RU2388003C1 - Method for electric field intensity measurement - Google Patents

Abstract

FIELD: measurement technique. ^ SUBSTANCE: claimed invention refers to measurement technique and can be used to measure electric field intensity in wide spatial range with improved accuracy and sensitivity. The claimed method features three-dimensional sensor, i.e. n=3, which is oriented in space so that one of the intensity vector components on one of the sensor coordinate axes becomes equal to zero, then while fixing sensor in this position, rotate sensor around found coordinate axis until other two components of electrical field intensity vector on sensor coordinate axes become equal to each other. Herewith module of measured electrical field intensity vector is determined by measuring algebraic sum of two not equal to zero components of electrical field intensity vector on sensor coordinate axes. ^ EFFECT: implementation of possibility to measure electrical field intensity vector in wide spatial range with improved sensitivity and accuracy. ^ 1 dwg

Description

The invention relates to the field of measuring equipment and can be used to measure the electric field in a wide spatial range with increased accuracy and sensitivity.

The known one-coordinate method for measuring electric field strength [Morozov Yu.A., Gromov OM A device for measuring the electric field of industrial frequency. // Scientific works of labor protection institutes of the All-Union Central Council of Trade Unions. - M.: Profizdat. - 1970. - Iss. 65. - S.41-44], based on the placement in the investigated space of one pair of sensitive elements included in the common sensor and located on the coordinate axis passing through the center of the sensor, the orientation of these sensitive elements in an electric field until the maximum component is obtained and the vector module is determined tension by measuring this component.

The advantage of this method of measuring the electric field is that the device that implements this method has a narrow range of input signals and a simple circuit implementation.

The disadvantages of this method are the low accuracy of measuring the vector of the intensity of an inhomogeneous electric field, low sensitivity and a narrow spatial range of measurement.

There is also a two-coordinate method for measuring electric field strength [Bocker N., Wilhelmy L. Messung der elektrischen Feldstarke bei hohen transienten und periodisch zeitabhangigen Spannungen. // Elektro-techniche zeitschrift. - 1970. - A91. - No. 8. - S.427-430], based on placing two pairs of sensing elements in the space under study that are part of a common sensor and located on two coordinate axes passing through the center of the sensor, orienting these sensitive elements in two planes of the electric field, measuring its two components and determination of the modulus of the tension vector by geometric summation of the measured components.

The disadvantages of this method are the low accuracy of measuring the vector of the intensity of an inhomogeneous electric field, low sensitivity, a narrow spatial range of measurement and an extended range of input signals of a device that implements this method.

Closest to the claimed method is a method of measuring electric field strength [Patent RU No. 2214611, MKI G01R 29/12, G01R 29/08], which consists in the fact that n-pairs of conductive sensitive elements included in a common sensor are simultaneously placed in the test space symmetrizing the outer surfaces of the sensor relative to the coordinate planes with the location of the centers of the surfaces of the sensitive elements in pairs on the n axes of the selected coordinate system symmetrically with respect to its beginning, while the sensor is oriented and m is maintained so that the electric field vector was equidistant from the axes of the coordinate sensor, i.e., so that its components along the coordinate axes are equal, and the configuration and size of the sensitive elements are selected from the condition of a minimum error from the inhomogeneity of the electric field at the maximum spatial range of measurement, while the modulus of the vector of the intensity of the measured electric field is determined by measuring one of the sensor components.

The disadvantage of this method is the low sensitivity, since one of the components of the sensor is measured, and the spatial range of the measurement is not wide enough.

Thus, the common disadvantages of the known analogues and prototype are low accuracy and sensitivity, as well as the fact that they can be used to measure the electric field in a narrow spatial range, i.e. at a distance from field sources and conductive surfaces, significantly exceeding the size of the sensor. In this region, the electric field can be considered homogeneous. When the sensor approaches the field source or conductive surfaces, the electric field becomes inhomogeneous, which leads to significant measurement errors.

The objective of the invention is the implementation of the ability to measure the vector of the electric field in a wide spatial range with increased sensitivity and accuracy.

