RU2133039C1 - Electrical measurement instrument - Google Patents

Abstract

FIELD: electrical measurement technology, automatic system collecting information on magnitudes of measured quantities. SUBSTANCE: electrical measurement instrument includes case, measurement mechanism with casing and mobile part, pointer indicator, marked scale, capacitive pickup formed by pointer indicator and current-carrying electrodes deposited on scale. Assemblage of electrodes presents arc-shaped layer divided into parts by grooves. These elements are integrated in two electrodes each of them being connected to separate additional terminal. Grooves between electrodes are made for differential and monotone change of capacitances between pointer and each electrode. Output capacitances of pickup may be equal and bridge measurement circuit can be balanced with maximum deflection of pointer. Scale can have additional element of one of electrodes to provide for equality of areas of surfaces of electrodes located outside region effected by pointer. EFFECT: enhanced sensitivity, precision and noise immunity. 2 cl, 2 dwg

Description

 The invention relates to the field of electrical engineering and can be used in systems with automatic collection of information about the values of the measured values.

 Known electrical measuring instruments (see, for example, in the book. Analog electrical measuring instruments: Textbook for universities / Dmitriev FS, Kiseleva EA, Lebedev GP and others; Edited by A.A. Preobrazhensky. - M .: Higher school, 1979. - 352 pp.), Containing the case, a clip fixed in it, relative to which the moving part is mounted with an arrow pointer mounted on it, a scale with marks, numbers and designations affixed to it, attached to the clip of the device. When moving the moving part of the device, the arrow changes its position relative to the marks on the scale, presenting information about the input value for visual reading by a person.

 However, analogue electrical measuring devices of this type convert the measured value only to moving the pointer relative to the scale marks, which does not allow their use in systems with automated data collection, where it is necessary to present the measuring information in the form of an electrical signal.

 Known electrical measuring instruments with contact groups (see, for example, the Handbook of electrical measuring instruments; Edited by KK Ilyunin, L., "Energy", 1977, S. 382 - 387), containing, as the proposed device, case, measuring mechanism, consisting of a cage and a movable part installed in it, connected to the working terminals of the device, an arrow pointer mounted on the moving part of the device, a scale with marks, numbers and symbols on it, fixed on the cage. In addition, the known devices contain a contact group, which closes the additional electrical circuit of the device when the arrow reaches a certain position. This position is set depending on the type of known devices either during manufacture or by mechanical regulators in the device body.

 A disadvantage of the known devices is the low reliability of the contact group, an increase in the error of the readings at the moment of contact closure, a limited number of contact groups in the device (no more than two in known devices), which leads to a large discreteness in determining the position of the arrow on the scale of the device by closing the contact groups.

 Closest to the proposed is an electrical meter in a. with. USSR 1308018, class G 01 R 35/00 (DSP), containing, like the proposed device, a housing, a measuring mechanism consisting of a cage and a movable part installed in it, connected to the working terminals of the device, a pointer, mounted on the moving part of the device, electrically connected to a negative terminal of the device, a scale with marks, numbers and symbols on it, fixed on a clip and isolated from it, an integrated capacitive sensor formed by an arrow and a system of fixed electrodes from a conductive material applied to the scale la.

 The disadvantage of the prototype is the inability to determine the position of the arrow relative to the scale marks with an arbitrary nature of the change in the input signal of the device, due to the fact that the output parameter of the capacitive sensor has similar maximums when the arrow is above each radial layer of the capacitive sensor. The identification of the layer over which the arrow is currently located is possible only with a monotonic change in the input signal, when the arrow passes over the layers in series, which greatly narrows the scope of such devices.

 Switch electrical measuring instruments are used to measure a wide range of currents and voltages and present information in a form convenient for human reading. But for use in systems with automatic reading using electronic and microprocessor devices, such devices are not adapted. The functioning of various systems in industrial and economic facilities is controlled by groups of measuring devices with direction indicators, combined into information panels. The number of devices on the shields can reach several tens. The information provided by arrow pointers is read out visually by the operator, who must constantly be at the switchboard, monitoring the state of the system and taking necessary measures in emergency situations. Therefore, when solving problems arising during the operation of the system, errors are possible related to the subjective assessment of situations and the delayed response of the operator. All the additional features for emergency blocking of system elements, partial automation of control and management, storing and documenting the values of measured parameters are realized by introducing additional hardware into the system, often very complex. Therefore, for many tasks of managing objects in which the values measured by the instrument parameters are controlled, it is required to provide two types of representation of heterogeneous measurement information. Firstly, in the form of moving the device’s arrow relative to the digitized marks on the scale, convenient for visual reading by a human operator. Secondly, in the form of a voltage that varies depending on the value of the input quantity, which is convenient to use in automatic control systems either directly or after analog-to-digital conversion. The use of arrow electrical measuring devices for this purpose with a capacitive arrow position sensor will greatly simplify the structure of the created control and instrumentation systems, as well as modify existing systems with minimal hardware costs.

