RU2335126C1 - Electrical deratisation device - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: electrical deratisation device relates to means of rodent control and can be used for scaring away rodents from storing places of agricultural and food products, from building basements, from underground pipeline collectors. Electrical deratisation device comprises high-voltage terminal electrodes connected to high-voltage pulse source which consists of charging circuit, two power rails, high-voltage transformer and pulse generator which includes energy-storage capacitor and electronic switch and which is fed from primary cell. Feature of novelty consists in fact that primary and secondary windings of high-voltage transformer are galvanically disconnected from each other. High-voltage terminal electrodes are connected to both ends of secondary high-voltage transformer winding. Electronic switch is fitted with two electrodes. Pulse generator is fed from primary cell through current half-waves of both polarities with the help of charging circuit consisting of current-limiting capacitor, two diodes and inductance coil. Cathode of the first diode, anode of the second diode and first plate of current-limiting capacitor are connected to each other. First lead of inductance coil is connected to cathode of the second diode; its second lead, first lead of the high-voltage transformer primary winding and first plate of energy-storage capacitor are connected to each other. Second lead of high-voltage transformer primary winding is connected to the anode of electronic switch. Anode of the first diode, second plate of energy-storage capacitor and cathode of electronic switch are connected to each other and are connected to the first power rail. Second plate of current-limiting capacitor is connected to the second power rail. According to the second version and in contrast to the first one feature of novelty of the electrical deratisation device consists in fact that one end of high-voltage transformer secondary winding is connected to grounding device, and the other end is connected to high-voltage terminal electrodes.

EFFECT: simplification of electrical deratisation device design and improvement of performance characteristics regarding electrical and fire safety.

6 cl, 4 dwg

Description

The invention relates to means for controlling rodents and can be used to scare away rodents from storage areas for agricultural products and food products, from basements of buildings, from collectors of underground utilities, etc.

A device for controlling rodents is known - an electric disinfestator [US, N 4780985, class. A01M 19/00, publ. 1988.11.01], in which the defeat of rodents by electric current occurs according to a two-wire circuit, while the rodent simultaneously touches two different-polar high-voltage electrodes. The device comprises a housing with high voltage contact electrodes fixed to it, to which voltage is supplied from a high voltage power source.

The disadvantages of this device are the lethal effects on rodents and, as a consequence, the need to remove the carcasses of dead rodents as soon as possible, as well as a high degree of danger to personnel.

The closest technical solution to the claimed device is a device - an electric disruptor, in which rodents are scared away by exposing the rodent to the body with high-voltage pulses of electric current in a single-wire circuit [RU N2087098, cl. A01M 29/00, 19/00, publ. 1997.08.20 (prototype)]. The radiator consists of the following main units: high-voltage contact electrodes and a power supply system connected to the primary current source - 220 V, 50 Hz network, and the power supply system is equipped with a control unit in the form of a three-electrode timing device, a source of high-voltage pulses made in the form of a high-voltage transformer and generator pulses, including a power capacitor, a controlled electronic key, a diode, a charging resistor and power terminals.

This design has several disadvantages:

1) A high degree of danger to personnel. High-voltage contact electrodes connected to the free terminal of the secondary winding of a high-voltage transformer do not have galvanic isolation from the primary current source - a single-phase network of 220 V, 50 Hz, since the beginning of the secondary winding is electrically connected to the end of the primary winding of the transformer. At the same time, the disinfector is intended mainly for such premises (warehouses, basements, etc.), which, in terms of the degree of danger of electric shock, relate either to rooms with increased danger or to especially dangerous premises [Polyak DI Manual on electrical safety (for employees of research institutes). - Novosibirsk: Science, Siberian Branch, 1974, 80 pp.]. Therefore, if a person accidentally touches the contact electrodes of a working device, it may result in electric shock from a 220 V, 50 Hz network, which can have serious consequences, even fatal.

2) Electricity consumption from the network 220 V, 50 Hz comes from half-waves of the same polarity, which can lead to the congestion of a large number of deratizers at the same time.

