RU172228U1 - ELECTRIC DRIVE CONTROL DEVICE - Google Patents

Abstract

The switchgear control device belongs to the field of electrical engineering and can be used in signaling, centralization and blocking (SSC) devices in railway transport. The proposed utility model solves the problems of increasing reliability and manufacturability, as well as matching the outputs of the control of the plus and minus arrow positions with inputs for this information in the UVK microprocessor centralization EC-EM used in Russia. The increase in reliability and manufacturability is achieved through the use of only one secondary winding of the transformer and the use of only one DC source (station DC source). The coordination of the outputs of the plus and minus arrow positions with the inputs for this information in the UVK microprocessor centralization EC-EM used in Russia is achieved by the fact that the UVK terminal entering information about the positive position of the arrow is connected to the UVK terminal of the test of the make contact through the sequentially connected make contact of one repeater of the polarized starting parallel to which the NC contact of this one repeater is connected, connected to the UVK terminal of the NC contact test, series-connected NO contacts of one and the other unipolar relay control arrows, parallel to which respectively the NC contacts of one and the other unipolar relay control arrows connected to the UVK test terminal NC contacts, and the UVK terminal for inputting information about the negative position of the arrow is connected to the UVK terminal for the test of NC contacts through the last The normally open break contact of another repeater of the polarized start relay, in parallel with which is the make contact of this other repeater connected to the make contact of one repeater of the polarized start relay.

Description

The utility model relates to the field of electrical engineering and can be used in signaling, centralization and blocking devices (SSC) in railway transport.

A control device for a turnout electric drive is known, which contains three line wires, an electric drive with a three-phase electric motor and an automatic switch with control and working contacts, a polarized start relay and a neutral start relay with a hold winding and an excitation winding, a phase monitoring unit with terminals for connecting one, another and third phases of a three-phase AC, with one, another and third terminals for connecting a three-phase load and terminals for connecting a relay, a control computer lex (UVK) of microprocessor centralization with test terminals for making and breaking contacts and terminals for entering information about the plus and minus positions of the arrow, one and the other unipolar relay control switches with working windings and polarizing windings, in one of these unipolar relay control switches used an additional working winding, while this additional working winding is connected in series to the circuit of connecting one of the linear wires to a three-phase AC source, transformers, dio s, capacitors, resistors, DC sources, and the alternating three-phase alternating currents (see. one; 2, p. 7, Fig. 12.).

This device is adopted as a prototype as the closest to the proposed in its technical essence.

The disadvantages of the opposed device are the low reliability and manufacturability due to the use of a three-winding transformer, to one of the secondary windings of which a rectifier bridge is connected as an additional DC source with a resistor divider of this voltage, used along with a stationary DC battery, as well as inconsistency of the plus and the negative positions of the arrows with inputs for this information in the UVK microprocessor centralization EC-EM, used in Russia, which is why an additional adapter (two relays) is required to use the device in this centralization.

The task to which the present utility model is directed is to eliminate the indicated disadvantages of the opposed device. The solution to this problem is achieved by the fact that it contains one repeater of the polarized start relay, the winding of which is connected in series with the normally closed contact of the polarized start relay and a DC power supply, and another repeater of the polarized start relay, the winding of which is connected in series with the normally open contact of the polarized start relay and a DC power source, while one end of the parallel connected polarizing windings of one and the other is one The control relay of the arrow is connected to one pole of the DC power source through a series-connected make contact of one repeater of the polarized start relay, in parallel to which the disconnect contact of this one repeater is connected, connected to the other pole of the DC power source, and the other end of the parallel connected polarizing windings of one and another unipolar relay control switches arrows connected to the other pole of the DC power source through in series a closed NC contact of another repeater of the polarized starting relay, in parallel with which a NC contact of this other repeater is connected, connected to one pole of the DC power supply, while the UVK terminal for inputting information about the positive position of the arrow is connected to the UVK terminal of the test of the NO contact through series-connected NO contact of one a repeater of a polarized starting relay, in parallel with which an opening contact of this one repeater is connected, connected to by the UVK test of the NC contact test, the serially connected NO contacts of one and the other unipolar relay control arrows, in parallel to which the NC contacts of one and the other unipolar relay control arrows are connected, connected to the UVK terminal of the test of the NC contacts, and the terminal UVK of inputting information about the negative position of the arrow connected with the UVK terminal of the test of the NC contacts through a series-connected NC contact of another repeater of the polarized start relay, p which are parallel connected normally open contact of another repeater connected to the normally open contact one repeater polarized starter relay.

