RU96258U1 - AMMETER - Google Patents

Abstract

 An AC ammeter, comprising a current transformer, the primary winding of which serves as the input of the ammeter, a rectifier, a switch for measuring limits at the N-positions (where N is the number of limits for measuring the ammeter), a load resistor, a measuring device, characterized in that, in order to increase the measurement accuracy and increase in temperature stability, it is equipped with a voltage limiter, N-1 additional load resistors, the measuring device is made in the form of a DC voltmeter with N-inputs, the secondary winding and a current transformer is connected to the input of the rectifier, the output of which is connected to the input of the switch, the outputs of the switch are connected to the corresponding load resistors and to the corresponding inputs of the DC voltmeter, a voltage limiter is connected to the output of the rectifier.

Description

This utility model relates to the field of electrical engineering, in particular, to alternating current ammeters based on the conversion of the measured alternating current into direct current using a rectifier and its subsequent measurement by a direct current device.

Ammeters of the rectifier system are known, containing a current transformer, the primary winding of which serves as the input of the ammeter, and the ammeter (milliammeter) of the electromagnetic system is included in the secondary winding, see, for example, Aluker S.M., Electrical meters, M. Higher School, 1976, p. 115-116, Fig. 77.

The advantages of such ammeters are that they allow the measurement of large currents (tens and hundreds of kiloamperes), and the disadvantages are the non-linear scale, and also that the electromagnetic system devices have a dead zone in the initial section of the scale, i.e. such devices allow you to measure currents in the range from 20 to 100% of the scale.

To obtain a linear scale, rectifier system devices are used that contain a current transformer, the primary winding of which serves as the input of the ammeter, the secondary winding is loaded on the resistor. One diagonal of the rectifier bridge is connected to the resistor through additional resistance, and the ammeter (milliammeter) of the magnetoelectric system is included in the second diagonal of the bridge, see, for example, Shkurin G.P., Handbook of New Electrical Measuring Instruments, M. Military Publishing House of the Ministry of Defense of the USSR, 1964, p. 305-306, fig. 381.

Such ammeters allow measuring large currents and do not have a dead zone in the initial section of the scale.

The disadvantages of these devices are that they have an error of the order of 2.5-4%, which is explained by the nonlinearity and temperature instability of the characteristics of the semiconductor diodes used in rectifier bridges.

To reduce the temperature error, temperature-dependent elements are used, connected either in series with the rectifier bridge, or parallel to the bridge, or in series with a measuring device (microammeter) resistance with a negative temperature coefficient (Taranyuk V.A., Portable multi-limit combined devices. M., "Energy ", 1970, pp. 25-27, Fig. 16).

Known methods of compensating for the temperature error of such schemes reduce it to a level of the order of 1.5-2.0% by 10 ° C, which is not always acceptable.

Closest to the claimed one is an ammeter containing a current transformer with several primary windings (according to the number of measurement limits), a load resistor connected in parallel with the secondary winding of the current transformer, a rectifier, the input of which is connected to the load resistor through the limit switch and an additional resistance, and to the output rectifier connected ammeter (milliammeter) of the magnetoelectric system - see Shkurin G.P., Handbook of electrical and radio measuring devices , M., Military Publishing House of the Ministry of Defense of the USSR, 1956, p. 310-312, Fig. 221.

The advantages of the prototype are that it does not have a dead zone in the initial section of the scale, and it is also possible to expand the dynamic range of the measured currents by switching the limits of measurement.

The disadvantages of the prototype are insufficient measurement accuracy and low temperature stability. These shortcomings are explained by the fact that in the prototype the current of the secondary winding of the current transformer is converted to voltage (using a resistor connected to the secondary winding of the transformer), and then the resulting voltage is measured by a rectifier millivoltmeter (additional resistance, a rectifier and a milliammeter of the magnetoelectric system form a rectifier millivoltmeter). In this mode of operation, the measurement error depends on the nonlinearity of the current-voltage characteristics of the semiconductor rectifier diodes, and the temperature error depends on the temperature instability of the current-voltage characteristics of the semiconductor rectifier diodes.

The purpose of this technical solution is to increase the accuracy of measuring the ammeter, as well as reducing its temperature error.

