RU221473U1 - SINGLE POLE HIGH VOLTAGE INDICATOR WITH BUILT-IN TEST DEVICE - Google Patents

Abstract

The utility model relates to devices for indicating and measuring voltage, in particular to voltage indicators designed to determine the presence/absence of operating and induced voltage on the wires of overhead power lines, contact wires of electrified railways and live parts of other electrical installations. The essence of the claimed solution is that in a single-pole high voltage indicator containing a working part of the indicator, an insulating part of the indicator and a handle, which is separated from the insulating part of the indicator by means of a restrictive ring, and the working part of the indicator is equipped with a contact tip and a voltage presence indicating unit, the input which is connected to the tip contact, a test alternating voltage generator is inserted into the working part of the indicator, the output of which is connected to the tip contact, and the test alternating voltage generator is equipped with a switch. The technical result of the implementation of the claimed solution is the creation of a single-pole high-voltage indicator with a built-in testing device, which ensures increased reliability of determining the presence or absence of operating and induced voltage, as well as expanded functionality of the indicator. 3 salary f-ly, 3 ill.

Description

The utility model relates to devices for indicating and measuring voltage, in particular to voltage indicators designed to determine the presence/absence of operating and induced voltage on the wires of overhead power lines, contact wires of electrified railways and live parts of other electrical installations.

A device is known for signaling a dangerous approach to live parts of electrical installations, containing a series-connected antenna, a threshold element, a differentiating circuit, a monovibrator, a rectifying diode connected by the cathode to the output of a storage capacitor, an alarm unit and a serviceability control key (Patent for invention RU 2042996 C1. Device for signaling a dangerous approach to live parts of electrical installations MPK: N02N 5/12) [1].

The disadvantage of the known device is the absence of an insulating part and a handle necessary to determine both the presence and absence of high voltage. In addition, when the serviceability control key is closed, the functionality of only part of the electronic circuit of the alarm is checked.

The closest to the proposed technical solution (prototype) is a voltage indicator 6-10 kV UVNI-10, containing a working part of the indicator, an insulating part of the indicator and a handle separated from the insulating part of the indicator by means of a restrictive ring, and the working part of the indicator is equipped with a contact tip and a block indication of the presence of voltage, the input of which is connected to the tip contact, and the voltage presence indication unit is equipped with a light indicator (Gusev Yu.N., Ushanov V.P. and Chesnokov N.M. Safety equipment and devices for work in electrical installations. M.: - Energoatomizdat, 1988, pp. 12-15) [2].

The disadvantages of the known device are the inability to check the serviceability of the voltage indicator, as well as the lack of acoustic indication of the presence of voltage, which significantly reduces the reliability of checking the absence and presence of voltage on live parts of an electrical installation.

The objective of the proposed utility model is to create a single-pole high-voltage indicator with a built-in testing device, providing increased reliability in determining the presence or absence of operating and induced voltage, as well as expanding the functionality of the indicator.

The problem is solved due to the fact that in a single-pole high voltage indicator with a built-in testing device, containing a working part of the indicator, an insulating part of the indicator and a handle, which is separated from the insulating part of the indicator by means of a restrictive ring, and the working part of the indicator is equipped with a contact tip and a presence indicating unit voltage, the input of which is connected to the tip contact, a first gas-discharge lamp, a second gas-discharge lamp and a high-voltage test alternating voltage generator, the output of which is connected to the tip contact through the second gas-discharge lamp, are introduced into the working part of the indicator, and the high-voltage test alternating voltage generator is equipped with a switch, and the input of the voltage presence indication unit is connected to the tip contact through the first gas-discharge lamp. In addition, the voltage presence indication unit contains a first galvanic power source, an electronic voltage presence detection unit and an optical indicator, the input of which is connected to the output of the voltage presence detection electronic unit, the input of which forms the input of the voltage presence indication unit, the power pins of the voltage presence detection electronic unit are connected with the terminals of the first galvanic power source, the high-voltage alternating voltage test generator contains a second galvanic power source connected by its output to the output of the first galvanic power source, and a self-oscillator with an output step-up transformer, the output of which forms the output of the high-voltage alternating voltage test generator, the power output of the autogenerator with the output The step-up transformer is connected to the second galvanic power source through a switch, which is made in the form of a controlled contact with a mechanical drive. In addition, the voltage presence indication unit contains a first galvanic power source, an electronic voltage presence detection unit and an optical indicator, the input of which is connected to the output of the voltage presence detection electronic unit, the input of which forms the input of the voltage presence indication unit, the power pins of the voltage presence detection electronic unit are connected with the terminals of the first galvanic power source, the high-voltage alternating voltage test generator contains a second galvanic power source connected by its output to the output of the first galvanic power source, and a self-oscillator with an output step-up transformer, the output of which forms the output of the high-voltage alternating voltage test generator, the switch is designed as a magnetically controlled contact through which the power output of the autogenerator with the output step-up transformer is connected to the second galvanic power source. In addition, the first part of the housing is equipped with a window for optical indication of the presence of voltage and a shade with a reflector that directs the optical flow towards the handle.

