RU2750436C1 - Input and distribution device for critical electrical receivers - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to electrical engineering for the organization of power supply of critical electrical receivers with electrical energy from two independent mutually redundant three-phase network inputs with an isolated neutral. The device contains input modules, automatic transfer switch and distribution. Each of the two channels of the input module includes input connection blocks based on a sealed connector, surge arresters, insulation monitoring and an input power protective switching device. The automatic transfer switch module is connected to each of the two channels of the input module up to the input power protective switching devices through the impulse noise protection units made in the form of three linear impulse noise protection modules connected to the phase-to-phase voltages of the three-phase system, each of the modules consisting of composite bi-directional limiting diode, fuse, screened isolation transformer and capacitor. The distribution module is equipped with group power protective switching devices. The communication channel with the automated control system provides the transfer of data on the state of the device and the presence of voltage at the inputs to the automated control system of the technological process, as well as remote change of the position of the power protective switching devices and the parameters of the device.

EFFECT: increases stability of power supply to critical electrical receivers when exposed to overvoltage and pulsed electromagnetic interference.

2 cl, 2 dwg

Description

The invention relates to the field of electrical engineering, namely to the production, transformation and distribution of electricity, and can be used to supply power to critical electrical receivers with electrical energy from two independent mutually redundant three-phase network inputs with an isolated neutral.

Known input distribution device (ASU) of critical electrical receivers, containing blocks that provide the ability to input, distribution of electrical energy, as well as control and protection of outgoing group electrical circuits, which are placed in the form of appropriate functional modules: input, automatic switching on of the reserve, distribution, etc. etc. [one].

Such an ASU, in the event of power supply failures at the working input, automatically transfers the power supply of the critical electrical receivers to the backup input. At the same time, power supply disruptions, as a rule, are associated with the impact on the elements of the power supply system (SES) of atmospheric discharges, switching in power systems, etc., which are accompanied by overvoltages and pulse electromagnetic interference propagating through the SES and causing failures and ( or) failures of electronic devices of automation [2]. Therefore, the disadvantages of the considered ASU, on the one hand, are the absence of overvoltage and electromagnetic interference protection elements at the device inputs, which leads to a failure in automatic switching of sources, and on the other hand, the impossibility of remote monitoring and control of the operation process.

Of the known technical solutions, the closest to the proposed device is an input distribution device [3], which includes an input module containing two input channels, each of which contains series-connected input buses, three-phase protection and control devices, a distribution module equipped with protection and control devices which also has remote control and signaling circuits.

The disadvantage of this device, which we have taken as a prototype, is that, on the one hand, to provide protection against emergency modes, automatic switches are used that have limited capabilities to protect networks with isolated neutral, and on the other hand, there is no means of localizing overvoltages and electromagnetic interference, which leads to a decrease in the stability of the power supply of critical electrical receivers under destructive influences. In addition, the use of input busbars for connecting independent sources makes it difficult to replace power sources during operation.

The aim of the invention is to increase the stability of power supply to critical electrical receivers when exposed to overvoltages and pulsed electromagnetic interference, to simplify the replacement of power sources, as well as to expand the scope of the ASU.

This goal is achieved by the fact that in the input-distribution device having an input module containing two input channels with a three-phase protection and control device in each, a distribution module equipped with protection and control devices with remote control and signaling circuits, insulation resistance monitoring units and surge suppressors, and the automation circuits are made with linear surge protection modules based on a composite bidirectional limiting diode, an isolation transformer with a screen and a capacitor. In addition, instead of input buses, input connection blocks based on sealed connectors are used, which makes it possible to simplify the replacement of power sources.

The use of insulation resistance monitoring units in the power supply circuit of each input allows the use of an input-distribution device in networks not only with a solidly grounded neutral, but also with an isolated neutral, i.e. expands the scope of the device.

FIG. 1-2 shows a diagram of the proposed device.

It contains:

1 - the first independent input of three-phase alternating voltage;

2 - second independent input of three-phase alternating voltage;

3 - input module;

4 - module for automatic switching on of the reserve;

5 - distribution module;

6.1, 6.2 - responsible power consumers;

7 - communication channel with an automated control system;

8.1, 8.2 - connection block;

9.1, 9.2 - overvoltage arrester unit;

10.1, 10.2 - insulation control unit;

11.1, 11.2 - impulse noise protection unit;

12.1, 12.2 - input voltage control unit;

13 - power supply unit;

14 - automation unit;

15.1, 15.2 - introductory power protective switching device;

16 - buses of guaranteed power supply;

17.1, 17.2 - group power protective switching device;

18.1, 18.2, 18.3 - linear module for protection against impulse noise;

19 - composite bidirectional limiting diode;

20 - fuse;

21 - insulating transformer with a screen;

22 - capacitor.

