RU2360346C2 - Direct current load power supply method and devices for realisation thereof - Google Patents

Abstract

FIELD: power engineering.

SUBSTANCE: invention can be used in power engineering, namely in devices for controlling high-voltage electric equipment parametres, including overvoltage protective devices for electric networks. Method of DC load power supply from AC electric power supply involves use of voltage divider. Resistor is made as potentiometer-type voltage divider, and voltage relieved therefrom is divided in two by again introduced capacitor voltage divider. Power supply of devices is performed by converting small loss currents of electric equipment itself. This excludes the possibility of using power supplies of control devices, which are replaced from time to time, e.g. galvanic cells, accumulators, etc. Into loss currents circuit there introduced is reactive (capacitor or inductive) or active voltage divider, there performed is rectification of drops of voltages created on those cells with radiation rectifiers, and charge with rectified current of storage capacitor whereto there periodically connected and supplied with power are control devices.

EFFECT: improving technical and economic specific power indices.

4 cl, 8 dwg

Description

The invention relates to electrical engineering and relates to the conversion and distribution of electrical energy (EE), in particular, circuits and devices for the transmission, distribution and conversion of electrical energy, including devices for protecting electrical power lines (power lines) and electrical equipment from lightning and switching overvoltages.

Protection devices include tubular arresters, valve arresters and non-linear surge arresters (arrester). Surge arresters are a relatively new class of protection devices with improved protective characteristics in comparison with the characteristics of these arresters.

As is known [1, 2], the arrester is a series / parallel connected non-linear resistors - varistors, enclosed in a sealed enclosure. The main difference between the material of nonlinear resistor-limiters and the material of the resistors of valve arresters is a sharply nonlinear current-voltage characteristic (I – V) and their increased throughput. The use of highly non-linear resistors in the arrester made it possible to exclude spark gaps from the apparatus design, which eliminates a number of drawbacks inherent in valve arresters. To protect electrical equipment from lightning and switching surges, limiters include parallel equipment.

When the limiter is operating under a voltage not exceeding the maximum permissible operating voltage, the varistor resistance reaches hundreds of megaohms. Due to the non-ideality of the material of the varistors, their resistance, although large, is not infinite; therefore, a current flows through the varistors, called the conduction current. The conductivity current is very small and, for example, for an arrester with a voltage of 110, ..., 220 kV is about 0.2, ... 0.8 milliamps. Conductivity current has an active capacitive character. The active component of the current determines the amount of loss in the limiter. The value of the conduction current is unstable and increases with the time of operation of the arrester. When exceeding the permissible current values, mainly its active component, the arrester must be decommissioned due to a violation of its thermal balance. Therefore, the main guidelines for the operation of electrical equipment, for example [3], require periodic monitoring of the conductivity current. Currently, surge arresters are equipped with conductivity current meters of various types, for example, made in accordance with [4].

When lightning or switching impulses of overvoltage occur in the network, the varistor resistance decreases sharply (to fractions of an ohm). A current pulse, which can reach tens of thousands of amperes, briefly flows through varistors. Varistors absorb the energy of the overvoltage pulse, then releasing it in the form of heat, scattering into the surrounding space. The surge voltage in the network is "cut off".

To control the modes of lightning and switching overvoltages of the network and the operation of the arrester, the limiters are equipped with various types of recorders, for example, made in accordance with [4].

Control devices made on the basis of the patent [4], for example [5, 6], are devices of the simplest type and do not need power devices. However, more sophisticated control devices [7, 8, etc.], which provide not only the measurement of the conductivity current or only the fixation of the arrester operation during overvoltages, but also, for example, the harmonic analysis of the conductivity current or the amplitude-time characteristics of the overvoltage current pulse, require power devices direct current. Such control devices can be powered by galvanic cells, batteries, solar panels [7], network power supplies of various types. The main disadvantage of such power supply devices for arrester monitoring devices is the need for periodic replacement of batteries or battery charge, which is very difficult to do under conditions of operation of high-voltage electrical equipment without disconnecting it.

The data of the invention, in particular, relate to DC power devices directly of non-linear surge suppressor monitoring devices. The essence of the proposal is that the power of these control devices is carried out by converting the conductivity current of the surge suppressor itself.