3) The voltage of the high voltage pulses on the high voltage contact electrodes depends on the voltage of the primary current source.

4) Heat losses in the charging resistor and current limiter in the power circuit of the timing device in the control unit are too large, which is unsafe in fire.

5) The personnel safety device is extremely unreliable, due to the fact that the non-contact rodent detector can falsely respond in response to human presence.

The technical result of the invention is to simplify the design of the electric disinfestator and increase its operational characteristics in the field of electrical safety of both personnel and electrical networks, as well as in the field of fire safety.

The technical result is achieved by the fact that in an electric disruptor containing high voltage contact electrodes that are connected to a source of high voltage pulses, consisting of a charging circuit, two power buses, a high voltage transformer and a pulse generator, including an energy storage capacitor and an electronic switch, and powered by a primary current source , new is that the primary and secondary windings of the high voltage transformer are galvanically isolated from each other, to both ends of the second the high voltage transformer’s winding is connected to high voltage contact electrodes, the electronic switch has two electrodes, the pulse generator is supplied from the primary current source from half-waves of current of both polarities using a charging circuit consisting of a current-limiting capacitor, two diodes and an inductor, while the cathode of the first diode, the anode of the second diode and the first lining of the current-limiting capacitor are interconnected, the inductor is connected by the first output to the cathode of the second the iodine, its second output, the first output of the primary winding of the high voltage transformer and the first lining of the energy storage capacitor are interconnected, the second output of the primary winding of the high voltage transformer is connected to the anode of the electronic key, the anode of the first diode, the second lining of the energy storage capacitor and the cathode of the electronic key are interconnected and connected to the first power bus, the second lining of the current-limiting capacitor is connected to the second power bus. According to the second embodiment of the invention, the technical result is achieved in that in the electric disperatorizer new is that, unlike the first embodiment, one end of the secondary winding of the high voltage transformer is connected to a grounding device, and the other end of the secondary winding of the high voltage transformer is connected to high voltage contact electrodes.

The combination of two technical solutions in one application is due to the fact that both of the claimed devices solve the same problem, consisting in simplifying the design of an electric disinfestator and increasing its operational characteristics, in the same way with the same result.

The drawings show: a block diagram of an electric disinfestator (figure 1); circuit diagram of a source of high voltage pulses (figure 2); circuit diagram of the alarm device (figure 3); voltage diagrams on the elements of the device (figure 4).

The electric disruptor contains high voltage contact electrodes 1 and 2, they are connected to a source of high voltage pulses 3, which, together with the signaling device 4, is powered from the primary current source 5.

The source of high-voltage pulses 3 contains a high-voltage transformer 6, a pulse generator, consisting of an energy-storage capacitor 7 and an electronic switch 8, including a dinistor 9 and a diode 10, a charging circuit, consisting of a current-limiting capacitor 11, two diodes 12, 13 and an inductor 14, and a bus power supply 15, 16, which using a two-pole contactor 17 are connected to the primary current source 5 - single-phase network 220 V, 50 Hz.

The high-voltage transformer 6 has a steeply falling characteristic, the high-voltage terminals of its secondary winding are connected to the high-voltage contact electrodes 1 and 2. The high-voltage contact electrodes 1 and 2 are spaced and designed to deratize different zones of one room or are located in different rooms, so that in any case exclude the possibility of simultaneous contact of two electrodes. The primary and secondary windings of the high voltage transformer 6 are electrically isolated from each other. The primary winding of the high voltage transformer 6 is connected by its findings to the pulse generator. The first terminal of the primary winding is connected to the first lining of the energy storage capacitor 7, and the second terminal to the anode of the electronic key 8. The second lining of the energy storage capacitor 7, the cathode of the electronic key 8 and the anode of the diode 12 are interconnected and connected to the power bus 15. The cathode of the diode 12, the anode of the diode 13 and the first plate of the current-limiting capacitor 11 are connected to each other, the second plate of the current-limiting capacitor 11 is connected to the power bus 16. The inductor 14 is connected to the first terminal the cathode of the diode 13 and the second output - to the first terminal of the primary winding of high voltage transformer 6 and the first plate of an energy storage capacitor 7. The anode 8, the electronic key is an anode of the diode 10 connected to the anode dynistor cathode 9, the cathode of which is the cathode 8 of the electronic key.

