RU2804916C1 - Two-coordinate cylindrical sensor of components of electric field intensity vector - Google Patents

Abstract

FIELD: measuring technology.

SUBSTANCE: invention relates to the field of measuring technology and can be used to measure the components of the intensity vector of radial electric fields in a wide spatial range with a small error. A two-coordinate cylindrical sensor of the components of the electric field strength vector contains a conductive cylindrical base, on the surface of which, isolated from each other and from the cylindrical base, conductive sensing elements are arranged in pairs on two coordinate axes, each of which passes through the centers of opposite pairs of sensing elements. On the surface of the cylinder are placed eight sensitive electrodes, from which two pairs of sensitive elements are formed, and each sensitive element consists of three sensitive electrodes, one of which is central with an angular size of θ₁ = 30° and two lateral with angular dimensions of θ₂= 15°, which are common to sensitive elements located on a different coordinate axis, while each the formed sensing element has an angular size of θ₀=60°.

EFFECT: technical result is a reduction in the measurement error and an expansion of the spatial measurement range to a≤0.5 (d≥2R) compared to known sensors.

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Description

The invention relates to the field of measurement technology and can be used to measure the components of the intensity vector of radial electric fields in a wide spatial range with a small error.

A known electromagnetic field sensor [USSR Author's Certificate No. 574683, MKI G 01 R 29/08. Electromagnetic field sensor /E.G. Gorbunova, V.A. Sikarev, V.I. Solovarov. - No. 2097768/09; Declared 01/14/75; Publ. 09/30/77, Bulletin. No. 36], containing two semi-cylindrical sensitive elements covering a housing made of conductive material, while the sensitive elements and the sensor housing are isolated from each other.

The advantage of the sensor is that it is double, since on the coordinate axis of the sensor there is a diametrically opposite pair of sensitive elements in the form of semi-cylinders - cylindrical rectangles. The magnitude of the electric field strength vector is judged by the charge difference between a diametrically opposite pair of sensitive elements. Using the sensor in differential connection leads to increased measurement accuracy by reducing common-mode components, i.e. external electrical interference. Another advantage of the sensor is that the sensitive elements of the sensor are half-cylinders with the maximum possible angular size θ ₀ = 90°, where the angle θ ₀ lies in the plane of the base of the cylinder and is enclosed between two straight lines passing through the center and edge of the sensitive element (electrode). Making the sensitive element with an angular size equal to θ ₀ = 90° ensures the maximum possible sensitivity of the sensor.

The disadvantages of the sensor include the fact that it can simultaneously measure only one component of the electromagnetic field strength vector and, therefore, belongs to single-axis sensors. As a result, the sensor requires orientation in the electromagnetic field until the maximum component of the field strength vector is obtained, i.e. its module. In addition, the sensitive elements of the sensor have the shape of half-cylinders with an angular size equal to θ ₀ = 90°. A sensor with such angular dimensions of sensitive elements in a non-uniform field has a negative error reaching ≈-22% in the spatial measurement range 0≤ a ≤1, where a = R/d ( R is the radius of the cylindrical base of the sensor; d is the distance from the axis of the cylindrical base to the field source). As a result, the electric field strength will be underestimated. In this regard, the sensor does not provide high accuracy in measuring the electromagnetic field strength in a wide spatial measurement range.

The closest device to the claimed one is a two-coordinate cylindrical electric field strength sensor [Klimashevsky I.P., Kondratyev B.L., Poletaev V.A., Yurkevich V.M. Electric field strength vector meter for high-voltage equipment //Measuring equipment. – 1983. - No. 1. – P.48-49], containing a metal cylinder, cut by mutually perpendicular planes YOZ and XOZ passing through the axis of symmetry of the cylinder. The resulting four parts of the cylinder represent sensitive elements of the sensor, located on two coordinate axes, each of which passes through the centers of opposite pairs of sensitive elements. Electric charges are induced on each pair of diametrically opposed sensitive elements, the differences of which are proportional to the corresponding components of the electric field strength vector E _x and E _y .