The electrical circuits of the devices according to the invention are presented in figures 1, 2, 3 and 4.

From the point of view of electrical engineering, arrester can be presented as a high-voltage source of alternating current of limited power. Its main parameters are:

1) alternating high voltage of 35-750 kV;

2) a relatively small value of the alternating current conductivity - in the range of 0.2-0.8 milliamps;

3) the inconstancy of the magnitude of this current depending on the operating conditions of the limiter, for example, temperature changes, etc .;

4) periodic, and random in time, the flow of current pulses of super-large magnitude - tens and hundreds of kiloamperes.

At the same time, the electronic equipment of the control devices involves direct current supply at a low-voltage stabilized voltage of the order of 3-12 V with power from tens of milliwatts to units and tens of watts.

The following methods are known for converting high voltage alternating current to low voltage direct current:

1) using step-down transformers and rectifiers;

2) using voltage dividers and rectifiers;

3) with the joint use of dividers and a transformer.

DC power devices based on step-down transformers are used mainly with a half-wave rectification circuit. Two-half-wave circuits are performed as bridge [9, Fig. 3.8a, p. 62] or according to the so-called scheme with a zero output of the transformer [10, Fig. 1.9a, p. 27], in which the alternating current is rectified by two half-wave beam rectifiers. Schemes of these power devices are shown in figure 5 and 6, respectively.

These devices for supplying power to the load (DC) with direct current according to the schemes of FIGS. 5 and 6 provide galvanic isolation of the low voltage load from a high voltage source, in particular a power transmission line. The main disadvantage of such devices is that these UPN are characterized by low values of specific energy indicators [W / kg, W / dm ³ , etc.]. This is due to the fact that even at low output powers, the high-voltage transformer is characterized by a relatively large mass due to the use of high-voltage insulation. The mass of such a transformer may exceed the mass of the arrester itself. In addition, such UPN with a low value of the output voltage U ₂ (of the order of 2-5 volts), commensurate with the voltage drop at the two valves of the rectifier bridge, are characterized by low values of efficiency.

However, the use of an alternating current electric energy source (IEPT) with a tap from its midpoint allows the load to be supplied with direct current through two half-wave beam rectifiers, which alternately conduct currents of these sources created on the basis of an alternating current voltage divider.

Devices for powering the load based on voltage dividers are quite fully described in the literature [11, 12 and 13]. The voltage dividers of such devices can be made on the basis of resistors, capacitors, or in combination with each other.

The disadvantage of UPN with a resistive divider is its low efficiency, since the entire load current passes through the active resistance of the ballast resistors. Therefore, such UPN are practically not used.

A peculiar IEE of alternating current with two output voltages (also in antiphase relative to the output of its midpoint) is a capacitor voltage divider (KDN). Strictly speaking, KDN, conducting an alternating current of the IEE, looks like a transformer with a tap from the midpoint of its secondary winding and therefore theoretically can also be used in conjunction with two beam rectifiers, however, capacitors conduct only alternating current and are not able to conduct a constant component of current. In fact, the inequality of the capacitances of KDN, due to technological and other reasons, practically exclude the possibility of using it to power the load through two beam rectifiers, alternately shunting the capacitors with load resistance.

Indeed, when the current passes through the KDN capacitors, due to the inequality of their reactance, the volt-second inequality over the half-period of the areas is created, and the capacitor of lower capacity (higher resistance) creates a large volt-second area. The energy stored by these capacitors is inversely proportional to their capacities. The connection of load resistance through the valves of the beam rectifiers creates inequality in the ampere-second areas, as a result of which negative effects are accumulated on the plates of the capacitors connected to the anodes of the rectifier valves, and the positive charges on the opposite ones, and the voltage on both capacitors directed opposite each other and approximately equal in size (due to the inequality of their capacities). For this reason, the current of the IEE passing through this KDN, first podryazyvaya capacitors to zero voltage, then recharges them, and the valves, closed by these voltages, do not conduct current to the load. Thus, KDN with the conclusion of its midpoint cannot fundamentally ensure the operation of beam rectifiers.