The alarm device 4, as well as the personnel safety device of the prototype, is not a necessary unit of an electric disinfector in its functional purpose. It is intended to alert personnel that the electric disinfector is in the on state. Notification is carried out by visual and (or) acoustic impact on the senses. Figure 3 presents a schematic electrical diagram of a variant of the device visual alarm signals. The alarm device 4 contains a stabilized DC source, including a diode bridge 18 connected by an diagonal of alternating current through a current-limiting capacitor 19 to the power supply buses 15, 16, a filter capacitor 20 and a zener diode 21, and a bright blinking LED 22 as a load. The first lining of the filtering capacitor 20, the cathode of the zener diode 21 and the anode of the LED 22 are connected to the plus terminal of the diode bridge 18, and the second lining of the filtering capacitor 20, the anode of the zener diode 21 and the cathode of LED 22 are connected to the negative terminal of the diode bridge 18.

As an acoustic signaling device, a standard device can be used: an audio frequency generator, a siren, an alarm device, etc. [cm. for example: Count R. Electronic circuits: 1300 examples. M .: Mir, 1989, 688 p.].

Electric disinfectant works as follows. When the contactor 17 is closed, power supply buses 15, 16 are supplied with voltage from the primary current source 5 - electrical network 220 V, 50 Hz. Figure 4 shows the following dependences of the voltage on time on the elements of the device: U ₅ - voltage of the primary current source 5; U ₇ is the voltage across the energy storage capacitor 7 in two different time scales; U ₁ and U ₂ - voltage on the high voltage contact electrodes 1 and 2.

The energy storage capacitor 7 is charged from the primary current source 5 according to the voltage doubler circuit for diodes 12, 13 and capacitors 7, 11. When a half-wave of negative polarity is applied, the capacitor 11 is charged through diode 12. When a half-wave of positive polarity is applied, diode 13 is open and the charge of the capacitor 7. In this case, the charging current flows through the capacitor 11, the diode 13 and the inductor 14. When the positive voltage on the capacitor 7 rises to a value equal to the voltage On the _{other hand} , the electronic switch 8 U _{cf.8 is activated} , the last opens (at time t _cf.8 ) and the capacitor 7 is discharged through the primary winding of the high-voltage transformer 6 and electronic key 8. The discharge process is oscillatory in nature. During the recharging of the capacitor 7 to the reverse polarity (τ ₁ ~ 0.1 ms), a half-wave of current of positive polarity is formed in the primary winding of the high-voltage transformer 6, and high-voltage pulses are induced in the secondary winding of the high-voltage transformer 6 and fed to the high-voltage contact electrodes 1 and 2.

When the current decreases to zero, the electronic key 8 is locked (at time t is _locked . ₈ ). At the same time, the diodes 12, 13 open and the capacitor 7 is discharged again, but now through the inductor 14 and the diodes 12, 13. The discharge process is also oscillatory in nature, however, the recharge time of the capacitor 7, which is determined in this case by the inductance values of the coil 14 and the capacitance of capacitor 7 is τ ₂ ~ 1 ms. As a result, the capacitor 7 is charged to a positive voltage slightly lower than the response voltage of the electronic switch 8 U _crab. , and then it is recharged from the primary current source 5.

Since the reverse recovery time of modern dinistors is too long (tens of microseconds), in order to prevent the reverse current from flowing through the dinistor 9, a diode 10 with a short reverse recovery time (fractions of a microsecond) is included in series with the dinistor 9. In this case, the response voltage of the electronic switch 8 U _cf.8 is determined by the sum of the unlocking voltage of the dynistor 9 and the direct voltage of the diode 10.