The device works as follows.

The power supply of the automation unit 14 is carried out from the power supply unit 13, which is connected through two parallel (mutually redundant) channels, respectively, to the first independent input of three-phase alternating voltage 1, through the connection unit 8.1, the block of overvoltage arresters 9.1, the insulation resistance monitoring unit

10.1 and an impulse noise protection unit 11.1, as well as to the second independent input of three-phase alternating voltage 2, through a connection unit 8.2, a surge arrester unit 9.2, an insulation resistance monitoring unit 10.2 and an impulse noise protection unit 11.2.

In parallel with the first and second inputs of the power supply, the voltage from the first independent input of three-phase alternating voltage 1 and the second independent input of three-phase alternating voltage 2 is supplied to the inputs of the input voltage control units 12.1 and 12.2, respectively. Signals about the presence of voltage with the parameters required by the responsible electrical consumers from the input voltage control units 12.1 and 12.2 are sent to the automation unit 14.

In the presence of signals from two voltage control units of the input 12.1 and 12.2, the automation unit 14 issues a signal to turn on the input power protective switching device 15.1.

Power supply of critical electrical consumers 6.1 and 6.2 is carried out from the first independent input of three-phase alternating voltage 1 through connection block 8.1, overvoltage arrester block 9.1, insulation resistance monitoring unit, input power protective switching device 15.1, guaranteed power buses 16 and corresponding group power protective switching devices 17.1, 17.2.

When exposed to lightning, an overvoltage arises at the first independent input of three-phase alternating voltage 1, which flows through the connection block 8.1 to the overvoltage arrester block 9.1, where it is limited to the voltage level acceptable for the insulation of the electrical installation. In the 11.1 impulse noise protection unit, the voltage level is further reduced to the permissible for electronic automation devices using three linear impulse noise protection modules 18.1, 18.2 and 18.3, connected to three phase-to-phase voltages U _ab , U _bc , U _ca, respectively. At the first stage, the voltage level is reduced by means of a composite bidirectional limiting diode 19, at the second stage by means of an isolation transformer with a screen 21 and a capacitor 22 at the final stage. The use of isolation transformers 21 with a foil or wire shield connected to the housing minimizes the capacitive coupling between the primary and secondary windings of the transformer and, accordingly, attenuates the level of the transmitted overvoltage pulse. The use of the capacitor 22 allows the absorption of the pulse energy at the output of the transformer 14. In this case, overvoltages do not enter the input voltage control unit 12.1, the power supply 13 and the automation unit 14, and, accordingly, do not cause failures both in their own work and in the operation of the controlled equipment, and therefore do not violate the stability of the power supply of critical power consumers.

When exposed to pulsed electromagnetic interference, characterized by a large slope of the front, through the first independent input of three-phase alternating voltage 1, they enter through the connection block 8.1 into the overvoltage arrester block 9.1, however, due to the relatively long response time of the overvoltage arresters, they are at the first stage, until they are triggered are distributed further. In the 11.1 impulse noise protection unit, the voltage level is reduced using three linear impulse noise protection modules 18.1, 18.2 and 18.3, connected to three phase-to-phase voltages U _ab , U _bc , U _ca, respectively. At the first stage, the voltage level is reduced using a composite bidirectional limiting diode 19, at the second stage using an isolating transformer with a screen 21 and a capacitor 22 at the final stage, and limiting the emergency values of impulse currents is performed using a fuse 20. Use of isolating transformers 21 with a screen made of foil or wire, connected to the housing, minimizes the capacitive coupling between the primary and secondary windings of the transformer and, accordingly, attenuates the level of the transmitted pulsed electromagnetic interference. The use of capacitor 22 makes it possible to absorb the energy of the impulse noise at the output of the transformer 14. In this case, the impulse electromagnetic interference does not enter the input voltage control unit 12.1, the power supply unit 13 and the automation unit 14, and, accordingly, does not cause failures both in their own work and in operation controlled equipment, and therefore do not violate the stability of the power supply of critical power consumers.