However, a direct current power source with a two-stage composite voltage divider is also known [10, Fig. 3], the circuit of which is shown in Fig.7. In this source, one stage (capacitor 2) is used to limit the magnitude of the current, and the other, made of capacitors of equal capacity 11 and 12, supplies the load resistance with current through two quasi-beam rectifiers 6 and 7, removed from these capacitors in turn.

The operability of such a device is achieved due to two additional valves - 26 and 27, which provide shunting of the capacitors to prevent overcharging. In this device, a combination of four gates creates a bridge rectifier, the loss of which is twice the loss in radiation rectifiers.

Since during operation (during each cycle) the capacitors 11 and 12 are charged and discharged, the power of the source enters the load and into the capacitors, one of which will be charged and the other discharged through the power source. Thus, the energy stored in the capacitors for one half-cycle will be returned to the power source for another half-cycle. This means that the energy efficiency of a limited power source (low current) will be very low. This virtually eliminates the possibility of such a device from a small current source.

The exclusion from this circuit of diodes 26 and 27, as noted above, leads to the inoperability of the UPN.

Closest to the technical essence of the invention according to paragraph 1 of the claims is a method of supplying a load with direct current from an alternating current electric energy source using a voltage divider, for example, a capacitor-resistive (CRDC) and a half-wave rectifier, the input of which is shunted by the resistor of this voltage divider, which consists in limiting the magnitude of the current in the load resistance by the capacitive resistance of the capacitor of the capacitor-resistive voltage divider, which removes they are removed from the resistor, and the rectified current is smoothed out by a low-pass filter (low-pass filter) [4, diagram of FIG. 3 of the patent] - see the diagram of Fig. 8. The term "load" hereinafter refers to a "device consuming power" according to ST IEC 50 (151) - 78 (Electrical Engineering. Terminology: Reference Guide. - Issue 3. - M .: Publishing House of Standards, 1989, p.133 )

Due to the fact that the alternating current removed from the resistor is rectified by a bridge rectifier, that is, it is carried into the load simultaneously by two valves, the efficiency of energy transfer to the low voltage load is very small.

The closest in technical essence to the claimed device according to paragraph 2 of the claims is a device for supplying a load with direct current, containing a capacitor-resistive voltage divider 2-3 and a half-wave rectifier 30, the anodes of two valves 6 and 7 of which are connected to the extreme terminals of the resistor 3 and the cathodes form the positive output terminal of the rectifier 8, connected to one terminal of the load resistance and one terminal of the capacitor 10 of the low-pass filter [4, Fig. 3], the circuit of which shown in Fig. 8. The disadvantage of this device, as noted above, is the use of 4 (four) valves for rectifying the current with a bridge rectifier.

In addition, it has a voltage limiter made on zener diodes 13 and 14, connected in series with each other, connected by their cathodes, and their anodes connected to the terminals of resistor 3. Input terminals 4 and 5 of this UPN are connected in parallel to the protective varistor 16 and through an arrester 17 directly or through a conductivity current sensor - to terminal 18. Parallel to the capacitor 2, a trip recorder of the arrester 17 is connected — an electromechanical counter 23. Terminal 18 is connected to the network wire of the protected power transmission line, and terminal 5 to the circuit grounding. In this device, the load 1 is a DC microammeter measuring the conductivity current of the arrester 17.

Due to the fact that the main elements of the arrester (connected in parallel to the protective varistor 16 and in series with the arrester 17) are the high-voltage oscillator and the rectifier connected to the terminals 4 and 5, the circuits of the arrester are considered to be connected to these terminals 4 and 5.

The closest in technical essence to the variants of the claimed device according to paragraphs 3 and 4 of the claims is a device for supplying a load with direct current, containing positive and negative output terminals for connecting the load resistance and the capacitor of the low-pass filter, a two-arm combined voltage divider, one of which forms a capacitor and the other is a resistor, to the terminals of which are connected the anodes of two zener diodes connected in series with each other and opposite Inonu their cathodes. [4] The disadvantages of this device are discussed above.

