RU2616192C1 - Inverter circuit for verification of inductive electricity meters - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: an inverter circuit is claimed and meant for verification of inductive electricity meters. It comprises of a line-voltage rectifier on series-connected high-current pulse diode and electrolyte condenser of a high capacity C which is calculated by the formula C≈T/2η(1+η)R, where T is AC cycle provided that the ratio η of the charging time to the discharging time of the electrolyte condenser is many times greater than one, e.g. 0.01 and less, where R is the load resistance characterized in that an additional rectifier, which is identical to said one for another half-wave of the AC current, is introduced into it. The both series-connected electrolyte high-capacity condensers are connected to collectors of series-connected power transistors of n-p-n and p-n-p types respectively. Their emitters are coupled with the midpoint of the electrolyte high-capacity condensers through a throttle which forms the line-voltage output for load R. The throttle is connected to a film-type condenser. Both, the throttle and the condenser, form an oscillating contour tuned to the line-voltage frequency (e.g. 50 Hz). Herein the control of the power transistors is performed by the connection of a step-down winding of a small-power transformer to their 'base-emitter' junctions. The transformer is linked to the input terminals and the power pulse diodes of the double-wave rectifier shall be designed for the pulse current amplitude I_{PUL MAX}≈I_N/η, where I_N is the nominal load current with the resistance R.

EFFECT: construction of an inverter circuit of a device where the rectified voltage is converted by simple means into an AC voltage of 220 V.

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Description

The invention relates to the field of measuring equipment and can be used to test newly developed electricity meters, in particular, induction type in order to exclude uncontrolled energy consumption [1-2].

Known instruments for checking induction electric meters for the correct metering consumed by the consumer of electricity [3-14 and 16-22].

The closest analogue of the claimed technical solution is “A device for checking the correctness of electricity metering by induction electric meters” [16], which consists of a power pulse diode and an electrolytic capacitor connected in series after the verified electric meter, to which an active load is connected in parallel, which allows DC operation, and the capacitance From the electrolytic capacitor is found by the formula С≈Т / 2η (1 + η) R, where Τ is the period of the alternating current of the network, provided that from Ocean η charging time to the time of the electrolytic capacitor discharge is much less than unity, for example, about 0.01, wherein R - load resistance connected in parallel to the electrolytic capacitor and the power switching diode must be designed for _IMP I ≈2I pulse current _N / η, where I _N is the rated current in the load with resistance R.

The disadvantage of this device is the supply of the load from direct current with an increased voltage (about 310 V), which excludes the operation of many household appliances designed for AC 220 V.

The specified disadvantage is eliminated in the claimed technical solution.

The aim of the invention is to construct a device circuit according to the inverter principle, in which the rectified voltage is converted by simple means into an alternating voltage of 220 V.

This goal is achieved in an inverter circuit for checking induction electric meters, containing a mains voltage rectifier on a series-connected high-current pulse diode and high-capacity electrolytic capacitor C, calculated by the formula С≈Т / 2η (1 + η) R, where Τ is the period of the alternating current of the network , provided that the ratio η of the charge time to the discharge time of the electrolytic capacitor is many times less than unity, for example, of the order of 0.01 or less, where R is the active resistance of the load, characterized in that an additional rectifier similar to the specified one is introduced for the other half-wave of the alternating current of the network, and both large-capacity electrolytic capacitors connected in series are connected to collectors of series-connected power transistors of npn and pnp types, respectively, whose emitters are connected to the midpoint of large-capacity electrolytic capacitors through a choke, forming a network voltage output for connecting the load R, to which a film capacitor is connected, forming together with oscillator circuit tuned to the frequency of the mains voltage (for example, 50 Hz), while the operation of power transistors is controlled by connecting to their base-emitter junctions a lower winding of a low-power transformer connected to the input network contacts, and pulse power diodes of a half-wave rectifier should be calculated on the amplitude of the pulse current I _{IMP MAX} ≈I _N / η, where I _N is the rated current in the load with resistance R.

The achievement of the objective of the invention is explained by the construction of an inverter conversion circuit using power transistors of different types of conductivity according to the bridge circuit of their inclusion to electrolytic capacitors of half-wave rectifiers, and a parallel oscillatory circuit made of a choke and a film (i.e. bipolar) capacitor tuned to the frequency is installed in the diagonal of this bridge circuit mains voltage with the operation of power transistors from a low-power step-down transformer connected to network contacts. At the same time, a sinusoidal voltage is formed on the inductor with an effective value of 220 V, connected to a load with a resistance of at least R.

