RU872U1 - Standalone spark gap - Google Patents

Abstract

1. An autonomous spark gap containing a cylindrical body of dielectric material having a working part and a handle, between which a spacer ring is installed with a switch with a normally open contact placed on it, discharge electrodes mounted on the end of the working part of the housing, and a battery located inside the housing , a pulse voltage source and a step-up transformer, the secondary winding of which is connected to the discharge electrodes, characterized in that it is charged the device is connected through an additionally introduced normally closed contact of the switch to the battery, the pulse voltage source is made in the form of a symmetric multivibrator and a transistor switch, and the output of the symmetric multivibrator through a limiting resistor is connected to the input of the transistor switch, the output of which through the protective diode is connected to the primary winding of the boost transformer. 2. The arrester according to claim 1, characterized in that the charger contains a diode bridge, one of the pairs of diagonal terminals of which is connected directly to the input pin contacts and through a parallel connected capacitor with a resistor, the other pair of diagonal terminals of the diode bridge is connected directly to the corresponding poles of the battery and through a normally closed contact of the switch, respectively, while the input pin contacts of the charger are located at a closed removable roof the edge of the handle of the housing. 3. The spark gap according to claim 1, characterized in that in the load circuit of one and trans

Description

Stand-alone spark

The utility model relates to high voltage spark gaps and can be used to create personal protective equipment, as well as in electrotherapy.

A self-contained spark gap, comprising a housing of dielectric material, an electric battery placed in the housing, a high voltage pulse generating circuit connected to it, comprising a first step-up transformer, a pulse generator and a charging capacitor, the discharge circuit of which includes an internal spark gap, a second step-up transformer, the primary winding of which is connected in series with the internal spark gap, and the secondary winding is connected to the discharge electrodes, size even on the working end of the case, on the outer surface of which in the area of the handle there is a start button / see patent US 4873609, IPC Н05С 1/04, ЗР41В 15/04, 1989 /,

The disadvantage of this known device is associated with the presence of an internal spark gap, the features of the design and operation of which determine the creation of excess moisture inside the housing, leading to corrosion of the elements of the electrical circuit of the arrester and its premature failure. In addition, the use of an internal spark gap limits the electric discharge power achievable at the discharge electrodes and, therefore, reduces the efficiency of the arrester as a whole.

IPC: ЗР41В 15 / 04t A61A / 1/38

electric batteries, an electronic circuit for generating high voltage pulses, containing a pulse generator, a first step-up transformer, a charging capacitor, two series-connected internal spark gaps, the first of which is connected parallel to the charging capacitor, and the second parallel to the primary winding of the second step-up transformer, secondary winding which is connected to the discharge electrodes placed on the working end of the housing, on the outer surface of which in the area of the handle placed start button / see US patent L 4872084, IPC Н01Т 14/00, 1989 /,

Replacing the internal spark gap with two series-connected internal spark gaps in a sealed design allows to increase the reliability of the device and thereby increase its service life. However, the electrical circuit of the known arrester is relatively complex, due to the presence of two stages of voltage increase, two specially made internal arrester designed for different operating voltages, which result in additional difficulties in setting and adjusting the electric parameters of the arrester, complicating the technology of its manufacture. The presence of two high-voltage transformers leads to an increase in the dimensions and mass of the device. The execution form of the known arrester in some cases may not be optimal if it is necessary to manipulate the arrester at a sufficient distance from the target.

Also known is a self-contained spark gap, adopted for the prototype, containing a cylindrical body made of dielectric material having a working part and a handle, between which a spacer ring is installed with a switch with a normally open contact placed on it, discharge electrodes mounted on the end of the working part of the housing, and placed inside the housing a rechargeable battery recharged using a stand-alone charger connected to the outlet of the connector located on the ring, a pulse voltage source, two step-up transformers with different and transformation coefficients, the secondary winding of one of which is loaded on the discharge electrodes / see patent (W No. 4486807, IPC Р41В 15/04, 1984 /. The disadvantages of the prototype device include relatively large dimensions and weight, inconvenience of use associated with the need to use an additional unit - an autonomous charger, low efficiency of voltage conversion, resulting in unsatisfactory electrical the characteristics of a known arrester. The objective of the utility model is to create an autonomous spark gap, free from the above disadvantages. The technical result achieved in this case is to improve the electrical parameters and increase the reliability of operation while reducing the dimensions and mass of the arrester. The specified technical result is achieved by the fact that in an autonomous spark gap containing a cylindrical body made of dielectric material having a working part and a handle, between which a dividing ring is installed with a switch with a normally open contact placed on it, discharge electrodes mounted on the end of the working part of the housing, and a battery located inside the housing, a pulse voltage source and a step-up transformer, the secondary winding of which is connected to the discharge ele By means of cathodes, a charger is connected, connected via an additionally introduced normally closed contact of the switch to the battery, the pulse voltage source is made in the form of a symmetric multivibrator and a transistor switch, and the output of the symmetric multivibrator through a limiting resistor is connected to the input of the transistor switch, the output of which is connected through a protective diode to primary winding of step-up transformer.