The introduction of a test alternating voltage generator into the working part of the indicator, connected by the output to the tip contact, ensures the serviceability of all electronic components and all electrical connections of the indicator, thereby increasing the reliability of checking the presence and absence of voltage on live parts of the electrical installation.

Supplying a high-voltage alternating voltage test generator with a switch, for example, in the form of a controlled contact connected in series between the output of a self-generator with an output step-up transformer and a tip contact, helps prevent false operation of the pointer when checking the presence and absence of voltage on live parts of an electrical installation.

The introduction of the first gas-discharge lamp into the working part of the indicator, connected in series between the input of the voltage presence indicating unit and the tip contact, provides an indication of the presence of voltage in the event of a malfunction of the power source included in the voltage presence indicating unit, an electronic unit for determining the presence of voltage, or a light indicator; This increases the reliability of the pointer. In addition, the first gas-discharge lamp is a buffer element and protects the input circuits of the voltage presence indication unit from pulse overvoltages that occur at the tip contact when touching live parts, especially in emergency operating modes of the electrical installation, in particular, during single-phase ground faults.

The introduction of a second gas-discharge lamp into the working part of the indicator, connected in series between the output of the high-voltage test alternating voltage generator and the tip contact, provides an indication of the inclusion of the high-voltage test alternating voltage generator, which indicates the serviceability of the high-voltage test alternating voltage generator. This increases the reliability of the indicator and makes it easier to determine the presence of a fault in the voltage presence indicating unit. In addition, the second gas-discharge lamp is a buffer element and protects the input circuits of the high-voltage alternating voltage test generator from pulse overvoltages that occur at the tip contact when touching live parts, especially in emergency operating modes of the electrical installation, in particular, during single-phase ground faults.

Equipping the voltage presence indication unit with a light indicator ensures the formation of a visual signal of the presence of voltage on live parts of the electrical installation.

The design of a high-voltage alternating voltage test generator with an autonomous galvanic power source and a self-generator with an output step-up transformer connected to the power source through a controlled contact, for example, with mechanical or magnetic control, ensures a long service life of the voltage indicator without replacing power sources.

Constructing a high-voltage alternating voltage test generator with a switch in the form of a magnetically controlled contact ensures the tightness of the contact and, consequently, the durability and reliability of the switch, which is controlled using a special source of constant magnetic field.

Equipping the working part of the indicator with a window for optical indication of the presence of voltage and a shade containing a reflector ensures improved visibility of the light signal for the presence of voltage at a greater distance and in conditions of high illumination of the working area.

Figure 1 shows a single-pole high voltage indicator with a built-in testing device; Figure 2 shows a block diagram of a single-pole high voltage indicator with a built-in testing device, equipped with a light indicator and a controlled contact with a mechanical drive; Figure 3 shows a block diagram of a single-pole high voltage indicator with a built-in testing device, equipped with a light indicator and a magnetically controlled contact.

A single-pole high voltage indicator with a built-in testing device contains a working part 1 of the indicator, an insulating part 2 of the indicator and a handle 3, which is separated from the insulating part 2 of the indicator by means of a restrictive ring 4. The working part 1 of the indicator is equipped with a contact tip 5 and a voltage presence indication block 6 and the first gas-discharge lamp 7. Input 8 of the block 6 indicating the presence of voltage through a conductor 9 is connected to the contact-tip 5 through the first gas-discharge lamp 7. The working part 1 of the indicator is also equipped with a high-voltage alternating voltage generator 10 and a second gas-discharge lamp 11. Output 12 of the high-voltage generator 10 The test alternating voltage using conductor 13 is connected to the tip contact 5 through the second gas-discharge lamp 7. The high-voltage test alternating voltage generator 10 is equipped with a switch 14.

In a particular case of the design of the indicator, the voltage presence indication block 6 contains a first galvanic power source 15, an electronic voltage presence detection unit 16 and an optical indicator 17, the input of which is connected to the output of the voltage presence detection electronic unit 16, the power pins of which are connected to the terminals of the first galvanic source power supply 15. Input 8 of block 6 indicating the presence of voltage is formed by the input of the electronic unit 16 for determining the presence of voltage. The high-voltage test alternating voltage generator 10 contains a second galvanic power source 18, the output of which is connected to the output of the first galvanic power source 13, and a self-oscillator 19 with an output step-up transformer, the output of which forms the output 12 of the high-voltage test alternating voltage generator 10. The switch 14 is made in the form of a controlled contact 20 with a mechanical drive. The power output of the self-oscillator 19 with the output step-up transformer is connected to the second galvanic power source 18 through a controlled contact 20 with a mechanical drive.