In fig. 1 presents a schematic diagram of the inventive device, including the following elements:

1 and 2 - power diodes, for example, avalanche to pulse currents I _{IMP MAX} ,

2 and 4 - electrolytic capacitors of large capacity C,

5 and 6 - power transistors respectively n-p-p and p-n-ρ types,

7 - inductor with inductance L,

8 - film capacitor with a capacitance C _To , forming a parallel oscillatory circuit with a choke, tuned to a frequency f = 1 / 2π (L C _To ) ^1/2 = 50 Hz,

9 - low-power step-down transformer,

10 - resistor limiting the base currents of power transistors 5 and 6 (several ohms)

In fig. Figure 2 shows a graph of the period of the mains voltage with an amplitude U _О , and in Fig. 3 is a graph of pulse charging currents of electrolytic capacitors 2 and 4 in the corresponding parts of the half-periods of the mains voltage. The duration of these pulses t _{And is} very small compared to the half-cycle Τ / 2 of the mains voltage, so that the ratio η = 2t _And / Τ = Δϕ / π≤0.01, at the value of which the induction-type meter takes into account only not more than 25% of the actually consumed power connected to the inductor 7 load R, which violates the correct metering of electricity and requires the developers of such metering devices to provide effective protection against theft of electricity.

Consider the operation of the claimed device.

As was shown in [16], at a constant time τ of the discharge circuit of an electrolytic capacitor with a capacitance C to a load of resistance R, where τ = RС, significantly longer than the period Τ of alternating current, that is, at τ = RC >> T = l / f, the electrolytic capacitor will be charged to approximately the amplitude voltage U _О = (2) ^1/2 U _С , where U _С is the effective mains voltage (220 V), and during operation, the load will change slightly over time, for example, by ΔU ^* for ΔT _DISCHARGE time interval equal to Τ-t _AND , where t _AND is the pulse time interval charge of the capacitor for each of the periods of the alternating voltage, and ΔT _SIZE >> t _I. Denote t _AND / ΔT _SIZE = η. Then η << 1, for example, η≤0.01. At the same time, a direct current with an increased voltage (about 300 V) flows in the load compared to the operating voltage of the network, which is a known inconvenience when using standard consumers.

In the considered circuit, the discharge of each of the capacitors 3 and 4 does not occur during the period T, but only during the half-cycle Τ / 2, which is determined by the operation of power transistors 5 and 6, controlled from a step-down transformer 9 connected to the network, while in the oscillating circuit from an inductor 7 and a film capacitor 8, an alternating voltage is formed with an amplitude approximately equal to U _O - an analog of the mains voltage supplied to an external load with resistance R.

Power pulse diodes 1 and 2 are turned on so that they pass current only into odd and even half-periods of alternating voltage, recharging electrolytic capacitors 3 and 4 to voltage U _О from voltage U _О -ΔU in each half-period of mains voltage, as can be seen in Fig. . 3. During the time _{ΔТ SIZE} = T / 2 (1 + η) due to the current flowing in the active load with resistance R, the voltage only slightly decreases by ΔU by the exponential law u (t) = U _O exp (-t / τ), so that ΔU = U _O [1-exp (-ΔT _SIZE / τ) = U _O {1-exp [-T / 2 (1 + η) τ]}. Assuming the ratios η and T / 2 τ to be the same, we find ΔU = U _O [1-exp (-η / (1 + η)], and the voltage drop ΔU is of the order of 3 V. Then the capacitance of the electrolytic capacitor is found by the formula: C = T / 2ηR - separately for each of the two branches of the rectifiers. At T = 20 ms and η = 0.01 we get С≈1 / 2R (here the capacitance is expressed in farads, the load in ohms). The charge of capacitors 3 and 4 begins in each half-cycle alternating voltage at the time when the voltage across the capacitor reaches the minimum value U _O -ΔU-ΔU _POT , where ΔU _POT - voltage loss to the diode x 1 and 2 and transistors 5 and 6, for example, of the order of 2.5 V, that is, up to a value of about 305 V, and during the time ΔТ _ZAR = ηТ / 2 (1 + η) increases to the maximum value U _MAX = U _O - _PRP ΔU = 307.5 B. energy recharging W _Zar electrolytic capacitors calculated by the formula W = C _Zar {U _O ² - [U _O -ΔU)] ^2} / 2 = C _[O U ΔU ^ΔU-2/2] ≈ CU _O ΔU, since ΔU << U _O by the initial condition. This energy W _Zar recharge is negligible compared to the total energy of the electrolytic capacitors CU _O ^2/2 (in U _O / 2ΔU≈50 times!), So you can use it electrolytic capacitors.