The aim of the invention according to paragraph 1 of the invention in a method of supplying a direct current load from an IEDP using a CRDC and a half-wave rectifier, the input of which is shunted by the resistor of this voltage divider, is to improve the specific energy performance of the devices for its implementation. This goal is achieved by reducing energy losses in the KRDN resistor and in the valves of its rectifier. To this end, the KRDN resistor is performed by a potentiometric voltage divider, and the voltage removed from it is divided in two by the newly introduced capacitor voltage divider, while the voltages removed from the potentiometric and capacitive voltage dividers are compounded and each sum of half of this voltage is rectified by beam rectifiers, and the reactive the resistance of the capacitors of an additional capacitor voltage divider at the frequency of an alternating current electric energy source is selected, for example, by the core is less than the resistance of the potentiometer and their capacitance C _g is determined by the formula C _g = U · C / Uc, where U is the voltage across the current-limiting capacitor of the capacitor-resistive voltage divider; C is the capacitance of the current-limiting capacitor of said voltage divider; U _C is the voltage at the input of the beam rectifiers, and the voltage of the AC electric power source U ₁ and the maximum output voltage of the rectifier are determined by the formulas U ₁ = U + 2U _C and U ₂ = √2U _C.

The main task, that is, the leading motive - the leitmotif of the invention according to claims 2-4 of the claims, is to provide rectification by beam rectifiers of alternating current to direct, in which it is detected - it is straightened.

The aim of the invention in the UPN according to paragraph 2 of the claims (diagram of FIG. 1) is to improve the technical, economic, mainly specific energy performance by reducing energy losses in the CRDN resistor and the valves of its half-wave rectifier. To this end, the UPN based on the CRDN and a half-wave rectifier, the anodes of two gates of which are connected to the extreme terminals of the resistor, and the cathodes form a positive output terminal of the rectifier, connected to one terminal of the load resistance and one terminal of the LPF capacitor, is equipped with two additional capacitors, and as a resistor the mentioned voltage divider a potentiometer is used - a variable resistance with a movable slider-engine, while additional capacitors are connected in series to ug with the other, the extreme terminals of the circuit are connected to the anodes of the rectifier valves, the output of the potentiometer slider is connected to the connection point of the capacitors and forms the negative output terminal of the AC rectifier, which is connected to the free terminals of the load resistances and to the other low-pass filter terminal.

The aim of the invention in UPN according to claim 3 of the claims (the diagram of FIG. 2) is to simplify the circuit of the device by combining the functions of rectifying AC and protecting it from overvoltage due to the use of zener diodes included in the arms of the beam rectifier included in the arms of two beam rectifiers.

To this end, a converter based on the CRDN containing positive and negative output terminals for connecting the load resistance and the low-pass filter capacitor, a two-arm combined voltage divider, one arm of which forms a capacitor, and the other a resistor, the terminals of which are connected to the anodes of two zener diodes included in the chain is serially opposite to each other and connected by their cathodes; a potentiometer with an engine is used as a resistor, which forms a negative one, and the connection points of the cathodes with abilitronov - positive output terminals of said rectifier.

The aim of the invention according to claim 4 of the invention (the scheme of figure 3) is to improve the specific energy performance of the UPN according to claim 3 by reducing the energy loss in the voltage divider and increasing the speed of energy transfer to the low-frequency capacitor filter (LPC). This goal is achieved through the use (application) as the other arm of the voltage divider linear choke, the winding of which is made of two equal halves and is equipped with a tap from its middle.

Figure 1-4 shows a diagram of a device for supplying a load with direct current in the protection system of power lines with arrester. In the device according to the scheme of figure 1, the load resistance 1 receives an EE from a capacitor-resistive voltage divider, made in the form of a chain of a capacitor 2 connected in series and a potentiometer resistor 3 connected to terminals 4 and 5. Valve anodes 6 are connected to the extreme terminals of the resistor 3 and 7, the cathodes of which form a positive output terminal 8 of the rectifier. The load resistance connected to the positive 8 and negative 9 terminals of the rectifier is bridged by the capacitor 10 of the low-pass filter, smoothing the ripple of the rectified current. The low-pass filter capacitor connected to the output of the beam rectifiers (that is, parallel to the output) is an integrating unit, and with a large capacity it is an energy storage device, especially in those devices with arrester in which the load resistance 1 is connected to this storage device periodically.