In the proposed device, an increase in reliability and manufacturability is achieved through the use of only one secondary winding of the transformer instead of two and the use of only one DC source (station battery) without the use of an additional DC source in the form of a rectifier bridge, as is customary in the opposed device.

In the proposed device, the control outputs of the plus and minus arrow positions are aligned with the UVK inputs for information on the plus and minus arrow positions of the EC-EM microprocessor centralization, which is provided by connecting the UVK terminals of the test contacts of the make contact to the UVK terminals for information about the plus and minus positions of the arrow with make contacts one and the other contact repeaters of the polarized start relay and the closing contacts of one and the other unipolar relay control arrows, as well as connecting the test signal terminals of the NC contacts to these UVK terminals by the NC contacts of all these relays. The proposed technical solution is new, because three-wire switchgear control devices are not known from the prior art, which contain one repeater of a polarized start relay, the winding of which is connected in series with a normally closed contact of a polarized start relay and a DC power source, and another repeater of a polarized start relay, whose winding is connected in series with a normally open contact of a polarized start relay and a DC power source, with one end parallel but the connected polarizing windings of one and the other unipolar monitoring relays arrows are connected to one pole of the DC power source through a series-connected make contact of one repeater of the polarized start relay, parallel to which is connected the disconnect contact of this one repeater connected to the other pole of the DC power source, and the other the end of parallel connected polarizing windings of one and the other unipolar relay control arrows are connected to the other pole a DC power source through a series-connected NC contact of another repeater of the polarized start relay, in parallel with which the NC contact of this other repeater is connected, connected to one pole of the DC power source, while the UVK terminal for inputting information about the positive position of the arrow is connected to the UVK terminal of the NO contact test through a series-connected make contact of one repeater of a polarized starting relay, in parallel to which the NC contact of this one repeater connected to the UVK terminal of the NC contact test, the serially connected NO contacts of one and the other unipolar relay control arrows, in parallel with which the NC contacts of one and the other unipolar relay control switches are connected, connected to the UVC terminal of the NC contact test, and the terminal UVK input information about the negative position of the arrow is connected to the UVK terminal of the test of the NC contacts through a series-connected NC the cycle of another repeater of the polarized start relay, in parallel with which is connected the make contact of this other repeater, connected to the make contact of one repeater of the polarized start relay.

The proposed technical solution is industrially applicable, because when it is used, a technical result is obtained in the form of an increase in reliability and manufacturability, as well as in the form of consistency of the outputs of the arrow position control with the UVK inputs for information on the plus and minus arrow positions of the EC-EM microprocessor-based electrical centralization used in Russia. From the above it follows that the proposed technical solution meets the requirements for a utility model.

An example of the implementation of the proposed three-wire control device arrow AC electric drive shown in FIG. one.