 EFFECT: obtaining an electrical measuring device with a multifunctional capacitive sensor of the position of the arrow, for which it is necessary to ensure the possibility of determining the location of the arrow relative to the scale marks at any time with an arbitrary input signal, as well as the highest possible sensitivity, accuracy and noise immunity of the sensor.

 An electrical measuring device comprises a housing, a measuring mechanism connected to the operating terminals of the device, consisting of a cage and a movable part installed in it, an arrow pointer mounted on the moving part of the device, electrically connected to the negative terminal of the device, a scale with marks, numbers and symbols on it fixed in a holder and isolated from it, a capacitive sensor formed by an arrow pointer and fixed electrodes of conductive material deposited on a scale.

 The ability to determine the position of the arrow relative to the scale marks is provided by the presence in the device of a capacitive sensor formed by a movable electrode - an arrow and a system of fixed electrodes applied to the scale and electrically isolated both from the scale and from the other structural elements of the device. The fixed electrode system is an arcuate layer with a center on the axis of rotation of the arrow, divided by at least one groove into several separate parts. These elements are electrically combined into two electrodes, with each of the electrodes connected to a separate additional terminal. The shape of the grooves between the elements of the electrodes determines the nature of the dependence of the output capacitances of the sensor on the angle of rotation of the arrow of the device.

 Due to the presence in the device of a capacitive sensor of the position of the arrow, in which the fixed electrode system on the scale has the form of an arcuate layer divided by at least one groove into two electrodes, the electric parameters between the arrow and the fixed electrodes additionally become the output parameters of the device. Moreover, when the shape of the grooves between the electrodes is such that the areas of overlap of the electrodes and the arrows when it moves in one direction change monotonously and differentially with respect to each other, the output capacitances of the electrodes will also change differentially and monotonously. This allows the use of bridge converters to convert the capacitance values taken from the terminals of the device, which greatly increases the sensitivity of the sensor. Since the output capacitance of the sensor with a turn of the arrow varies differently and monotonously, this allows you to uniquely match the angular position of the pointer of the device and the capacitance values at the sensor outputs. Therefore, knowing the dependence of the sensor output on the rotation angle of the arrow, it is possible to determine the location of the arrow on the scale of the device at any time from the sensor, and each and every angular position of the arrow will correspond to one and only one value on the capacitive outputs of the sensor.

 In the particular case of execution, the grooves between the elements of the stationary electrodes can be made so that with a maximum deviation of the arrow of the device, the output capacitances of the sensor will be equal to each other. If the bridge measuring circuit of the sensor is balanced at the maximum deflection of the arrow, then its output signal at this point of the scale will be invariant to a change in the supply voltage of the bridge, the gap between the arrow and the scale, and the angle of the arrow to the scale. The sensor errors from all these disturbances will have a multiplicative character and are taken into account using a correction factor, which is determined by the deviation of the sensor readings from the nominal value in the absence of the input signal of the measuring device. This increases the accuracy of determining the location of the arrow relative to the marks on the scale.

 In another particular case of execution with the help of additional elements of the stationary electrodes, which are located outside the area of the scale covered by the arrow, ensure that the surface areas of the electrodes are equal to each other. In this case, changes in output capacitances caused by external disturbances (for example, the movement of objects near the device) are equal to each other and mutually compensated in the bridge measurement circuit, which increases the noise immunity of the sensor.

 In FIG. 1 shows an example of a configuration of a system of fixed electrodes on the scale of an electrical measuring device with a capacitive sensor for the position of the arrow; in FIG. 2 - graphs of the output voltages of the arrow position sensor of the electrical measuring device for various gaps between the arrow and the scale d.

 An electrical measuring device comprises a housing, a measuring mechanism connected to the operating terminals of the device and consisting of a cage and a movable part installed in it, an arrow pointer mounted on the movable part of the device and electrically connected to the negative operating terminal of the device, scale 1 (Fig. 1) with the applied on it marks, numbers and designations, mounted in a holder and isolated from it, a capacitive sensor of the position of the arrow, formed by a pointer pointer and fixed electrodes made of current on the scale rovodyaschego material. The system of fixed electrodes is electrically isolated both from the scale and from the remaining structural elements of the device and is an arcuate layer with a center on the axis of rotation of the arrow, divided by at least one groove into separate parts, electrically combined into two electrodes, each of the two electrodes obtained (2 and 3) is connected to a separate auxiliary terminal.