The capacitors 11 and 12, connected in series with each other, form a capacitive voltage divider connected in parallel with the potentiometer 3. The connection point of these capacitors with each other is combined with the movable motor of the potentiometer and forms a negative output terminal of the rectifier. The parallel connection of the capacitive voltage divider 11-12 and the resistive voltage divider - potentiometer 3 form a compounding unit - mixing currents in separate branches - shoulders of this four-arm block, as a result of which the voltage at its output is balanced. This, eliminating the asymmetry of the voltages on the shoulders of the capacitive voltage divider 11-12 (due to the inequality of the capacitances of these capacitors), ensures the normal operation of two beam rectifiers formed by valves 6 and 7. If necessary, stabilize the voltage parallel to the resistor, as in the prototype, a circuit can be connected of two zener diodes or one two-anode zener diode.

Figure 2 shows just a simplified version of an arrester with an arrester, in which capacitors 11 and 12 are absent, and zener diodes 13 and 14 are used as beam rectifier valves. They not only provide AC rectification, but also stabilize the voltage at load 1. This option it is possible to use in two cases: 1) with a rare connection of load 1 to drive 10, in this case, the efficiency of the device is not particularly important, since the drive manages to charge even with increased power losses; 2) if it is unacceptable to add additional capacity to the conduction current circuit, for example, in the case of using the conduction current spectrum analyzer as a load.

Figure 3 presents the scheme of UPN according to claim 4 of the claims. In this device, the winding of the linear inductor 15 is connected in series with the capacitor 2, the tap from the middle of which forms the negative output terminal of the rectifier 9. The zener diodes 13 and 14, connected with their anodes to the extreme terminals of the inductor 15, form the positive output terminal 8 of the beam rectifiers with their cathodes. The voltage U ₁ , taken from terminals 4 and 5, as in the UPN according to the schemes of Figures 1 and 2, is equal to the voltage taken from the protective varistor 16 (not shown in the diagrams), which is connected through the arrester 17 to the protected equipment (terminals 18 and 5).

All three UPN circuits (Figs. 1-3) are covered by the unity of the inventive concept - rectification of small and ultra-small current values by beam rectifiers (with simultaneous stabilization of the rectified voltage when using zener diodes in these rectifiers, including according to the circuit of Fig. 1), be used at significantly higher load currents.

Figure 4 presents one of a number of possible examples of the use of the proposed device in the protection system of electrical equipment with arrester. According to [5], the surge suppressor 17 is connected in series with the protective varistor 16, while the input terminal 18 of the limiter 17 is connected to the network wire, and the output terminal 5 of the protective varistor 16 is connected to the ground loop. An arrester monitoring device, consisting, for example, of a current sensor 19 connected to a voltage divider circuit and a counter or load meter 1 for the power supply in question, is connected in parallel to the protective varistor 16 with terminals 4 and 5 and is supplied with current by the electronic meter (meter) UPN. The current sensor and the device for supplying the load is additionally protected against overvoltages by protective small-sized arresters or, as shown in Fig. 4, by protective diodes 20 and 21.

The implementation of the method of power supply of the load according to claim 1 of the claims will be considered when performing UPN according to the scheme of figure 1.

When considering the operation of the UPN, we assume that before applying voltage to the terminals-terminals 4 and 5, the LPF capacitor (energy storage) 10 is discharged. The capacitors 11 and 12 are also discharged. We will also assume that at the time of connecting the UPN to the network, the voltage is zero and at subsequent times increases in absolute value, and positive is applied to terminals 18-4 in the first (and subsequent odd half-periods), and to terminal 5 - negative voltage.

Due to the fact that the resistance in the circuit with capacitor 2 is capacitive in nature (the resistance of the capacitors 11, 12 can be practically neglected due to their smallness compared to the resistance of the capacitor 2, and the resistance of the resistor 3 at that time is shunted by discharged capacitors, the resistance of which equal to zero), the current is ahead of the voltage by almost 90 el. hail. This current, passing through the circuit 4-2-11-12-5 (we will consider it the first circuit), branches out at the junction point of the capacitors 2 and 11 and charges the low-pass filter capacitor 10 through the diode 6 of the beam rectifier through the circuit: 2- 6-8-10-9-12-5 (we consider this chain to be the second).

