RU2799666C1 - Method for measuring the electric field strength by one component - Google Patents

Abstract

FIELD: measuring technology.

SUBSTANCE: invention can be used to measure the modulus of the electric field strength vector with increased accuracy in a wide spatial measurement range with a simple measurement process. Several pairs of conductive sensing elements included in a common sensor are simultaneously placed in the space under study, with symmetrical outer surfaces of the sensor relative to the coordinate planes with the centres of the surfaces of the sensing elements located in pairs on the axes of the selected coordinate system symmetrically relative to its origin, while the sensor is oriented in the field to achieve the maximum values of the electric field strength and hold in this position, and the sensor is made with one pair of sensitive elements in the form of spherical segments with the optimal angular size θ₀ =56.6°, while the sensitive elements are independent sensors, by which two values of the electric field strength E₁ and E₂ are simultaneously determined, and the average value is found from them, and then, when the sensor is oriented in the electric field, they achieve the maximum average value, measuring which, they find the module of the electric field strength vector E.

EFFECT: reducing the measurement error, increasing measurement sensitivity and simplifying the measurement process.

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Description

The invention relates to the field of measuring technology and can be used to measure the modulus of the electric field strength vector with increased accuracy in a wide spatial measurement range with a simple measurement process.

A known method for measuring the electric field strength (patent US 3586973), based on the placement in the investigated space of a hollow conductive sphere formed by two hemispheres separated by a dielectric flange, so that the flanged hemispheres are isolated from each other. The dielectric flange forms a narrow insulating gap along the equator of the sphere. The sphere is suspended in an electric field on a dielectric thread so that the plane passing through the equatorially located insulating gasket is perpendicular to the electric field propagation vector. This causes a current to flow through the insulating pad proportional to the strength of the electric field.

The advantage of the method for measuring the electric field strength is that the device for its implementation has a wide range of input signals, and the method is easy to perform the measurement process. In addition, the method has the highest possible sensitivity, because. it uses a sensor with sensitive elements in the form of hemispheres with an angular size θ ₀ =90°, having a maximum surface area. The angular size is determined between two straight lines lying in the same plane and emerging from the center of the sphere and passing one through the center of the sensitive element, and the other through its edge.

The disadvantage of this method is the use of a sensor with sensitive elements in the form of hemispheres with an angular size θ ₀ =90°. Such a size of the sensitive elements leads to a significant negative error from the field inhomogeneity. In a wide spatial measurement range 0 ≤ a ≤ ∞ (a=R/d; R is the radius of the sphere; d is the distance from the center of the sphere to the field source), this error can reach -34%. When the error is limited, for example, to -5%, the spatial measurement range is limited to approximately the range a=0.3, which does not allow measurements near the field source with a small error. A sensor with a negative error underestimates the value of the electric field strength.

Closest to the claimed method is a method for measuring the electric field strength (patent for invention RU 2231802), which is based on placing three pairs of conductive sensitive elements included in a common sensor into the test space at the same time, symmetrizing the outer surfaces of the sensor relative to the coordinate planes with the location of the centers of the sensitive surfaces elements in pairs on three axes of the selected coordinate system symmetrically with respect to its origin, while the sensor is oriented in the field so that one of the components of the electric field strength vector reaches the maximum value that occurs at the moment the direction of the strength vector coincides with one of the coordinate axes of the sensor, then the sensor is held in this position and measure the module of the tension vector along this coordinate axis.

The advantage of the method is the use of a three-coordinate sensor when measuring the electric field strength, which makes it possible to simultaneously determine the three components of the electric field strength vector.

The disadvantage of this method is the determination of the electric field strength by measuring one of the maximum of the three values of the components of the electric field strength vector along the three coordinate axes of the sensor. The measurement process consists in the orientation of the sensor in space and the reduction of its two components to zero. In this case, the sensor has a redundancy in the number of coordinates, and the method itself is a complicated measurement process. The presence of a sensor with three pairs of sensing elements in the form of spherical segments limits their angular dimensions to θ ₀ =45°, with a larger angular size, the sensing elements are superimposed on each other. A sensor with sensitive elements in the form of spherical segments and angular dimensions θ ₀ ≤45° in an inhomogeneous field has a positive error, the limiting value of which in a wide spatial range 0 ≤ a ≤ ∞ reaches +34% and low sensitivity. When the error decreases, for example, to +5%, the spatial measurement range is limited to approximately the range a=0.25, which does not allow measurements near the field source with a small error. A sensor with a positive error overestimates the value of the electric field strength.