The circuit of a three-wire control device for an alternating current electric drive (see Fig. 1) contains a control computer complex (UVK) 1 of a microprocessor centralization system with test terminals for make contacts 1.1 and test disconnect contacts 1.2, input terminals for information on plus 1.3 and minus 1.4 arrow positions, relay block 2 with one contact follower of a polarized start relay (positive) 2.1 and its contacts 2.1.1, 2.1.2, and another contact follower of a polarized start relay (minus) 2.2 and its circuit You are 2.2.1, 2.2.2, a double-wound polarized start relay 3 and its contacts 3.1, 3.2, 3.3, 3.4, a neutral start relay 4 with an excitation winding 4.1 and a hold winding 4.2 and its contacts 4.3, 4.4, 4.5, 4.6, one unipolar arrow control relay 5 with working 5.1 and 5.2 polarizing windings and its contact 5.3, and another unipolar arrow control relay 6 with working 6.1, additional working winding 6.2 and 6.3 polarizing windings and its contacts 6.4, 6.5, transformer 7 with secondary 7.1 winding, phase-controlled block 8 with transformers 8.1, 8.2, 8.3 and terminals 8.1.1, 8.2.1, 8.3.1 for connecting of one, another and third phases of a three-phase alternating current source, terminals 8.1.2, 8.2.2, 8.3.2 for connecting a three-phase load, rectifier 8.4 and terminals 8.4.1, 8.4.2 for connecting a relay, electric drive 9 with control 9.1 and working 9.2 contacts of the auto switch and three-phase electric motor 9.3, line wires 10, 11, 12, diodes 13, 14, 15, capacitors 17, 18, 19, resistors 20, 21, 22, power supply of a DC relay with terminals plus “PB” and minus "MB", the source of three-phase alternating current 23, the source of alternating current 24. 6.2 operating winding is connected in series connection in the circuit of the linear conductor 10 to the phase of the voltage source 23 1F.

Polarizing windings 5.2 and 6.3 are connected in parallel.

The device of FIG. 1 shows in the normal state of control the positive position of the arrow, while from winding 7.1 of the transformer 7 to the working winding 5.1 through the disconnecting contacts 4.5, 4.6 to the linear wires 10, 12 and connected to them through the normally closed control contacts of the auto switch 9.1, diode 15 and the resistor 21, an AC voltage is supplied from the source of this current 24, which, under the influence of the diode 15, is rectified and has one polarity, and the polarity of this rectified voltage coincides with the polarity of the voltage supplied through the circuit contact 2.1.2 and contact 2.2.2 from the source "PB", "MB" to the polarizing winding 5.2, which is why relay 5 is energized, from winding 7.1 of the transformer 7, to the working winding 6.1 through the disconnecting contacts 4.4, 4.5 into line wires 10 11 and connected to them through normally closed control contacts of the auto switch 9.1, the diode 15 and the resistor 22, an AC voltage is supplied from the source of this current 24, which is rectified by the action of the diode 15 and the polarity of this rectified voltage coincides with the voltage polarity “PB”, “ MB ", p supplied through the make contact 2.1.2 and the make contact 2.2.2 to the polarizing winding 6.3, which makes relay 6 energized.

From the UVK 1.1 terminal, through the NO contacts 5.3, 6.4, unipolar relay control switches and contact 2.1.1 of the positive follower of the polarized start relay, the NO contact test is received at the UVK 1.3 terminal, which fixes the positive position of the arrow.

To transfer the arrow from the positive to the negative position from the output device of the UVK, the “PB” is switched from the “+” terminal to the “-” terminal, which causes relay 4 to be activated via the circuit: “PB”, normally closed contact 3.1, “MB”. Relay 4 with make contacts 4.5 through a linear wire 10 and closed working contacts of a circuit breaker 9.2 and a capacitor 19 and a resistor 20 will connect one output of an electric motor 9.3 to an alternating current source 23, with make contacts 4.4 through a linear wire 11 will connect a second output of an electric motor 9.3, with make contacts 4.6 through a linear wire 12 will connect the third output of the electric motor 9.3 to an alternating current source 23 with an unchanged phase sequence, which will not cause the switch to occur. The opening of the normally open contact 4.6 will stop the power supply to the winding 5.1 from the diode 15, which is why the relay 5 will release its armature and with the open making contact 5.4 it will stop feeding the test of the make contact to the UVK 1.3 terminal, which will stop monitoring the positive position of the arrow. The closed NC contact 5.4 will connect the NC test from the UVK 1.2 terminal to the UVK 1.3 terminal, which will ensure that the positive position of the arrow is not monitored during this period of operation of the circuit. Closed make contact 4.3 will create a relay 3 response circuit: “ПБ”, relay winding 3, diode 13, closed contact 4.3, “MB”.

