgear equipment.

 Thus, the amount of control and labor costs for its implementation are very significant.

 The aim of the invention is to improve the accuracy and reduce the cost of monitoring the protective properties of the shielding kits.

 The goal is achieved by the fact that in the known method of controlling the protective properties of the shielding kit, according to which a mannequin equipped with sensors of electric field intensity is used, made of an electrically conductive material with conductivity close to that of the human body, the mannequin is placed in an electric field in and without a shielding kit and determine the coefficient of reduction of the electric field on the surface of the mannequin according to the results of measurements of the sensor signals when the dummy is tested without a shielding kit, the dummy is electrically connected to the shroud when testing the dummy without the shielding kit, and when testing the dummy in the shielding kit, the shielding kit is electrically connected to the shim.

 The signals of the sensors are measured in the dummy positions with the face and back to the nearest plate and repeat the measurements when the plates are connected opposite to the capacitor power source.

 The use of a capacitor makes it possible to unify the testing process of shielding kits. The unification of the test electric field allows one to obtain comparable results that are not distorted by the changing configuration of the electric field. A homogeneous electric field prior to the introduction of the dummy is, on the one hand, the most difficult for the shielding kit, which makes it possible to better check its protective properties, and on the other hand, it is easily reproducible. In addition, the control process, which is transferred from field to laboratory conditions, is greatly simplified.

 This method allows you to test the shielding kits of any type. So, shielding kits designed to work on the ground potential are tested when the dummy is located only on the grounded capacitor plate, and shielding kits for working on the potential of the wires of disconnected overhead lines are only on the plate connected to the voltage source.

Claims (1)

 METHOD FOR CONTROL OF PROTECTIVE PROPERTIES OF A SCREENING KIT, according to which a mannequin equipped with sensors of electric field strength is used, made of an electrically conductive material with conductivity close to that of a human body, a mannequin is placed in a shielding set and without it in an electric field, the coefficient of decrease in electric field strength on the surface is determined dummy according to the measurement results of sensor signals, characterized in that, in order to improve accuracy and reduce the cost of contact Ole, place the dummy in the electric field of the capacitor by laying the dummy on one of the capacitor plates, the dimensions of which exceed the dimensions of the dummy, when testing the dummy without a shielding kit, connect the dummy electrically to the lining, and when testing the dummy in the shielding kit, electrically connect the shielding kit to the lining, measure sensor signals in the dummy positions with the face and back to the nearest plate, repeat the measurements when the plates are connected to the condensate power source opposite ora.