 In a preferred embodiment, the elements of the stationary electrodes have such a shape that, with a maximum deviation of the arrow, the output capacitances of the sensor are equal to each other, and the bridge measuring circuit of the sensor at this point is balanced.

 In another embodiment, on the scale outside the area covered by the arrow, there is an additional element of one of the stationary electrodes 4, so that the surface areas of the electrodes are equal to each other.

 An electrical meter works as follows. Under the influence of the measured signal, the moving part of the device rotates, and the arrow changes its position relative to the marks on the scale 1 and the system of fixed electrodes 2 and 3. Moreover, the shape of the electrodes is such that when the arrow moves, the overlap area of the arrow and one of the electrodes (for example, 2) increases, like the corresponding output capacitance of the sensor, and the other electrode (3) - decreases with the corresponding capacitance. The shape of the grooves (one or more) between the electrodes determines the sensitivity of the sensor at each point of the output characteristic. The most universal is the shape of the groove, in which the dependence of the output capacities on the angle of rotation of the arrow of the device is directly proportional. When the condition of equality of capacitance between the arrow and the electrodes at the point of extreme deviation of the arrow is fulfilled, the procedure for taking into account additional sensor errors is simplified. If the bridge measuring circuit is balanced at the point of equal capacitance, then the location of this point on the output characteristic will not change from the supply voltage, the gap between the arrow and scale, etc. A change in the output characteristic from external influences will be mainly multiplicative in nature with a center at the equilibrium point of the circuit. This change can be taken into account by measuring the output signal of the sensor in the absence of an input and making a correction factor. An additional element of one of the stationary electrodes 4 serves to increase the noise immunity of the sensor to external influences.

 An electrical instrument with a built-in capacitive sensor for the position of the arrow was tested at the Department of Information and Communication Technologies of UlSTU in laboratory conditions. The ammeter M42100 of the magnetoelectric system was used as a base, the scale of which was made of foil fiberglass 1 mm thick. The arcuate layer had boundary radii (internal - external) 9 - 40 mm and was divided by a groove 1 mm wide into two electrodes so that the capacitive characteristics of the sensor were close to directly proportional. An arrow 2 mm wide, 40 mm long, mounted on the moving part of the device, was electrically connected to the standard negative terminal of the device. In the extreme right position, the arrows of the overlapping area of the electrodes were equal to it. When taking the characteristics of the sensor, we used: a programmable calibrator P320, a digital voltmeter V7-34A, and a low-frequency signal generator G3-109. A six-armed bridge of alternating current with a diode ring, balanced at the point of maximum deviation of the arrow, is used as a measuring circuit of the sensor. The scheme used is given in book. Levshina E.S., Novitsky P.V. Electrical Measurements of Physical Quantities: A Textbook for High Schools - L .: Energoatomizdat, 1983. The bridge was powered by an alternating voltage of 16V, 45 kHz. Graphs of the dependences of the output voltage of the sensor U on the angle of rotation of the arrow a for various values of the gap between the arrow and the scale of the device d are shown in FIG. 2.

 Testing confirmed the achievement of the technical result: the ability to determine the position of the arrow relative to the scale marks with an arbitrary nature of the change in the input signal of the electrical measuring device; increasing the sensitivity of the capacitive sensor of the position of the arrow of the device due to the use of bridge measuring circuits; the possibility of improving the accuracy and noise immunity of the sensor while ensuring the equality of output capacitances at the point of maximum deflection of the arrow and the areas of the stationary electrodes by placing an additional element on one of them on the scale.

Claims (3)

 1. An electrical measuring device comprising a housing, a measuring mechanism connected to the working terminals of the device and consisting of a cage and a movable part installed in it, an arrow pointer mounted on the movable part of the device and electrically connected to the negative working terminal of the device, a scale with marks on it , with numbers and designations, mounted in a holder and isolated from it, a capacitive sensor for the position of the arrow, formed by an arrow pointer and fixed electrodes made of current material, electrically isolated from the scale and from other elements of the device design, characterized in that the fixed electrode system is an arcuate with a center on the axis of rotation of the arrow layer, separated by at least one groove into separate parts, electrically combined into two electrodes, moreover, each of the two obtained electrodes is connected to a separate additional terminal.  2. The device according to claim 1, characterized in that the elements of the stationary electrodes have such a shape that, with a maximum deviation of the arrow, the output capacitances of the sensor are equal to each other, and the bridge measuring circuit of the sensor at this point is balanced.  3. The device according to claim 1, characterized in that on the scale outside the area covered by the arrow, there is an additional element of one of the stationary electrodes, so that the surface areas of the electrodes are equal to each other.

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