Relay 3 by switched contact 3.1 will disconnect power to relay 4 through winding 4.1. Relay 3 with the switched contact 3.4 will disconnect the power supply "PB" from the coil of relay 2.1, why this relay will release its armature, and connect this power to the coil of relay 2.2, why this relay will work.

The switched contacts 2.1.2 and 2.2.2 will change the polarity of the power supply connection "PB", "MB" to the polarizing windings 5.2, 6.3.

The switched contacts 3.2, 3.3 will change the sequence of phase rotation from the source of the three-phase alternating current 23 in the linear wires 11, 12, which is why the three-phase electric motor 9.3 will begin to move the arrow to the negative position.

At the beginning of the switch’s switch, normally open working contacts 9.2 of the automatic switch are closed, which shunts the capacitor 19 and resistor 20, which ensures the normal power supply of the motor windings 9.3 for the entire time of the switch wit arrows, and the control contacts 9.1 are disconnected, which disconnect from the linear wires 10, 11, 12 diode 15, why the DC power supply to the working winding 6.1 will stop, and relay 6 will also release its armature, open the make contacts 6.4 and close the make contact 6.5 and thereby create a holding circuit relay armature winding 4 4.2 8.4 from the rectifier flowing under the influence of the primary windings of transformers 8.1, 8.2, 8.3 9.3 motor operating current, causing relay 4 holds the armature in attracted position during the transfer time direction.

After the translation is complete, the arrows in the negative position will open and the shunt will be removed from the capacitor 19 and the resistor 20, the normally closed working contacts 9.2 of the auto switch, so that the capacitor 19 and the resistor 20 will be turned on in series with the winding of the electric motor 9.3 for the entire period of monitoring the position of the arrow, as well as the normally open control the contacts of the auto switch 9.1, which will change the polarity of the connection of the diode 15 to the linear wires 10, 11, 12.

Because the other polarity of connecting the diode 15 to the linear wires 10, 11 corresponds to the polarity of connecting the power to the polarizing winding 6.3, then the relay 6 is energized by the operating current of the power supply 23 rectified by the diode 15 and the disconnecting contact 6.5 will turn off the power supply circuit of the relay coil 4.2 why this relay will release its anchor and open the closing contacts 4.4, 4.5, 4.6 will disconnect the power of the electric motor 9.3 from the power source 23, and with the closed breaking contacts 4.4, 4.5, 4.6 will provide tanie working coils 5.1, 6.1, 7.1 of the coil 7 of the transformer and a diode 15.

Relay 5 is energized because the working winding 5.1 will receive power from the rectifier 15 through a closed opening contact 4.6, the polarity of which coincides with the polarity of the power received by the polarizing winding 5.2 from the source "PB", "MB". Relay 6, which was previously energized by the additional working winding 6.2 under the influence of the current of the power source 23, after releasing the armature, relay 4 will continue to hold its armature in the pulled position under the influence of the rectifier 15 connected to the working winding 6.1, and the voltage from winding 7.1, and under the influence of the source "PB", "MB" connected to the winding 6.3, due to the coincidence of the polarity of these voltages on the windings 6.1 and 6.3

After the relay 5 is activated, the terminal of the UVK 1.4 receives a test of the make contact from the terminal of the UVK 1.1 through the make contact 2.2.1 and the closed make contacts 5.4, 6.4, which fixes the negative position of the arrow.

The arrow returns to the positive position in the same way when the command is from the UVK device, which switches “PB” from the “-” terminal to the “+” terminal. A variant of the proposed device is possible, in which the wires connected to the terminals 1.3, 1.4, instead of connecting to the UVK, are connected respectively to one end of the windings of the positive (PC) and negative (MK) control switches of the arrows, the other ends of which are connected to one pole of the constant source current, and wire 1.1 instead of connecting to the UVK is connected to the other pole of this power source. In this case, the device can be used in any relay systems of electrical centralization.