This goal is achieved in that the ammeter of the alternating current transformer, the input of which serves as the input of the ammeter, a rectifier, a switch of measurement limits at the N-positions (where N is the number of measurement limits of the ammeter), a load resistor and a measuring device, is additionally equipped with a voltage limiter and N -1 additional load resistors.

In the proposed ammeter, the measuring device is made in the form of a DC voltmeter with N-inputs. The secondary winding of the current transformer is connected to the input of the rectifier, the output of which is connected to the input of the switch, the outputs of the switch are connected to the corresponding load resistors and to the corresponding inputs of the DC voltmeter, and a voltage limiter is connected to the output of the rectifier.

The proposed embodiment of the ammeter makes it possible to increase the accuracy of measuring alternating current by connecting the rectifier directly to the secondary winding of the current transformer, which ensures the operation of the semiconductor diodes of the rectifier in the set current mode, which increases the linearity of the characteristics of the ammeter and increases its temperature stability.

The use of a direct current voltmeter as a measuring device (instead of an alternating current voltmeter in the prototype) also increases the accuracy of the ammeter, since direct current voltmeters are always more accurate in comparison with a direct current milliammeter with a rectifier at the input.

The introduction of a voltage limiter connected to the output of the rectifier ensures the ammeter’s operability, since the limiter protects the rectifier semiconductor diodes, as well as the current transformer, from damage in the event of voltage and current surges in various transient modes of operation, in particular, when the switch is switched from one position to another.

Figure 1 shows an example implementation of the proposed ammeter with two measurement limits.

The ammeter contains (see Fig. 1) a current transformer 1, a rectifier 2, a voltage limiter 3, a switch 4 of the measurement limits, load resistors 5 and 6, a DC voltmeter 7.

The primary winding 8 of the current transformer 1 serves as the input of the ammeter (terminals 9 and 10), the secondary winding 11 of the current transformer 1 is connected to the input of the rectifier 2, the output of which is connected to the input of the switch 4. In addition, the output of the rectifier 2 is connected to the voltage limiter 3.

The outputs of switch 4 are connected respectively to load resistors 5 and 6 and to the inputs of voltmeter 7, i.e. the first output of the switch 4 is connected to the load resistor 5 and to the first input of the voltmeter 7, the second output of the switch 4 is connected to the load resistor bis the second input of the voltmeter 7 (in the general case, when performing an ammeter with N measurement limits - output N of the switch 4 is connected to the load resistor N and with the input N of the voltmeter 7).

The current transformer 1 is made in the form of a standard measuring current transformer, for example, in the form of a toroidal core, on which the primary winding 8 and the secondary winding 11 are wound.

Rectifier 2 is made according to one of the standard schemes on semiconductor diodes, for example, in the form of a bridge rectifier.

The voltage limiter 3 can be made in the form of series-connected semiconductor diodes connected in the forward direction with respect to the polarity of the output current of the rectifier 2. The number of diodes in the limiter 3 determines the value of the voltage limiting threshold at the output of rectifier 2 (and at the output of current transformer 1). The voltage limiter 3 can also be made in the form of a zener diode, turned on in the opposite direction relative to the polarity of the output signal of the rectifier 2.

In addition, the voltage limiter 3 can be made in the form of a varistor, the resistance of which changes sharply when the voltage exceeds a threshold value.

As a switch 4 of the measurement limits can be used a standard switch of the biscuit type or a standard switch key (push-button) type. In this case, the general contact of the switch serves as its input, and the contacts isolated from each other serve as its outputs. The number of switch positions 4 and the number of its output contacts is determined by the number of ammeter measurement limits. In the general case, the switch has N-positions and, accordingly, N-outputs, where N is the number of ammeter measurement limits

Load resistors 5 and 6 are standard resistors, for example, type C2-29. The number of load resistors is equal to the number of ammeter measurement limits and the number of output contacts of switch 4, i.e. in the general case, the number of load resistors is N.

The DC voltmeter 7 can be made in the form of a magnetoelectric type measuring device 12 (milliammeter, microammeter) of direct current and resistors 13, 14, one of the terminals of which are connected to the first input of the measuring device 12, and the second conclusions of these resistors serve as inputs of the voltmeter 7. Second the input of the measuring device 12 is connected to a common ammeter bus. In the general case, the number of inputs of the voltmeter 7 is N.

