RU2564689C1 - Device for verification of inductive electric meters - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: device contains two circuits, each of which operates alternately respectively from positive and negative half waves of mains voltage. Each of these circuits contains the networks which are series connected to phase and zero conductors downstream the metering device, the avalanche diode and the storage capacitor. The point of connection of the named circuit elements is connected through the load resistor with the emitter - collector junction of the power transistor the other junction electrode of which is connected to the phase conductor of the network. Avalanche diodes of two circuits are connected to the phase conductor of the network by different electrodes - the cathode for the circuit operated from positive half-cycles of mains voltage, and the anode for the circuit operated from negative half-cycles of mains voltage, and power transistors of these circuits provide their conductivity of discharge current through the respective load resistors. Each of these power transistors is open for the respective half wave of mains voltage and reliably closed for another half wave of mains voltage, for this purpose the step-down transformer the primary winding of which is connected to phase and zero conductors of the network downstream the metering device is used, and its two separate secondary windings are connected to the operating electrodes of "base emitter" junction of power transistors through the limiting resistors.

EFFECT: device design simplification.

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Description

The invention relates to the field of electrical engineering and can be used to verify the correct operation of induction-type electric meters operating on an active load.

It is known that induction electric meters contain a multiplier of the instantaneous value of the active load current flowing through its low-resistance current winding to the instantaneous value of the mains voltage acting in the high-resistance winding, which is realized by the action of the corresponding magnetic fields on a rotating metal disk in which eddy currents are excited, and at the torque applied to the disk is proportional to the instantaneous value of the products of these mutually orthogonal magnetic fields, then e be the product of the instantaneous voltage of said winding current values at the harmonic law of change of current and voltage with a low power frequency (50 Hz) and the count of electricity is determined by integrating said current works to a voltage that is determined by the number of aluminum disk revolutions.

It is important to note that the correct operation of such counters occurs with the harmonic nature of the change in time of currents and voltages in the low-frequency spectrum. Violation of this condition, for example, by high-frequency fragmentation of the active load current and with the pulsed nature of the load current, the spectrum of which is significantly higher with respect to the harmonic oscillation of the network, for example, by an order of magnitude or more, leads to underestimation of the energy consumed by the load, up to only a part from really consumed energy.

This allows unscrupulous users to apply various schemes for the theft of electricity, and developers of induction electric meters need to improve the design of metering devices to counter such schemes, one of which is considered in the claimed technical solution.

There are various options for devices for winding off readings of electricity meters based on high-frequency crushing of the load current, which are the capacitance of storage capacitors with their subsequent smooth discharge in the opposite direction of the discharge current [1-8].

The disadvantage of such devices is their relatively high complexity, in particular, controlling the operation of power transistors and triac devices.

The aim of the invention is to simplify the design.

This goal is achieved in the inventive device for checking induction energy meters, containing two circuits, each of which operates alternately from the positive and negative half-waves of the mains voltage, characterized in that each of these circuits contains sequentially connected to the phase and zero conductors of the network after the meter avalanche diode and storage capacitor, the connection point of these circuit elements is connected through a load resistor to the emitter-collector transition of forces of the transistor, the other transition electrode of which is connected to the phase conductor of the network, the avalanche diodes of the two circuits are connected to the phase conductor of the network by different electrodes - the cathode for the circuit operating from positive half-periods of the mains voltage, and the anode for the circuit operating from negative half-periods of the mains voltage, and power the transistors of these circuits ensure their discharge current conductivity through the respective load resistors, each of these power transistors being open to the corresponding lunar waves of the mains voltage and securely closed to the other half-wave of the mains voltage, for which a step-down transformer is used, the primary winding of which is connected to the phase and zero conductors of the network after the meter, and its two separate secondary windings are connected to the control electrodes of the base-emitter junction of power transistors through the limiting resistors.

Achieving this goal is explained by the formation in each half-cycle of the mains voltage for the corresponding two circuits of short charging storage capacitors, the spectrum of which is two to three orders of magnitude higher than the frequency of the mains voltage, and by the smooth discharge of the storage capacitors back to the network through power transistors open in the corresponding half-periods, so that discharge currents and rms voltages have different signs, by virtue of which the counter is rewound.