When the voltage reaches the maximum amplitude value, the current becomes equal to zero, and the capacitors 2, 11 and 12 have a positive potential on the upper plates according to the scheme of Fig. 1. The capacitor 10 is partially charged and has a positive charge on the right lining according to the scheme of figure 1. Since the current in the first circuit at this time changes sign and flows in the opposite direction along the circuit: 5-12-11-2-4, as well as along the third circuit: 5-7-8-10-9-11-2 -4, the capacitor 10 will be recharged along the second and third circuits, simultaneously discharging on the resistance 1 (if it is connected by a key 22, as shown in the diagram of figure 4).

In the second (and the next even) half-periods of the network voltage change, the conduction current of the system with an arrester, recharging-discharging the capacitors 11-12 of the voltage divider, provides a charge of the low-pass filter capacitor 10 to a voltage not exceeding the amplitude value of the voltage on the shoulders of the voltage divider.

Resistor-potentiometer 3, the resistance of which is at least an order of magnitude higher than the capacitive (at the source frequency) resistance of the capacitors 11 and 12 of the introduced capacitive voltage divider, as noted above, providing phase compounding - mixing voltages / currents taken from the arms of the resistive voltage divider (potentiometer 3) and capacitive (capacitors 11 and 12, almost always having different capacities), as a result of which the capacitors 11 and 12, charging in one half-cycle of the change in the source current, are discharged into each other ohms and at the same time serve as sources of electrical energy for two beam rectifiers, valve diodes 6 and 7 of which charge the low-pass capacitor 10. It is this capacitor that serves as the power source for the load resistance 1, connected in parallel to the capacitor 10 constantly or connected to this drive periodically.

Capacitors 11 and 12, being charged-discharged by a current that changes in harmonic law without overcharging, create a voltage on the potentiometric divider 3, twice the voltage on each of these capacitors. It is this effect of phase compounding of currents / voltages in the divider 3-11-12 that ensures the operability of the capacitor voltage divider 11-12 with an inequality in the capacitances of its capacitors.

When the capacitance C of the current-limiting capacitor 2 KRDN and the capacitance C _{g of the} capacitors 11 and 12, the voltage U _c at the input of the beam rectifiers is √2 times higher than the voltage U ₂ at their output (terminals 8 and 9), and the voltage U ₁ at the terminals 4-5 UPN equal to the sum of the voltages U at the capacitor 2 and the voltage at the input of the beam rectifiers U ₁ = U + 2U _C.

When operating UPN according to the scheme of figure 2, the zener diodes 13 and 14 of the beam rectifiers, supplying load 1 and the charge of the low-pass filter capacitor 10, also protect them from overvoltage. As the resistor 3, you can use two connected resistors equal to the resistance, the connection point of which forms the output 9.

The current in the first and subsequent odd half-periods of voltage change passes in the form of pulses along the circuits 4-2-3-5, bypassing the load and 4-2-13-8-1-9-3 (the lower part of the resistor) -5, and in even half-cycles along the circuit: 5-3-2-4, also bypassing the load and 5-14-8-1-3 (the upper part of the resistor) -2-4.

The capacitor 10 low-pass filter is charged by the current of the rectifiers when the current passes through the load 1 and provides its power in the time intervals between the current pulses of the rectifiers. The current pulses of the beam rectifiers in odd half periods are limited by the resistance of the lower half of the resistor (in the even half of the upper half), which can be considered as a L-shaped RC filter of the rectifier (see, for example, V. Roginsky. Calculation of power supply devices. M .: Communication , 1972, § 5.2. Calculation of simple LC and RC filters. - 149-167 p.). As the charge of the capacitor 10 current pulses are reduced in amplitude and duration, and the voltage across it reaches the _^half amplitude of the voltage across the resistor 3. When this voltage exceeds the voltage "breakdown" zener diodes 13-14, the latter, pushing, prevent further charging of the capacitor 10, and the current in the odd half-cycle will pass through the circuit: 4-2-13-8-14-5, and in the even - through the circuit: 5-14-8-13-2-4.