The objective of the invention is to simplify the measurement process, increase its sensitivity and accuracy in a wide spatial measurement range.

The solution of this problem is achieved by the fact that in the known method of measuring the electric field strength, based on placing several pairs of conductive sensitive elements included in a common sensor in the space under study, symmetrizing the outer surfaces of the sensor relative to the coordinate planes with the centers of the surfaces of the sensitive elements located in pairs on the axes of the selected coordinate system is symmetrical with respect to its origin, while the sensor is oriented in the field to achieve the maximum value of the electric field strength and held in this position, according to the claimed invention, the sensor is made with one pair of sensitive elements in the form of spherical segments with the optimal angular size θ ₀ =56.6° , while the sensitive elements are independent sensors, by which two values of the electric field strength E ₁ and E ₂ are simultaneously determined, and the average value is found from them, and then, when the sensor is oriented in the electric field, they achieve the maximum average value, measuring which, they find electric field strength vector E.

The proposed method is illustrated in figures 1-2, where in Fig. 1 shows the implementation of the method, and Fig. 2 - graphs of errors from the inhomogeneity of the electric field for the proposed method, and methods of the prototype and analogue, depending on the spatial measurement range.

The proposed method is based on a double spherical single-coordinate sensor, consisting of a conductive spherical base 1 and two conductive, isolated from each other and a spherical base 1 sensitive elements 2 and 3 in the form of a spherical segment, located diametrically opposite on the same coordinate axis passing through the center of the spherical grounds. The sensing elements 2 and 3 together with the spherical base 1 form two independent and oppositely directed electric field strength sensors. The sensing elements 2 and 3 through measuring transducers 4 and 5, which are, for example, charge amplifiers and an average value adder 6, are connected to a measuring device 7 calibrated in units of electric field strength.

The measurement method is implemented as follows. The sensor with sensitive elements is placed in the space of the field under study. At the same time, on the sensitive elements 2 and 3 of the sensor, electric charges q ₂ and q ₃ of opposite sign are induced, proportional to the strengths E ₁ and E ₂ of the electric field

– чувствительность датчика по чувствительным элементам 2 и 3. Where

– sensor sensitivity by sensitive elements 2 and 3.

The measured values of E ₁ and E ₂ determine the average value of the tension

where in expressions (1) - (3) k is the conversion coefficient determined by the parameters of the charge amplifier;

-

– суммарная погрешность датчика в неоднородном поле. Суммарная погрешность датчика определяется по известному выражению для расчета погрешности от неоднородности поля датчиков сферической формы [Бирюков С.В. Расчет и измерение напряженности электрического поля в электроустановках сверх- и ультравысокого напряжения /С.В. Бирюков, Ф.Г. Кайданов, Р.А. Кац, Е.С. Колечинский, В.Я. Ложников, Н.С. Смекалова, М.Д. Столяров //Влияние электроустановок высокого напряжения на окружающую среду: Переводы докладов Международной конференции по большим электрическим системам (СИГРЭ-86) (Энергетика за рубежом) / Под ред. Ю.П. Шкарина. – М.: Энергоатомиздат, 1988. – С. 6-13]– sensitivity of the proposed method; R is the radius of the spherical base of the sensor; θ ₀ is the angular size of the sensitive element in the form of a spherical segment; α is the angle between the direction of the electric field vector and the coordinate axis of the sensor; δ ₂ and δ ₃ – sensor errors due to field inhomogeneity for sensitive elements 2 and 3;

-

is the total error of the sensor in an inhomogeneous field. The total error of the sensor is determined by the well-known expression for calculating the error from the inhomogeneity of the field of sensors of a spherical shape [Biryukov S.V. Calculation and measurement of the electric field strength in electrical installations of super- and ultra-high voltage / S.V. Biryukov, F.G. Kaidanov, R.A. Katz, E.S. Kolechinsky, V.Ya. Lozhnikov, N.S. Smekalova, M.D. Stolyarov // The impact of high voltage electrical installations on the environment: Translations of the reports of the International Conference on Large Electrical Systems (SIGRE-86) (Energy abroad) / Ed. Yu.P. Shkarina. - M.: Energoatomizdat, 1988. - S. 6-13]

и

т.к. погрешности δ₂ и δ₃ имеют противоположные знаки;a=R/d is the spatial measurement range (where R is the radius of the spherical base of the sensor, d is the distance from the center of the spherical base of the sensor to the field source); θ ₀ - the angular size of the sensitive elements 2 and 3 of the sensor in the proposed method. For the error δ, the conditions

And

because errors δ ₂ and δ ₃ have opposite signs;

The sensor is oriented in the field until, in expression (3), the equality cosα=1 is reached, under this condition, the average value of the electric field strength will be maximum

Holding the sensor in this position, measure the modulus of the electric field strength vector. The angular size of the sensitive elements θ ₀ made in the form of a spherical segment is selected based on the required error and the spatial measurement range.