The problem is achieved in that in the known method of measuring the electric field strength, based on placing at the same time n pairs of conductive sensitive elements included in a common sensor, balancing the outer surfaces of the sensor relative to the coordinate planes with the location of the centers of the surfaces of the sensitive elements in pairs on n axes of the selected coordinate systems symmetrically with respect to its origin, while the sensor is oriented and then supported so that the vector electric field strength was equidistant from the coordinate axes of the sensor, i.e. so that its components along the coordinate axes are equal, and the configuration and size of the sensitive elements are selected from the condition of a minimum error from the inhomogeneity of the electric field at the maximum spatial range, while the modulus of the vector of the measured electric field intensity is determined by measuring the components of the sensor, according to the claimed invention, the sensor is three-coordinate, t .e. n = 3, and it is oriented in space so that one of the components of the tension vector along one of the coordinate axes of the sensor becomes zero, then, fixing the sensor in this position, turn the sensor around the found coordinate axis until two other components of the electric tension vector are equal field along the coordinate axes of the sensor, while the modulus of the intensity vector of the measured electric field is determined by measuring the algebraic sum of two non-zero components of the vector of the electric field on the coordinate axes of the sensor.

The proposed method is illustrated in the drawing. Sensitive elements 1-6 are the outer surfaces of the spherical segments symmetrical with respect to the planes of the Cartesian coordinate system, for example, in three ordinates of the body 7, which in a particular case is a sphere, a sphere. The centers 8-13 of these surfaces are arranged in pairs on the axes of the same coordinate system symmetrically with respect to its origin 14. Sensitive elements, in the particular case representing spherical (spherical) segments, layers, triangles, squares and their combinations, are connected in the particular case through resistors, and in the General case, through the differential transducers 15-17 and the adder 18 with the measuring device 19, and the outputs of the differential transducers 15-17 are connected through a signaling device 20 with sound, light or other signaling devices 21- 23, revealing that the components of the tension vector are equal to zero along the coordinate axes of the sensor — along the X axis — 21, along the Y axis — 22, and the Z axis — 23.

The measurement method is implemented as follows. A sensor with sensitive elements is placed in the space of the investigated field and orient it in it until the sound, light or other signal generated by one of the signaling devices. At this moment, one of the components of the sensor becomes equal to zero, and the vector of the electric field strength falls into the plane of the other two coordinate axes of the sensor. Fixing the sensor in this position, they begin to turn it around the coordinate axis of the sensor with a zero component until the maximum reading of the device is obtained. The maximum reading of the device will come when the tension vector is equidistant from the two coordinate axes of the sensor, and its components along these coordinate axes become equal. Thus, when the sensor is oriented, it is necessary that the vector of the electric field strength fall into the plane of any two coordinate axes. Holding the sensor in the position corresponding to the maximum reading of the device, the algebraic sum of the components of the electric field vector is measured along two coordinate axes, by which its module is determined.

The configuration and size of the sensitive elements is selected from the condition of a minimum error from the inhomogeneity of the electric field with a maximum spatial range of measurement

where n = 3; E _i are the components of the vector of electric field strength along the coordinate axes, depending on the configuration and size of the sensitive elements, as well as on the spatial range of measurements; E ₀ - the module of the vector of the intensity of a uniform electric field.

Using the proposed measurement method and with the correct selection of the configuration and size of the sensitive elements, it is possible to achieve a measurement error of less than 3% at distances from the field source and conductive surfaces greater than or equal to 1.1 · R, where R is the conditional radius of the sensor body. In addition, the device for processing sensor signals is simplified and its sensitivity is increased.

Claims (1)

A method of measuring the electric field strength, based on placing simultaneously in the test space n pairs of conductive sensitive elements included in a common sensor, balancing the outer surfaces of the sensor relative to the coordinate planes with the location of the centers of the surfaces of the sensitive elements in pairs on the n axes of the selected coordinate system symmetrically with respect to its beginning, the sensor is oriented and then supported so that the electric field vector is equidistant from sensor axis, i.e. so that its components along the coordinate axes are equal, and the configuration and size of the sensitive elements are selected from the condition of a minimum error from the inhomogeneity of the electric field at the maximum spatial range, while the modulus of the vector of the measured electric field strength is determined by measuring the components of the sensor, characterized in that the sensor is three-coordinate, those. n = 3, and it is oriented in space so that one of the components of the tension vector along one of the coordinate axes of the sensor becomes zero, then, fixing the sensor in this position, turn the sensor around the found coordinate axis until two other components of the electric tension vector are equal field along the coordinate axes of the sensor, while the modulus of the intensity vector of the measured electric field is determined by measuring the algebraic sum of two non-zero components of the vector of the electric field on the coordinate axes of the sensor.