In the case of the UPN according to the scheme of Fig. 3, the inductive voltage divider 15 in combination with the zener diodes 13 and 14 provides not only a half-wave rectification of the conduction current of the arrester with two beam rectifiers and protection of the load from overvoltage, but also an increase in the rate of energy transfer to the load. The increase in this speed is due to the fact that energy is transferred to the load not only electric but also electromagnetic paths along the chains: 4-2-13-8-1-9-15 (upper half-winding) and 4-2-13-8- 1-9-15 (lower half-winding) -5 in one half-cycle and in chains: 5-14-8-1-9-15 (lower half-winding) and 5-14-8-1-9-15 (upper half-winding) - 2-4.

An autotransformer with a transformation coefficient K _T = 2, reducing the voltage by half, doubles the current at the output of the rectifiers, i.e. doubles the magnitude of the charge current of the capacitor 10.

Considered UPN according to the schemes of figures 1, 2 and 3 can be used to power any low-voltage loads, including control devices of surge arrester, from high-voltage sources of alternating current electric energy. The implementation of the proposed UPN, for example, performed according to the scheme of figure 1, in the monitoring device of the arrester can be considered in more detail on the example of the scheme of figure 4.

The arrester monitoring device, including as a main element a protective varistor 16, a current sensor 19 and an overvoltage pulse counter and / or a conductivity current meter 1, is constantly connected to the limiter 17. In the absence of overvoltage conditions in the network, the conduction current flows only through the current sensor of the device and the voltage converter due to the high resistance of the protective varistor 16. A signal about the current value is supplied to meter 1. At the same time, the storage capacitor 10 is charged (the electrical processes when charging the capacitor are described above).

An indication of the current value or data transfer, for example, via a radio channel, when a large power consumption is required, occurs periodically, in the so-called pulsed mode. The specified operating mode of the storage capacitor is described in the literature (see, for example, Veksler G.S. Power supply for special equipment: Textbook for high schools. 2nd ed. - Kiev: Vishcha school. Head publishing house. 1979. - 368 p. In section "Work on the storage capacity", p.93-95). The meter is connected to the capacitor 10 using the built-in key 22. At the end of the session, the capacitor 10 is again charged.

During network overvoltages, only part of the overvoltage current flows through the current sensor 19, while the main current flows through the protective varistor 16. The meter / counter 1 accumulates information and displays / transmits it in the indicated mode. Additional protection of the radio elements of the device against overvoltage is provided by zener diodes or the so-called protective diodes 20 and 21.

Thus, if the device for supplying the load with direct current, containing a capacitor-resistive voltage divider and a half-wave AC rectifier, the anodes of the two valves of which are connected to the extreme terminals of the resistor, and the cathodes form a positive output terminal of the rectifier connected to one terminal of the load resistance and one terminal the low-pass filter capacitor, provide two additional capacitors, and use the potential as a resistor of the voltage divider tr - variable resistance with a movable slider, in this case, connect additional capacitors to the circuit in series with each other, connect the extreme terminals of the circuit to the anode of rectifier valves, connect the output of the potentiometer slider to the connection point of these capacitors, it forms a negative output terminal of the AC rectifier, which must be connected with free terminals of the load resistance and with another terminal of the low-pass filter capacitor, the voltages removed from the potentiometric and capacitive voltage dividers are compounded, and each half of this compounded voltage is rectified by beam rectifiers, the energy losses in the resistor and valves of a half-wave rectifier are reduced, which improves the specific energy indicators of the device according to claim 2.

If in the UPN containing the positive and negative output terminals for connecting the load resistance and the low-pass filter capacitor, there is a two-arm combined voltage divider, one arm of which forms a capacitor, and the other a resistor, to the terminals of which are connected the anodes of two zener diodes connected in series with each other to each other and connected by their cathodes, use a potentiometer with a slider as a resistor, which forms a negative, and the connection point of the zener diodes The output terminals of the rectifier mentioned above, the design of the device is simplified and prevents overvoltage on the load. And if you use a linear inductor with a tap from its midpoint as a voltage divider, the energy loss in the UPN is reduced and the charge current doubles, which increases the rate of current transfer to the storage capacitor of the low-pass filter.