Good performance of the circuit is obtained when the ratio of the capacitor recharge times 7 τ ₁ and τ _{2 of the} order of 1:10, which corresponds to the ratio of the inductances of the primary winding of the transformer 6 and the coil 14 of the order of 1: 100. By varying the value of the capacitance of the current-limiting capacitor 11, it is possible to change the charge rate of the energy-accumulating capacitor 7 and this can control the repetition frequency of high-voltage pulses over a wide range - from one pulse during several periods to two pulses during one half-cycle of the mains voltage. Thus, it is possible to select the most optimal operating mode of the electric disinfestator for various specific applications.

In contrast to the prototype circuit, in which an electric charge is transferred during the operation of high-voltage pulses between a high-voltage contact electrode (a group of equipotential high-voltage contact electrodes) and the Earth, with which there is a galvanic connection, in the inventive device, an electric charge is transferred between two electrodes (two groups of high-voltage contact electrodes) 1 and 2. Effective electrical effects on rodents, the electric capacity of the body of which is Work feed picofarads, is provided at the electrical capacity of each electrode few tens of picofarads. At the same time, the electrical effect on a person whose electric capacity of the body is comparable with the electric capacity of the electrode (tens of picofarads) is less powerful than that of the prototype, due to the significant increase in the current-limiting effect of the small, in comparison with the electric capacity of the Earth, electric capacity of the electrode.

A variant of the electric disperatorizer is also a design in which one of the ends of the secondary winding of the high voltage transformer 6 is connected not to the high voltage contact electrodes 1 or 2, but is grounded, i.e. connected to a grounding device. However, it should be borne in mind that in this case, the strength of the electrical impact on a person is about the same as that of the prototype. This option of an electric disinfector is not recommended for use in rooms with conductive floors.

The alarm device 4 is turned on when voltage is supplied to the power supply bus 15, 16 from the primary current source 5. The filter capacitor 20 is charged from the primary current source 5 through a circuit consisting of a current-limiting capacitor 19 and a diode bridge 18 as a half-wave rectifier in a bridge circuit. The capacitor 20 is charged to the stabilization voltage of the zener diode 21. The LED 22 begins to emit light pulses with a repetition rate of the order of 1 Hz, which notify personnel that the electric disinfector is turned on and high-voltage contact electrodes 1 and 2 are under high voltage.

If the alarm device is an acoustic impact device, then it starts to give alarm sound signals.

Example.

The following components are used in the source of high-voltage pulses 3. The high-voltage transformer 6 is made on a ferrite U-shaped core of the brand 2500 НМС1 PK38 × 14, the transformation coefficient is 100, the voltage on the primary winding is 300 V, on the secondary winding is 30 kV. As capacitors 7, 11, KBG-MP-600 V-0.5 μF ± 5% and K73-9-400 V-0.15 μF ± 10% capacitors were used, respectively, as a dynistor 9, a K3000F1 type dynistor manufactured by the company was used Littelfuse, as a diode 10, a diode of the type KD411BM was used, as diodes 12, 13, diodes of a rectifier block of the type KTs405A were used, an inductor of the type D34-0,08-1,4 was used as an inductor 14, a type changeover switch was used as a contactor 17 TV 1-1. The repetition rate of high voltage pulses is 50 Hz.

In the alarm device 4, the following components are used. A rectifier block of type KTs405I was used as diode bridge 18, capacitors of types K73-9-400 V-0.15 μF ± 10% and K53-21-16 V-220 μF ± 20%, respectively, were used as capacitors 19, 20, respectively As a Zener diode 21, a KS456A type zener diode was used, as an LED 22, an ultra-bright flashing red LED of the glow type L-796BSRC-B manufactured by Kingbright was used.