The charger contains Pjost, one of the pairs of diagonal terminals of which is connected to the input pin contacts directly and through a parallel connected capacitor with a resistor, respectively, and the other pair of diagonal terminals of the diode bridge is connected to the corresponding poles of the battery directly and through the normally closed contact of the switch, respectively, and input pin contacts are located at the end of the housing handle closed with a removable cover

In addition, a variable resistor can be included in the load circuit of one of the transistor cascades of a symmetric multivibrator, and the transistor switch can be made in the form of series-connected first and second transistor stages, made according to a common emitter circuit, and the collector of the second transistor stage on a high-power composite transistor connected to a protective diode.

In this case, each of the discharge electrodes can be made in the form of a pointed pin with cylindrical grooves, one of them is located in the center of the working end of the housing and connected to the first output of the step-up transformer, and the remaining discharge electrodes are located at the same distance from each other on the circumference of the concentric axis central electrode, and connected to the second terminal of the step-up transformer

.different, distinguishing a utility model from a prototype, include the implementation of a pulsed voltage source, the introduction and implementation of a charger and the features of the discharge electrodes. This simplifies the electrical circuit of the device, eliminates the need for a two-stage voltage increase and the associated large-sized circuit elements. At the same time, the indicated embodiment of the pulse voltage source allows, without any additional transformations, to ensure the formation of a pulse sequence with optimal parameters / with a given duration, repetition rate, required edge steepness /, which allows to increase the efficiency converting the voltage of the primary power source to a high pulse voltage and maximize the power in the secondary winding of the step-up transformer. At the same time, ease of installation and adjustment of the parameters of the electric circuit of the arrester is provided. The built-in charger and the features of its implementation provide without additional increase in the dimensions of the arrester, due to the rational choice of circuit components and their compact placement, the arrester’s continuous operation with high reliability and efficiency of its operation. The utility model is illustrated by an example of its implementation, illustrated by the drawings. Figure 1 presents a General view of an autonomous spark gap, figure 2 - its circuit diagram. As shown in figure 1, a self-contained spark gap contains a housing 1 in the form of a cylinder made of dielectric material, for example, fiberglass, having a working part 2 and a handle 3, between which there is a dividing ring 4 with a start button 5 and a lock 6. Start button 5 is a switch with normally open and normally closed contacts / (

At the working end of the housing 1 there are installed discharge electrodes, a central electrode 7 and side electrodes 8. Each of the discharge electrodes 7.8 has the shape of a pin with a groove on a cylindrical surface. The central electrode 7 is connected to the first terminal, and the side electrodes 8th are the second terminal of the step-up transformer (not shown in FIG. 1). The opposite end of the housing 1 on the side of the handle 3 is closed by a removable cover 9, secured with an eccentric screw 10, which also serves to fasten the belt loop 11.

In the housing 1 there are elements of the electric circuit of the spark gap / Fig.2/. The charger 12 includes a bridge rectifier on diodes VD 1 + VD4, one pair of diagonal leads of which are connected to the input pin contacts directly and through parallel-connected capacitor 01 and resistor R1, respectively. The input pin contacts are closed by a removable housing cover 9, which is removed when the charger is connected to the network. Another pair of diagonal terminals of the rectifier is connected to the € 11 battery directly and through the normally closed contact of switch Ј1.

The pulse voltage source contains a pulse generator 13, made according to the scheme of a symmetric multivibrator on transistors VT1, YT2, capacitors C2.C3, resistors E2 + WB; the limiting resistor R7 and the transistor switch 14, made on transistors TK, VT4 and resistor K8, connected through a protective diode 5 to the primary winding of the step-up transformer Tpl, the secondary winding of which is connected to the discharge electrodes.

Autonomous spark spark gap works as follows.