Taking into account that the cable costs in the proposed device and in the two-wire direct current arrow control device widely distributed in Russia are almost identical, it is possible to replace the latter with the proposed device without laying an additional cable, and by replacing only the electric motor in the electric drive and some correction of the post equipment.

A variant of the proposed device, in which a capacitor is connected in parallel with winding 4.2, is used to increase the deceleration by releasing the armature of relay 4 after the current ceases in the windings of the electric motor arrows.

A variant of the proposed device, in which a non-contact auto-switch is used, is used, instead of the working and control contacts of the auto-switches in FIG. 1, the corresponding relay contacts are included, which are repeaters of the control contacts of the sensors of the plus and minus positions of the arrow. The proposed device for controlling a pointer electric drive can be used to control twin arrows, while the operation of the device is similar to that described for FIG. 1, and the electrical diagrams of the connections in the electric drives, between the electric drives and connecting them to the linear wires, as well as the procedure for transferring arrows and obtaining control of their position are similar to those described in the opposed device.

The economic effect of the proposed three-wire control device arrow AC electric drive can be characterized by the following indicators:

- increased reliability of a two-winding transformer compared to a three-winding;

- economic effect due to the possibility of using the device in microprocessor centralization EC-EM, used in Russia, without the use of additional transitional devices;

- the economic effect of the increased manufacturability of a double-winding transformer.

- the economic effect of eliminating the use of an additional rectifier bridge to power the elements of the device.

Literature

1. RF patent No. 127704, IPC B61L 5/00 of 11.29.2012

2. "Automation, communications, computer science." Moscow, No. 9, 2014

Claims (1)

A switchgear control device containing three line wires, a three-phase electric motor drive and a circuit breaker with control and working contacts, a polarized start relay and a neutral start relay with a holding winding and an excitation winding, a phase monitoring unit with leads for connecting one, another and third phases of a three-phase alternating current current, with one, another and third terminals for connecting a three-phase load and terminals for connecting a relay, control computer complex (UVK) microprocessor centralization with test terminals for making and breaking contacts and terminals for entering information about the plus and minus positions of the arrow, one and the other unipolar arrow control relays with working windings and polarizing windings, one of these unipolar arrow control relays has an additional working winding, while this additional working winding is connected in series to the circuit of connecting one of the linear wires to a three-phase alternating current source, transformers, diodes, conden senators, resistors, sources of direct, alternating and three-phase alternating currents, characterized in that it contains one repeater of the polarized start relay, the winding of which is connected in series with the normally closed contact of the polarized start relay and a DC power source, and another repeater of the polarized start relay, winding which is connected in series with a normally open contact of the polarized start relay and a DC power source, while one end of parallel connected polarizing windings of one and the other unipolar monitoring relay arrows are connected to one pole of the DC power source through a series-connected make contact of one repeater of the polarized start relay, parallel to which is connected the disconnect contact of this one repeater connected to the other pole of the DC power source and the other the end of the parallel-connected polarizing windings of one and the other unipolar relay control arrows are connected to another at the pole of the DC power source through a series-connected disconnecting contact of another repeater of the polarized starting relay, in parallel with which the closing contact of this other repeater is connected, connected to one pole of the DC power source, while the UVK terminal for inputting information about the positive position of the arrow is connected to the UVK test terminal make contact through series-connected make contact of one repeater of a polarized start relay, in parallel with the NC contact of this one repeater is connected, connected to the UVK terminal of the NC contact test, the series-connected NO contacts of one and the other unipolar relay control switches, in parallel with which the NC contacts of one and the other unipolar relay control switches are connected, connected to the UVK terminal of the NC contact test, and terminal UVK input information about the negative position of the arrow is connected to the terminal UVK test break contacts through a series-connected break yuschy contact another repeater polarized starter relay is connected in parallel normally open contact of another repeater connected to the normally open contact one repeater polarized starter relay.

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