In a particular case of the design of the indicator, the switch 14 is made in the form of a magnetically controlled contact 21, and the power output of the autogenerator 17 with an output step-up transformer is connected to the second galvanic power source 18 through a magnetically controlled contact 21.

In a particular case of the design of the pointer, the working part 1 of the pointer is made in a dielectric housing 22, which is equipped with a window 23 for optical indication of the presence of voltage and a shade 24 with a reflector 25 that directs the light flux towards the handle 3.

A single-pole high voltage indicator with a built-in test device works as follows.

Before determining the presence or absence of voltage on live parts of the electrical installation, switch 14 is switched to the “Off” state. To determine the presence or absence of voltage on live parts of an electrical installation, the worker holds the pointer by handle 3 and brings the working part 1 of the pointer closer to the live parts so that the contact tip 5 touches the live parts. The insulating part 2 of the indicator, together with the restrictive ring 4, protects the worker from electric shock. If there is voltage on the current-carrying parts, the electric potential from the tip contact 5 along the conductor 9 through the first gas-discharge lamp 7 is supplied to the input 8 of the voltage presence indication block 6, which generates a signal informing the worker about the presence of voltage.

As a result of contact-tip 5 touching current-carrying parts of the electrical installation that are energized, electric current flows from the contact of tip 5 through the first gas-discharge lamp 7 into the input circuits of the electronic unit 16 for determining the presence of voltage. The specified electric current flows both in the presence and in the absence or insufficient voltage at the power terminals of the electronic unit 16 for determining the presence of voltage, which can occur, for example, in the event of a malfunction (discharged state) of the first galvanic power source 15. As a result of the flow of electric current, the first gas-discharge lamp 7 begins to glow, thereby signaling the presence of voltage on live parts of the electrical installation. Thus, the first gas-discharge lamp 7 generates an additional optical signal, informing about the presence of voltage even if the voltage presence indication unit 6 is inoperative.

Checking the serviceability of the indicator is carried out in the absence of an electrical installation that is energized. To check the serviceability of the indicator, switch 14 is switched to the “On” state, which ensures the formation of a test alternating voltage at the output 12 of the high-voltage generator 10 of the test alternating voltage. The specified voltage is supplied through conductor 13 through the second gas-discharge lamp 11 to the contact tip 5, and then through conductor 8 through the first gas-discharge lamp 7 is supplied to the input 8 of the voltage presence indication block 6, which generates a signal informing the worker about the presence of voltage, which indicates the serviceability of all electronic components and all electrical connections of the indicator.

After the switch 14 is switched to the “On” state, the test alternating voltage from the output 12 of the high-voltage generator 10 of the test alternating voltage is supplied to the second gas-discharge lamp 11, and then through the conductor 13 it is supplied to the contact tip 5. From the contact tip 5, the voltage is supplied to the conductor 9 to the first gas-discharge lamp 7, and then to the input 8 of block 6 for indicating the presence of voltage. Under the influence of an alternating test voltage, an electric current flows through the second gas-discharge lamp 11, as a result of which it begins to glow, signaling the proper operation of the high-voltage alternating voltage test generator 10.

In a particular case of the design of the indicator, the voltage from input 8 of the voltage presence indication block 6 is supplied to the input of the electronic voltage presence detection block 16, which causes it to operate and generate a voltage presence signal at the input of the light indicator 17. Power supply of the voltage presence detection block 16 with the required voltage for its operation, provides the first galvanic power source 15. When a corresponding signal is received at the input of the block 16 for determining the presence of voltage, the optical indicator 17 generates a luminous flux, which enters through the window 23 in the tubular housing 22 to the reflector 25, directing the luminous flux towards the handle 3 such such that the optical voltage signal is visible to the worker. The shade 24 ensures sufficient visibility of the optical signal of the presence of voltage even at a high level of illumination of the working area.

In a particular case of the design of the pointer, the test alternating voltage at the output 12 of the high-voltage generator 10 of the test alternating voltage comes from a self-oscillator 19 with an output step-up transformer, which starts when its power output through a closed controlled contact 20 with a mechanical drive receives a constant voltage from the output of the second galvanic power source 18. The controlled contact 20 is closed by means of a mechanical drive when switch 14 is switched to the “On” state.