The invention is clear from the presented in Fig. 1 scheme, which includes:

1 - single-phase induction electric meter without backstop,

2 - fuse,

3 - the first avalanche diode,

4 - the first storage capacitor, for example, electrolytic type,

5 - the first load resistor,

6 - the first power transistor, for example, n-p-n-type,

7 - step-down transformer with two separate secondary windings,

8 - the first limiting resistor in the base circuit of the first power transistor 6,

9 - the second storage capacitor, for example, electrolytic type,

10 - second avalanche diode,

11 is a second load resistor,

12 - the second power transistor, for example, n-p-n-type,

13 is a second limiting resistor.

In fig. Figure 2 shows a graph of one period of a sinusoidal alternating voltage, and in Fig. 3 is a graph of the current in the phase conductor after the meter.

Consider the action of the claimed device.

When this circuit is connected to the network, both storage capacitors 4 and 9 are quickly charged in the corresponding half-periods through avalanche diodes 3 and 10 and are relatively slowly discharged back into the network through load resistors 5 and 11 and alternately open power transistors 6 and 12 for the corresponding half-periods of the mains voltage, as can be seen from the graphs in fig. 2 and 3. It is important to note that the polarities of the charging currents and the voltages acting at the same time coincide, which creates a direct reading of the readings in the electric meter, and the polarities of the discharge currents and the voltages acting at the same time are different, which ensures a countdown (rewinding of the meter )

Let the storage capacitor 4 with a capacity of C be charged from the mains voltage through an avalanche diode 3 with a negligible internal resistance to a voltage U equal to the amplitude value of the alternating voltage equal to 310 V for a network with an operating voltage of 220 V. Moreover, in the second quarter of the first positive half-cycle through the resistor load 5 of magnitude R and an open power transistor 6 with a very small internal resistance of the transition "emitter-collector" flows current back to the network, determined by the difference in instantaneous values of the voltage across the storage capacitor and the alternating voltage of the network in the second quarter of the period, that is, equal to

where τ = RC is the time constant of the discharge circuit, t is the current time 0≤t≤T / 4.

In this case, the voltage across the storage capacitor slowly decreases exponentially, reaching the voltage value U ₁ by the end of the positive half-cycle.

Note that when the mandatory condition τ >> T / 4 is fulfilled, it can be assumed that the voltage between the values of U and U ₁ changes almost linearly in time.

The discharge energy of the storage capacitor 4 through the load resistor 5 in the second quarter of the period can be calculated taking into account (1) by the formula

So, if T = 0.02 s and τ = 0.5 s, then, according to (2), we have ΔW _PIT = 1.107 U ² / R (mJ) when integrated using the MathCad program. Note that the discharge energy indicated in (2) is spent on its conversion into thermal energy released in the load resistor 5.

After the discharge of the storage capacitor 4 by the amount of energy indicated in (2), the voltage on this capacitor decreases to a value of U ₁ equal to:

Moreover, in all other odd half-periods of the mains voltage, this situation persists. According to the law of energy conservation, we note that the charge energy of the storage capacitor 4 should be equal to the discharge energy specified in (2), assuming that the losses in the power line and in the metering device are negligible. Therefore, the charge energy ΔW _{ZAR is} calculated by the formula

For negative even half-periods, the same effects are repeated with the participation of elements 9, 10, 11, and 12. Therefore, the charge power Pzar of both storage capacitors 4 and 9 is found from the expression

and is spent on heating a pair of load resistors 5 and 11. In this case, meter 1 takes into account this energy, and its aluminum disk rotates in the right direction. However, due to the pulsed operation of the charge recharging mode of storage capacitors 4 and 9, accounting for the energy consumed is underestimated due to the high frequency of the spectrum of charging pulses, the duration of which is many times less than a quarter of the period T / 4 = 5 ms. This duration of the charging pulses Δt _UTI is found from the expression

where ΔW _EXIT is found from expression (2).