Given the small voltage drop ΔU, we can assume that an alternating voltage U _C * = 217 V is formed on the inductor 7, which is almost equal to the initial mains voltage U _C.

. Тогда расчетная емкость конденсаторов 3 и 4 равна С≈1/2R=0,01064 Ф=10638 мкФ. Рабочее напряжение этих конденсаторов должно быть не менее 400 В. Такая большая величина емкости приводит к существенному удорожанию всего прибора в целом. Так, известные импортные электролитические конденсаторы емкостью 4700 мкФ на напряжение 400 В стоят на рынке от 1000 до 2000 рублей за одну штуку, а в таком приборе их надо использовать желательно в количестве 6 штук в двух цепях выпрямителей по 3 параллельно соединенных конденсатора. При этом такой прибор стоил бы более 10 тысяч рублей при закупке конденсаторов оптом.Consider an example in which the power consumption in the load R is 1 kW. This means that the resistance value R is chosen equal to

. Then the calculated capacitance of capacitors 3 and 4 is equal to C≈1 / 2R = 0.01064 F = 10638 μF. The operating voltage of these capacitors must be at least 400 V. Such a large value of the capacitance leads to a significant increase in the cost of the entire device as a whole. So, well-known imported electrolytic capacitors with a capacity of 4700 μF for a voltage of 400 V are on the market from 1000 to 2000 rubles per unit, and in such a device they should be used preferably in an amount of 6 pieces in two rectifier chains of 3 capacitors connected in parallel. Moreover, such a device would cost more than 10 thousand rubles when purchasing capacitors in bulk.

The inductor 7 is made with a PEV-2 conductor with a diameter of 1 mm on a W-shaped iron with a core cross section Ш40 × 80 with an inductance L = 1 H, the film capacitor 8 has a capacitance of 10 μF at an operating voltage of 400 V. Resonance frequency f = 50 Hz. A transformer 9 with a power of about 5 W lowers the control voltage of transistors 5 and 6 to 5 ... 7 V.

As power transistors 5 and 6, you can apply KT862A (n-p-n) and KT892A (p-n-p). Diodes 1 and 2 of type B200 must allow pulsed charging currents of up to several kiloamperes.

The applicant in [15] proposed an option for constructing an electricity metering device, excluding the theft of electricity by known methods.

Literature

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2. Smaller O.F. The way to combat the theft of electricity (Lesser method), RF patent No. 2308726, publ. No. 29 dated 10/20/2007.

3. Smaller O.F. A device for checking the sensitivity of an electronic electric meter with two current circuits with active load and reactive compensation, RF patent No. 2338217, publ. No. 31 of 11/10/2008.

4. Smaller O.F. The device for checking electric meters of active energy, RF patent No. 2456623, publ. at number 20 from 07/20/2012.

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Patent Search Data

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Claims (1)

An inverter circuit for checking induction electric meters, containing a mains voltage rectifier on a series-connected high-current pulse diode and a large-capacity electrolytic capacitor C, calculated by the formula C≈T / 2η (1 + η) R, where T is the period of the alternating current of the network, provided that the ratio η of the charge time to the discharge time of the electrolytic capacitor is many times less than unity, for example, of the order of 0.01 or less, where R is the active resistance of the load, characterized in that a similar an additional rectifier for the other half-wave of the alternating current of the network, and both large-capacity electrolytic capacitors connected in series are connected to collectors of series-connected power transistors of npn and pn-p types, respectively, the emitters of which are connected to the midpoint of large-capacity electrolytic capacitors through a choke, which forms the output of the mains voltage for connecting the load R, to which a film capacitor is connected, forming together with the inductor an oscillating circuit, the frequency of the mains voltage (for example, 50 Hz), while the operation of the power transistors is controlled by connecting to their base-emitter junctions a lower winding of a low-power transformer connected to the input network contacts, and the pulse power diodes of a half-wave rectifier must be designed for amplitude pulse current I _{IMP MAX} ≈I _N / η, where I _N is the rated current in the load with resistance R.

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