The advantage of the electric field strength sensor is that it is double and two-coordinate, consisting of two pairs of diametrically opposed sensitive elements. This makes it possible to obtain two components of the electric field strength vector and determine its modulus from them.

The disadvantages of the electric field strength sensor include low sensitivity due to the design of the sensor's sensitive elements with angular dimensions θ ₀ = 45°. A sensor with such angular dimensions of sensitive elements in a non-uniform field has a positive error reaching ≈+12% in the same spatial measurement range 0≤ a ≤1 as for the analogue sensor. As a result, the electric field strength will be overestimated. This angular size of the sensitive elements, as well as in the analogue, does not allow the sensor to provide high accuracy in measuring the electromagnetic field strength in a wide spatial measurement range.

A common disadvantage of the known sensors is low accuracy when measuring non-uniform electric fields and a limited spatial measurement range to the field source - several linear dimensions of the sensor.

The objective of the invention is to reduce the error in measuring the intensity of non-uniform radial electric fields and expand the spatial range of measurement.

The task is achieved by the fact that in a known sensor for measuring electric field strength, containing a conductive cylindrical base, on the surface of which conductive sensitive elements are located in pairs on two coordinate axes, each of which passes through the centers of opposite pairs of sensitive elements. , according to the claimed technical solution, to improve the measurement accuracy, eight sensitive electrodes are placed on the surface of the cylinder, from which two pairs of sensitive elements are formed, each sensitive element consisting of three sensitive electrodes, one of which is central with an angular size θ ₀ =30°, and two side ones with angular dimensions θ ₀ =15°, which are common to sensitive elements located on a different coordinate axis, with each formed sensitive element having an angular dimension θ ₀ =60°.

The present invention is illustrated by drawings, where Fig. 1, a, b shows an electric field strength sensor (general view of Fig. 1, a and end view of Fig. 1, b), and Fig. 2 shows graphs of the error from field inhomogeneity for sensors implemented by analogue, prototype and proposed sensor depending on the spatial measurement range a=R/d (where R is the radius of the cylindrical base 1 of the sensor, d is the distance from the axis of the cylindrical base 1 to the field source) and different values of the angular dimensions of the sensitive elements θ ₀ . The graph corresponding to the analogue is built for a sensor with the angular size of the sensitive element θ ₀ =90°, the graph corresponding to the prototype is built for a sensor with the angular size of the sensitive element θ ₀ =45°, and graph 3 corresponds to the claimed sensor at θ ₀ =60°.

The sensor is based on a cylindrical conductive base 1 long l coated by sputtering with a thin layer of dielectric (Fig. 1). Eight conductive sensitive electrodes 2-9 are applied to the surface of the dielectric layer, made in the form of cylindrical rectangles symmetrically located on the cylindrical surface of the sensor base. From eight sensitive electrodes 2-9, two diametrically opposed pairs of sensitive elements are formed. Each sensitive element consists of three sensitive electrodes isolated from each other, one of which is central and two lateral. Diametrically opposite pairs of sensitive elements are located on the coordinate axes x and y . Along the x- axis there are two diametrically opposed sensitive elements, the first consists of electrodes 3, 2, 9, and the second of electrodes 5, 6, 7. Along the y -axis there are two diametrically opposed sensitive elements, the first consists of electrodes 7, 8, 9, and the second of the electrodes 3, 4, 5. The central sensitive electrodes 2, 4, 6 and 8 of each sensitive element are the main ones, and the side sensitive electrodes 3, 5, 7 and 9 are common to the adjacent sensitive elements. The central sensitive electrodes are made with an angular dimension θ ₁ =30°, and the side sensitive electrodes are made with an angular dimension θ ₂ =15°. The sensitive element, formed from a central sensitive electrode and two side ones, has an angular size of θ ₀ =60°.