The lack of information (recommendations) in the technical and patent literature on the implementation of the described device circuits in order to achieve the described effect (result) of half-wave rectification of alternating current by two beam rectifiers operating alternately when powered by capacitive, resistive or inductive voltage dividers, shows the novelty of the relationship between a set of essential features of the described inventions and a positive effect. This provides a significant difference between these inventions from all known devices of similar purpose, and the novelty of the proposal does not follow explicitly from the prior art, which provides an inventive step for these inventions.

The proposed method and UPN can be used, as noted above, not only for the operation of devices with arrester, but also to power other low-voltage (mainly information) devices that operate both in continuous and in pulsed modes.

Experimental studies of the layout of the device to power the load confirmed the efficiency and reality of achieving the goals formulated in the invention.

Information sources

1. Afanasyev A.I. and other Devices for limiting overvoltages in high-voltage networks: Textbook. allowance. / Ed. A.I. Afanasyev. SPb .: Publishing house of SPbSTU, 2000, 164 p., Ill.

2. Afanasyev A.I., Bogatenkov I.M. High voltage tests of electrical apparatus. Part 1. Testing non-linear surge arresters. Textbook allowance. / Ed. A.I. Afanasyev. St. Petersburg: Publishing House of St. Petersburg State Technical University, 1998, 136 pp., Ill.

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Claims (4)

1. The method of supplying the load with direct current from an alternating current electric energy source using a voltage divider, a capacitor-resistive and half-wave rectifier, the input of which is shunted by the resistor of this voltage divider, which consists in limiting the current value in the load resistance by the capacitive resistance of the capacitor of the capacitor-resistive voltage divider, which is removed from the resistor and smooth the rectified current with a low-pass filter, characterized in that the resistor is with a potentiometric voltage divider and the voltage taken from it, are divided in two by the newly introduced capacitor voltage divider, while the voltages removed from the potentiometric and capacitive voltage dividers are compounded and each half of this voltage is rectified by beam rectifiers, and the reactance of the capacitors of the additional capacitor voltage divider by the frequency of the AC electric energy source is selected, for example, by an order of magnitude less than the potential resistance pa and capacitance C _g is determined by the formula _{C g = U · C / U} C, where U - the voltage on the capacitor current-limiting capacitor-resistor voltage divider; C is the capacitance of the current-limiting capacitor of said voltage divider; U _C is the voltage at the input of the beam rectifiers, and the voltage of the AC electric power source U ₁ and the maximum output voltage of the rectifier are determined by the formulas U ₁ = U + 2U _C and U ₂ = √2U _C. 2. Device for supplying the load with direct current, containing a capacitor-resistive voltage divider and a half-wave rectifier of alternating voltage, the anodes of the two valves of which are connected to the extreme terminals of the resistor, and the cathodes form a positive output terminal of the rectifier connected to one terminal of the load resistance and one terminal of the filter capacitor low frequencies, characterized in that it is equipped with two additional capacitors, and used as a resistor of the voltage divider an potentiometer is a variable resistance with a movable slider, while additional capacitors are connected in series with each other, the extreme ends of the circuit are connected to the rectifier valve anodes, the output of the potentiometer slider is connected to the connection point of these capacitors and forms a negative output terminal of the AC rectifier, which is connected with free terminals of the load resistance and with another low-pass filter capacitor terminal. 3. A device for supplying the load with direct current, containing positive and negative output terminals for connecting the load resistance and the low-pass filter capacitor, a two-arm combined voltage divider, one arm of which forms a capacitor, and the other a resistor, the terminals of which are connected to the anodes of two zener diodes in a chain sequentially opposite each other and connected by their cathodes, characterized in that a potentiometer with a movable slider is used as a resistor, which th forms a negative, and the junction point of the zener diodes cathodes is the positive output terminals of the said rectifier. 4. The device for supplying the load with direct current according to claim 3, characterized in that the other arm of the voltage divider is made in the form of a linear inductor, the winding of which is taped from its middle.

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