The battery € 1 through a normally closed contact of the switch 51 is connected to the circuit of the charger 12. When you turn on the charger 12 in the network / cover 9 is removed /. Charging current flows through the battery, which ensures that the battery is charged when the arrester is inoperative. When you press the switch 5 / with the unlocked lock 6, FIG. L / the battery € 1 is disconnected from the charger 12, after which the supply voltage is supplied to the pulse generator 13, the transistor switch 14 and one of the terminals of the primary winding of the transformer Tpl by closing a normally open contact switch 51. The pulse generator 13, made according to the scheme of a symmetric multivibrator, generates pulses, the duration of which is set by the elements C2, R5. The pulse repetition rate is determined by the elements of SZ, R3, R4 and can be changed using a variable resistor VZ. Through the limiting resistor R7, the signal of the pulse generator 13 is supplied to the transistor switch 14 on the transistors VT3, VT4. Resistor P8 limits the collector current of the UTZ transistor, keeping it open. The load of the VT3 transistor is the base-emitter junction of the powerful composite transistor VT4, which allows switching large currents. The high switching speed of the YT4 transistor and the low primary impedance of the primary winding of the step-up transformer Tpl lead to the appearance in it of self-induction EMF of increased amplitude compared to the prototype. In this case, an EMF is induced in the secondary winding, which ensures the occurrence of a spark discharge between the discharge electrodes 7.8. When touching or approaching a distance of less than half the distance between the central 7 and any of the lateral 8 discharge electrodes to the object of influence, the latter experiences the effect of electric shock. The above described embodiment of the electrodes 7.8 causes the formation of a discharge at the ends of the electrodes, which eliminates. the possibility of breakdown on the case and, as a result, increases the mechanical strength, i.e. reliability of the arrester. The indicated arrangement of the electrodes 8 is symmetrical with respect to the central electrode 7, which optimizes the shape of the discharge from the point of view of the accompanying optical and acoustic effects. In addition, with the indicated location of the discharge electrodes, their connection with the elements of the device’s electrical circuit is most easily realized, because eliminates the need to create and isolate additional conclusions, reduces the risk of internal breakdowns and ultimately increases the electrical and mechanical strength of the device An example of a specific implementation of an autonomous spark gap. The voltage of the primary power source / battery / 9 V. Dimensions: length 250 mm, diameter 31 mm. Weight is not more than 350 g. The frequency of repetition of discharge pulses from 25 Hz to 500 Hz. The duration of the discharge pulses is 0.5 ms. Discharge current 5+ 7 mA. The maximum output voltage between the discharge electrodes is at least 45 kV.

Claims (5)

1. An autonomous spark gap containing a cylindrical body of dielectric material having a working part and a handle, between which a spacer ring is installed with a switch with a normally open contact placed on it, discharge electrodes mounted on the end of the working part of the housing, and a battery located inside the housing , a pulse voltage source and a step-up transformer, the secondary winding of which is connected to the discharge electrodes, characterized in that it is charged the device is connected through an additionally introduced normally closed contact of the switch to the battery, the pulse voltage source is made in the form of a symmetric multivibrator and a transistor switch, and the output of the symmetric multivibrator through a limiting resistor is connected to the input of the transistor switch, the output of which is connected via a protective diode to the primary winding of the boost transformer. 2. The arrester according to claim 1, characterized in that the charger contains a diode bridge, one of the pairs of diagonal leads of which is connected to the input pin contacts directly and through parallel connected capacitor with a resistor, respectively, the other pair of diagonal leads of the diode bridge is connected to the corresponding poles of the battery batteries directly and through a normally closed contact of the switch, respectively, while the input pin contacts of the charger are located at a closed removable to yshkoy end of the handle body. 3. The arrester according to claim 1, characterized in that a variable resistor is included in the load circuit of one and the transistor stages of the symmetric multivibrator. 4. The arrester according to claim 1, characterized in that the transistor switch is made in the form of series-connected first and second transistor stages made in accordance with a common emitter circuit, while the collector of the second transistor stage on a powerful composite transistor is connected to a protective diode. 5. The spark gap according to claim 1, characterized in that each of the discharge electrodes is made in the form of a pointed pin with grooves on its cylindrical surface, one of them is located in the center of the working end of the housing and connected to the first output of the step-up transformer, and the remaining discharge electrodes are located at the same distance from each other on a circle concentric with the axis of the central electrode, and are connected to the second terminal of the step-up transformer.