Since the conductive parts of the sensor, such as the cylindrical conductive base 1, sensitive electrodes 2-9, are insulated with each other by a thin layer of dielectric 10 and have a small thickness due to sputtering, the entire structure of the sensor can be considered a continuous conductive cylindrical surface, and each conductive part of the sensor is electrically the field will have almost the same electric potential. In addition, to ensure equal potential for all parts of the sensor, its sensitive electrodes and elements must be connected to measuring devices with a low-impedance input. Current meters and current integrators (charge amplifiers) can be used as devices with a low-impedance input. Preference should be given to a current integrator, because its output voltage is independent of the field frequency and is proportional to the charges induced on the sensitive elements of the sensor. The conductive cylindrical base 1 can be the midpoint of the sensor for the measuring circuit.

The electric field strength sensor works as follows.

When a dual sensor is introduced into an electric field, electrical charges are induced on the conductive electrodes 2-9 of the sensor, the magnitude of which is proportional to the components of the measured electric field strengthE. By forming from electrodes 2-9 opposite pairs of groups of sensitive elements, consisting of three sensitive electrodes: along the axisx – 3, 2, 9 and 5, 6, 7; along the axisy – 7, 8, 9 and 3, 4, 5, separated by coordinate planesYOZ AndXOZ, measure the charge differencesΔQ _x AndΔQ _x between electrically connected (via measuring circuits) pairs of composite sensitive elements, proportional to the componentsE _x AndE _y electric field strength vector. Based on the measured components of the electric field, the modulus of the electric field strength is determinedE, How

, (1)

Where And ;

in a uniform field ; (2)

in a non-uniform field

(3)

The difference in electric charges (see expressions (2) and (3)) induced by uniform and inhomogeneous fields leads to sensor error caused by field inhomogeneity. Taking into account the error from field inhomogeneity, the modulus of the field strength vector (see expression (1)) can be written

,

Where (4)

– error from field inhomogeneity [Biryukov, S.V. Study of an electromagnetic field strength sensor of a cylindrical shape for directional reception // Bulletin of the Voronezh State Technical University. T. 19. No. 2. - 2023. – P. 111–118].

In expression (4) a=R/d is the spatial measurement range, R is the radius of the cylindrical base of the sensor, d is the distance from the axis of the cylindrical base of the sensor to the field source, θ ₀ is the angular size of the sensor’s sensitive element.

The reduction in error is confirmed by Fig. 2, where, as examples, graphs of the error from the inhomogeneity of the electric field are given depending on the spatial measurement range a = R/d for the analog δ ₁ , the prototype δ ₂ and the proposed device δ .

Graph δ ₁ corresponds to the analogue sensor at θ ₀ =90°, and graph δ ₂ corresponds to the prototype sensor at θ ₀ =45°, and graph δ corresponds to the claimed sensor at θ ₀ =60°.

From the graphs of Fig. 2 it follows that the proposed sensor allows not only to reduce the measurement error of non-uniform electric fields to 1% (see graph δ for the proposed sensor), but also to expand the spatial measurement range to a ≤0.5 ( d ≥2 R ). At that time, for the analogue and prototype with the same error, the spatial measurement ranges are the same and do not exceed a ≤0.18 ( d ≥ 5R ).

Thus, the use of the proposed sensor makes it possible to reduce the error to 1% when measuring the components of the intensity vector of inhomogeneous electric fields and expand the spatial measurement range to a ≤0.5 ( d ≥2 R ) in comparison with known sensors, which have the same spatial error the measuring range is a ≤0.18 ( d ≥ 5R ).

Claims (1)

An electric field strength sensor containing a conductive cylindrical base, on the surface of which, isolated from each other and from the cylindrical base, conductive sensing elements are located in pairs on two coordinate axes, each of which passes through the centers of opposite pairs of sensing elements, characterized in that in order to reduce the error by On the surface of the cylinder, eight sensitive electrodes are placed, from which two pairs of sensitive elements are formed, and each sensitive element consists of three sensitive electrodes, one of which is central with an angular size of θ ₁ = 30° and two side ones with angular dimensions of θ ₂ = 15°, which are common to sensitive elements located on a different coordinate axis, with each formed sensitive element having an angular size θ ₀ =60°.