If the voltage at the first independent input of three-phase alternating voltage 1 fails or its value deviates more than a predetermined level, the input voltage control unit 12.1 issues a corresponding signal to the automation unit 14, according to which the input power protective switching device 15.1 is turned off and the input power protective switching device is turned on. apparatus 15.2. In this case, the power supply of the critical electrical receivers 6.1 and 6.2 is carried out from the second independent input of three-phase alternating voltage 2 through the connection block 8.2, the overvoltage arrester block 9.2, the insulation resistance monitoring unit, the input power protective switching device 15.2, the guaranteed power bus 16 and the corresponding group power protective - switching devices 17.1, 17.2. The power supply of the automation unit 14 continues to be supplied from the power supply unit 13, which is connected to the second independent input of three-phase alternating voltage 2, through the connection unit 8.2, the overvoltage arrester unit 9.2, the insulation resistance monitoring unit 10.2 and the impulse noise protection unit 11.2.

When exposed to lightning or pulsed electromagnetic interference on the second independent input of three-phase alternating voltage, the device operates in the same way as when exposed to the first independent input of three-phase alternating voltage.

If it is necessary to replace independent sources of three-phase alternating voltage of electricity, it is carried out promptly, without complicated installation operations, by redoing inputs 1 or 2 on sealed connectors 8.1 or 8.2, respectively.

Through the communication channel with the automated control system 7, data on the state of the device and the presence of voltage at the inputs are transmitted to the automated control system of the technological process, and also there is a remote change in the position of the power protective switching devices and the parameters of the device.

Thus, the use of overvoltage arresters and impulse noise protection units as part of three linear impulse noise protection modules based on composite bidirectional limiting diodes, isolation transformers with a screen and capacitors, makes it possible to increase the stability of the power supply of critical electrical receivers when exposed to overvoltage and impulse electromagnetic interference organization of two power supply channels of the automation unit from different inputs additionally increases stability in case of power outages from one of the inputs, the use of insulation resistance monitoring units in the power supply circuit of each input expands the scope of the device on a network with an isolated neutral, the implementation of input connection blocks in the form of sealed connectors makes it easier replacement of electricity sources, and the introduction into the device of a communication channel with an automated control system allows remotely changing the parameters of the device and implementing control over his work.

The applicants do not know the way to solve the problem with the given set of essential features, which speaks of the "inventive step" of the technical solution.

The authors tested an input-distribution device with surge suppressors and impulse noise protection units based on composite bidirectional limiting diodes, isolating transformers with a screen and capacitors, which provided a stable power supply to critical electrical receivers when exposed to overvoltage and impulse electromagnetic interference.

The given data and information confirm the possibility of industrial implementation of the proposed invention.

Information sources

1. Tulchin I.K., Nudler G.I. Electrical networks and electrical equipment of residential and public buildings. - M .: Energoizdat, 1990 .-- 480 p.

2. Electromagnetic compatibility and lightning protection in the power industry. / A.F. Dyakov, B.K. Maximov, R.K. Borisov and others; ed. A.F. Dyakov. - M .: Publishing house. house MEI, 2011 .-- 544 p.

3. RF patent No. 2279746 C1, class. Н02В 1/00, Н02В 7/00, publ. 10.07.2006.

Claims (3)

1. Input-distribution device of critical electrical consumers, containing a series-connected input module, consisting of two channels with an input power protective switching device in each, and a distribution module equipped with group power protective switching devices with remote control and signaling circuits, characterized by the fact that that each channel of the input module additionally includes overvoltage suppressor and insulation monitoring units, and the automatic transfer switch included in the input module is connected to each of its channels up to the input power protective switching device through surge protection blocks made in the form of three linear impulse noise protection modules connected to phase-to-phase voltages of a three-phase system, each of the modules consists of a composite bidirectional limiting diode connected to the corresponding phase-to-phase voltage, connected in parallel to it through a fuse b the first winding of an insulating transformer with a screen, the second winding of which with a parallel connected capacitor is connected to the corresponding input phase-to-phase voltage, the input of the input control unit and the power supply unit, the automation unit. 2. The input distribution device of critical power consumers according to claim 1, characterized in that in each of the two channels of the input module, input connection blocks based on sealed connectors are used to simplify the replacement of power sources. 3. The input distribution device of critical electrical receivers according to claim 1, characterized in that it includes a communication channel with an automated control system for remotely changing the parameters of the device and monitoring its operation.

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