Voltmeter 7 can also be made in the form of a digital measuring device (millivoltmeter) of direct current integrating type, which according to the principle of action reacts to the average value of the measured signal.

Ammeter works as follows. The measured alternating current is supplied to terminals 9 and 10 of current transformer 1, i.e. on the primary winding of a current transformer. The current of the secondary winding of current transformer 1, reduced correspondingly to the transformation coefficient, is supplied to rectifier 2, from the output of rectifier 2 through switch 4, direct current passes to one of the resistors 5 or 6 (depending on the position of switch 4). The voltage drop across the resistor 5 (or 6) is applied to one of the inputs of the DC voltmeter 7. In order for the voltmeter 7 to correspond to the measured current, the ammeter is calibrated, which can be performed by changing the nominal resistances of the resistors 5, 6 and 13, 14.

The voltage limiter 3 in the steady state does not take part in the functioning of the ammeter, for which the limit threshold is selected higher than the voltage at the output of the rectifier 2 at the maximum value of the measured current. This is done either by choosing the number of diodes in the limiter 3 (when making the limiter in the form of diodes connected in series), by choosing the breakdown voltage of the zener diode (in the case of making the limiter in the form of a semiconductor zener diode), or by choosing the corresponding varistor, the rated voltage of which is higher than the voltage the output of the rectifier 2 (in the case of a limiter in the form of a varistor).

When the switch 4 is switched from one position to another, a short circuit break occurs between the output of the rectifier and one of the resistors 5 or 6. At the moment of a circuit break in the secondary winding 11 of the current transformer, a short voltage surge can occur, and a voltage limiter is triggered, through which current begins to flow.

Therefore, the amplitude of the surge does not exceed the threshold of the voltage limiter 3. This protects the current transformer and rectifier from unwanted overvoltage in transient conditions.

The proposed embodiment of the ammeter makes it possible to increase the accuracy of measuring alternating current by connecting the rectifier directly to the secondary winding of the current transformer, which ensures the operation of the semiconductor diodes of the rectifier in the set current mode, which increases the linearity of the ammeter characteristics.

The use of a DC voltmeter as a measuring device (instead of an alternating current voltmeter in the prototype) also increases the accuracy of the ammeter, since DC voltmeters are always more accurate compared to a DC microammeter with an input rectifier.

The operation of the rectifier in the set current mode, as well as the use of a measuring device in the form of a DC voltmeter, reduces the temperature error of the proposed ammeter.

The introduction of a voltage limiter connected to the output of the rectifier ensures the ammeter’s operability, since the limiter protects the rectifier semiconductor diodes, as well as the current transformer, from damage in the event of voltage and current surges in various transient modes of operation, in particular, when the switch is switched from one position to another.

An additional advantage of the proposed ammeter is also that in it the current transformer has only one primary winding, i.e. one input, therefore, when switching from one measurement limit to another, there is no need to switch in the measured current circuit. This is especially important when measuring currents in high voltage circuits, as well as when measuring high currents (of the order of hundreds and thousands of amperes). In the prototype, the number of primary windings is equal to the number of measurement limits, therefore, when switching from one measurement limit to another, it is necessary to disconnect the measured current source, then switch to the primary winding circuit, after which it is necessary to turn on the current source and measure.

Known ammeters of the rectifier system provide a measurement error of the order of 1.5%, the temperature error of such devices is 1.5% / 10 ° C.

The ammeter implemented according to the proposed scheme has a measurement error of less than 0.1%, a temperature error of less than 0.1% / 10 ° C.

Claims (1)

An AC ammeter, comprising a current transformer, the primary winding of which serves as the input of the ammeter, a rectifier, a switch for measuring limits at the N-positions (where N is the number of limits for measuring the ammeter), a load resistor, a measuring device, characterized in that, in order to increase the measurement accuracy and increase in temperature stability, it is equipped with a voltage limiter, N-1 additional load resistors, the measuring device is made in the form of a DC voltmeter with N-inputs, the secondary winding and a current transformer is connected to the input of the rectifier, the output of which is connected to the input of the switch, the outputs of the switch are connected to the corresponding load resistors and to the corresponding inputs of the DC voltmeter, a voltage limiter is connected to the output of the rectifier.