Consider an example. Let T = 0.02 s, τ = 0.5 s, U = 310 V, R = 96.1 Ohms. Moreover, 2 F ΔW _SIZE = 110.7 W is the heat loss in the load resistors 5 and 11. The value of the capacitance of the storage capacitors 4 and 9 is found from the expression С = τ / R = 0.5 / 96.1 = 0.005203 Ф≈ 5200 uF. Such a capacitor can be made of 16 parallel-connected electrolytic capacitors with a capacity of 330 μF with an operating voltage of at least 350 V, allowing operation in the frequency mode. The maximum energy of each of the charge storage capacitor 4 and 9 Cu ^2/2 = 249.86 J. Then from (6) we find the charging pulse duration Δt _IMP = 0,02 [0,25-0,1592arcsin (1-0,1107 / 249.86)] = 0.02 [0.25-0.1592arcsin0.999557] = 0.02 (0.25-0.1592 · 1.541) = 0.0000934 s = 93.4 μs. The spectrum of such a pulse is in the frequency range f _SP ≥1 / Δt _IMP = 10707 Hz, which is 10707/50 = 214 times higher than the frequency of the mains voltage. This circumstance leads to a reduced metering of electricity, for example, up to 75% of the actually consumed electricity circuit for the maximum spectral density of charging pulses at a frequency of about 10 kHz. That is, when the power consumption of this circuit is 110.7 W, the meter will take into account energy with an apparent power of only 0.75 · 110.7 = 83.02 watts.

Since in the second and fourth quarters of each period of the alternating current the discharge currents flow in the current winding of the counter 1 in the opposite direction than in the first and third quarters of the period, so that the product of these currents and the mains voltage in these quarters of the periods have DIFFERENT SIGNS, this further reduces readings of the electric meter, and the winding power P _OTM is found from the expression

Thus, instead of taking into account the power of 110.7 W, the device will take into account the power equal to 83.02-67.16 = 15.86 W, therefore, the power unaccounted for by the meter will be 110.7-15.86 = 94.84 W. Therefore, only 14.33% of the actually consumed electricity is taken into account by the electric meter.

The average value of the discharge current in the considered example is 0.36 A (maximum at the end of the half-cycle is 3.2 A). Therefore, the average value of the current of the avalanche diode is approximately T / 4 Δt _IMP = 50 times greater than the average value of the discharge current, that is, it is of the order of 18 A, and the maximum value of this current is of the order of 40 A, for which avalanche type diodes are used.

Note that useful load consumers of electricity, for example, heating appliances, can be used as load resistors 5 and 11. In this case, we are dealing with the theft of electricity.

Developers of induction metering devices without a backstop (as in CO-2M counters) should ensure that metering devices are insensitive to short (about 100 μs) charging pulses at a large time constant τ of the used RC circuit in such circuits as considered in this technical solution.

Literature

1. Smaller O.F. Device for checking the operation of single-phase induction electric meters. Patent No. 2474825, publ. in bull. No 4 on 02/10/2013.

2. Smaller O.F. Bridge device for checking electric meters of active energy of induction type. Patent No. 2522706, publ. in No. 20 of 07/20/2014.

3. Smaller O.F. A method of compensating for losses at the end of a long power line. Patent No. 2512706, publ. No. 10 dated 04/10/2014.

4. Smaller O.F. The device volt-additive power supply. Patent No. 2517203, publ. No. 15 dated 05/27/2014.

5. Smaller O.F. Device for monitoring electricity meters. Patent No. 2521782, publ. No. 19 dated 07/10/2014.

6. Smaller O.F. Power boost device for three-phase power line. Patent No. 2515049, publ. No 13 on 05/10/2014.

7. Smaller O.F. Voltage stabilization system on an extended power line. Patent No. 0252311, publ. No. 17 dated 06/20/2014.

8. Smaller O.F. A device for studying the operation of induction electric meters. Patent No. 2523109, publ. in No. 20 of 07/20/2014.

Claims (1)

A device for checking induction energy meters, containing two circuits, each of which operates alternately from positive and negative half-waves of the mains voltage, characterized in that each of these circuits contains an avalanche diode and a storage capacitor sequentially connected to the phase and zero conductors of the network after the meter , the connection point of these circuit elements is connected through a load resistor to the emitter-collector junction of the power transistor, another electrode junction which is connected to the phase conductor of the network, the avalanche diodes of the two circuits are connected to the phase conductor of the network by different electrodes - the cathode for the circuit operating from positive half-periods of the mains voltage, and the anode for the circuit operating from negative half-periods of the mains voltage, and the power transistors of these circuits ensure their conductivity discharge current through the corresponding load resistors, each of these power transistors being open to the corresponding half-wave of the mains voltage and reliably covered for another half-wave of the mains voltage, for which is used a step-down transformer whose primary winding is connected to phase and neutral conductors of the network after the accounting unit and its two separate secondary windings connected to the control electrodes of transition "the base-emitter" power transistors through limiting resistors.

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