When using the proposed method, the measurement error of inhomogeneous electric fields is reduced, the measurement sensitivity is increased and the measurement process is simplified.

Reducing the measurement error by the claimed method is carried out due to, firstly, finding the average value of the tension from the two measured, secondly, different-sign errors δ ₂ and δ ₃ included in the total error δ of the proposed method, and, thirdly, by choosing the optimal value the angular size of the sensitive elements of the sensor θ ₀ in terms of the minimum error δ, determined by expression (5) and the maximum spatial measurement range a.

,Using expression (5), we construct and compare the error graphs for the analog method, the prototype method and the proposed method, depending on the spatial measurement range a=R/d. The error curves are shown in Fig. 2, from which it follows that for the proposed method, the sensor of which has sensitive elements with an optimal angular size θ ₀ =56.6°, the measurement error is δ=±4.3% in the spatial range 0≤a≤1. For the methods of analogue and prototype used in the same spatial range (0≤a≤1), the angular dimensions of the sensitive elements θ ₀ and the error δ, respectively, are θ ₀ =90°and δ < -34% (similar), θ ₀ =45 ° and δ < +34% (prototype). If for analog and prototype limit the error values equal to the error of the proposed method, i.e. -4.3% and +4.3%, respectively, then their spatial range will significantly decrease and will be 0≤а≤0.28. These graphs confirm a significant decrease in the error in the same spatial measurement range for the proposed method in relation to the method of analogue and prototype. In this regard, the proposed method has advantages over the methods of analogue and prototype, allowing, with the simplicity of the measurement process, to significantly reduce the error from the inhomogeneity of the electric field and expand the spatial measurement range. The increase in the sensitivity of the proposed method can be estimated through the coefficient

,

- чувствительность способа прототипа (см. выражение (4)) для θ₀=45°. Коэффициент увеличения чувствительности заявляемого способа по отношению к способам прототипа и аналога where G ₁ is the sensitivity of the proposed method (see expression (4)) for θ ₀ =56.6°, and

- sensitivity of the prototype method (see expression (4)) for θ ₀ =45°. The coefficient of increase in the sensitivity of the proposed method in relation to the methods of the prototype and analogue

- in relation to the prototype method

.

.

The coefficient k shows the increase in the sensitivity of the proposed method in relation to the methods of the prototype.

Simplification of the measurement process, when applying the proposed method, is carried out using a single-coordinate sensor in the measurement process. The use of such a sensor allows, by its orientation, to quickly find the maximum value of the module of the electric field strength vector E=E _max . This made it possible to eliminate the complex method of finding the maximum component of the electric field strength vector in the prototype method by excluding from the measurement process the finding of two other sensor components equal to zero by sound, light or other signals indicating the deviation of the electric field strength vector from the coordinate axes of the sensor.

Thus, the inventive method for measuring the electric field strength by one component can significantly reduce the sensor error due to field inhomogeneity, increase its sensitivity and simplify the measurement process.

Claims (1)

A method for measuring the electric field strength by one component, based on placing several pairs of conductive sensing elements included in a common sensor into the test space at the same time, symmetrizing the outer surfaces of the sensor relative to coordinate planes with the location of the centers of the surfaces of the sensing elements in pairs on the axes of the selected coordinate system symmetrically relative to its origin , while the sensor is oriented in the field to achieve the maximum value of the electric field strength and held in this position, characterized in that the sensor is made with one pair of sensing elements in the form of spherical segments with the optimal angular size θ ₀ =56.6°, while the sensing elements are independent sensors, which simultaneously determine two values of the electric field strength E ₁ and E ₂ , and find the average value from them, and then, when the sensor is oriented in the electric field, they achieve the maximum average value, by measuring which, they find the module of the electric field strength vector E .

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