In a particular case of the design of the pointer, the test alternating voltage at the output 12 of the high-voltage generator 10 of the test alternating voltage is supplied from a self-generator 19 with an output step-up transformer, which is started when its power output through a closed magnetically controlled contact 21 receives a direct voltage from the output of the second galvanic power source 18 The closure of the magnetically controlled contact 21 is carried out under the influence of a magnetic field, which is created by using an external source, for example, a permanent magnet.

The creation of a test voltage at the output of the self-oscillator 19 with an output step-up transformer is carried out due to the built-in positive feedback [3]. In accordance with the requirements of GOST 20493-2001 [4], the indicator is triggered when the voltage at the tip contact 5 reaches 25% of the rated voltage of the electrical installation, which is 1500 V at a rated voltage of 6 kV. An alternating voltage sufficient to trigger unit 16 for determining the presence of voltage at the output of the self-generator 19 is provided by a built-in step-up transformer.

The operation of the block 16 for determining the presence of voltage when starting the autogenerator 19 with an output step-up transformer is ensured by the flow of alternating current through the circuit: output of the autogenerator 19 with an output step-up transformer, output 12 of the high-voltage generator 10 test alternating voltage, conductor 13, contact tip 5, conductor 9 , input 8 of block 6 indicating the presence of voltage, input of block 16 for determining the presence of voltage, power output of block 16 for determining the presence of voltage, power output of the self-generator 19 with an output step-up transformer.

In a particular case of design, when checking the serviceability of the indicator, the test alternating voltage at the output 12 of the high-voltage generator 10 of the test alternating voltage is supplied through a closed magnetically controlled contact 21 from the output of the autogenerator 19 with an output step-up transformer, the power terminals of which are constantly connected to the second galvanic power source 18.

Sources of information taken into account:

1. Patent for invention RU 2042996 C1. Device for signaling dangerous approach to live parts of electrical installations MPK: N02N 5/12.

2. Gusev Yu.N., Ushanov V.P. and Chesnokov N.M. Safety equipment and devices for work in electrical installations. - M.: Energoatomizdat, 1988, p. 12-15.

3. Golub B.C. Generators of harmonic oscillations. - M.: Energy, 1980. - 80 p. - (B-ka on radio electronics; Issue 69), p. 39, p. 42.

4. GOST 20493-2001. Voltage indicators. General technical conditions. Official publication. - Minsk: Interstate Council for Standardization, Metrology and Certification. 2004, p. 3.

Claims (4)

1. A single-pole high voltage indicator with a built-in testing device, containing a working part of the indicator, an insulating part of the indicator and a handle, which is separated from the insulating part of the indicator by means of a restrictive ring, and the working part of the indicator is equipped with a contact tip and a voltage presence indicating unit, the input of which is connected to tip contact, characterized in that a first gas-discharge lamp, a second gas-discharge lamp and a high-voltage test alternating voltage generator are introduced into the working part of the indicator, the output of which is connected to the tip contact through the second gas-discharge lamp, and the high-voltage test alternating voltage generator is equipped with a switch, and the input The voltage presence indicating unit is connected to the tip contact through the first gas-discharge lamp. 2. The voltage indicator according to claim 1, characterized in that the voltage presence indication unit contains a first galvanic power source, an electronic voltage presence detection unit and an optical indicator, the input of which is connected to the output of the voltage presence detection electronic unit, the input of which forms the input of the voltage presence indication unit voltage, the power terminals of the electronic unit for determining the presence of voltage are connected to the terminals of the first galvanic power source, the high-voltage alternating voltage test generator contains a second galvanic power source connected by its output to the output of the first galvanic power source, and a self-oscillator with an output step-up transformer, the output of which forms the output of the high-voltage test alternating voltage generator, the power output of the autogenerator with the output step-up transformer is connected to the second galvanic power source through a switch, which is made in the form of a controlled contact with a mechanical drive. 3. The voltage indicator according to claim 1, characterized in that the voltage presence indicating unit contains a first galvanic power source, an electronic voltage presence detection unit and an optical indicator, the input of which is connected to the output of the voltage presence detection electronic unit, the input of which forms the input of the voltage presence indicating unit voltage, the power terminals of the electronic unit for determining the presence of voltage are connected to the terminals of the first galvanic power source, the high-voltage alternating voltage test generator contains a second galvanic power source connected by its output to the output of the first galvanic power source, and a self-oscillator with an output step-up transformer, the output of which forms the output of the high-voltage test alternating voltage generator, the switch is made in the form of a magnetically controlled contact, through which the power output of the autogenerator with the output step-up transformer is connected to the second galvanic power source. 4. The voltage indicator according to claim 1, characterized in that the working part of the indicator is made in a dielectric housing, which is equipped with a window for optical indication of the presence of voltage and a shade with a reflector that directs the light flux towards the handle.

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