Thus, in comparison with a device for a similar purpose (prototype), the claimed device has several advantages:

- a simpler power supply system, since the control unit is not required in the high-voltage pulse source circuit;

- it is possible to control the repetition frequency of high voltage pulses by changing the nominal capacitance of the current-limiting capacitor in the source of high voltage pulses;

- the voltage of the high voltage pulses on the high voltage contact electrodes does not depend on the instability of the voltage of the primary current source - the network 220 V, 50 Hz;

- the absence of a network overload of 220 V, 50 Hz while simultaneously connecting a large number of deratizers, since the electricity consumption from the network comes from half-waves of current of both polarities;

- a higher degree of fire safety, since there are no resistors in the electrical circuit of the deratizer and, therefore, there is no heat emission in them;

- higher efficiency of the electric disinfestator, since there are no inefficient heat losses in the resistors;

- a higher degree of electrical safety of personnel, as

1) high-voltage contact electrodes are galvanically isolated from the primary current source - a single-phase network 220 V, 50 Hz;

2) the electrical effect on a person with high-voltage pulses is weaker than that of the prototype, due to a significant increase in the current-limiting effect of the small, in comparison with the electric capacity of the Earth, electric capacity of a high-voltage contact electrode;

3) there is an alarm device that turns on at the same time as voltage is supplied to the power bus from the primary current source, which is carried out manually;

4) the spontaneous inclusion of an electric disruptor is excluded.

Claims (6)

1. An electric disinfector containing high voltage contact electrodes that are connected to a high voltage pulse source, consisting of a charging circuit, two power buses, a high voltage transformer and a pulse generator, including an energy storage capacitor and an electronic switch, and powered from a primary current source, characterized in that the primary and secondary windings of the high voltage transformer are galvanically isolated from each other, to both ends of the secondary windings of the high voltage transformer and high-voltage contact electrodes are connected, the electronic switch has two electrodes, the pulse generator is supplied from the primary current source from half-waves of current of both polarities using a charging circuit consisting of a current-limiting capacitor, two diodes and an inductor, while the cathode of the first diode and the anode of the second diode and the first lining of the current-limiting capacitor are interconnected, the inductor is connected by the first output to the cathode of the second diode, its second output, the first output of the primary the windings of the high voltage transformer and the first lining of the energy storage capacitor are interconnected, the second terminal of the primary winding of the high voltage transformer is connected to the anode of the electronic key, the anode of the first diode, the second lining of the energy storage capacitor and the cathode of the electronic key are interconnected and connected to the first power bus, the second lining of the current-limiting capacitor connected to a second power bus. 2. The electric disperatorizer according to claim 1, characterized in that the electronic key is made of a dynistor and a diode connected in series. 3. The electric disinfector according to claim 1, characterized in that it is equipped with an alarm device that is turned on simultaneously with the electrical disinfestator. 4. An electric disruptor containing high voltage contact electrodes that are connected to a high voltage pulse source, consisting of a charging circuit, two power buses, a high voltage transformer and a pulse generator including an energy storage capacitor and an electronic switch, and powered from a primary current source, characterized in that the primary and secondary windings of the high voltage transformer are galvanically isolated from each other, one end of the secondary winding of the high voltage transformer with it is single with a grounding device, and the other end of the secondary winding of the high-voltage transformer is connected to high-voltage contact electrodes, the electronic key has two electrodes, the pulse generator is supplied from the primary current source from half-waves of current of both polarities using a charging circuit consisting of a current-limiting capacitor, two diodes and inductors, while the cathode of the first diode, the anode of the second diode and the first lining of the current-limiting capacitor are interconnected, the inductor ktivnosti is connected by the first terminal to the cathode of the second diode, its second terminal, the first terminal of the primary winding of the high voltage transformer and the first lining of the energy storage capacitor are interconnected, the second terminal of the primary winding of the high voltage transformer is connected to the anode of the electronic key, the anode of the first diode, the second lining of the energy storage capacitor and the cathode the electronic key are interconnected and connected to the first power bus, the second lining of the current-limiting capacitor is connected Connects to a second power bus. 5. The electric disperatorizer according to claim 1, characterized in that the electronic key is made of a dynistor and a diode connected in series. 6. The electric disinfector according to claim 1, characterized in that it is equipped with an alarm device that is turned on simultaneously with the electrical disinfestator.

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