SU1094109A1 - System for standby supply of load with direct current - Google Patents

Abstract

SYSTEM FOR A RESERVE LOAD POWER SUPPLY WITH A PERMANENT CURRENT, This is from the main and additional batteries, connected in series, the first volt-meter relay connected in parallel to the main battery, the buffer rectifier, the minus of which is connected to the minus of the backup charging rectifier, and through the current sensor - to the minus of the main battery and two contactors, the trays of which are connected in parallel to the load, moreover, plus a backup charge rectifier is connected via the make contact of the first switch with a plus additional battery the multiplier battery, through the disconnecting contact of the first contactor, with the connection point of the main and auxiliary. batteries and with the anode of the first gateless switching valve, and through time there are 1 contacts of the second contactor with the plus of the load, which, in order to increase the reliability of the load and the entire supply system by providing a predetermined voltage to the load all operating modes of the power supply system, a second voltmeter relay connected in parallel with the main and auxiliary battery m, counter elements, g connected in parallel with the opening contact of the second contactor and the second the uninterrupted commutation circuit, the cathode of which is connected to the plus of an additional battery, and the anode to the plus of the backup battery rectifier 1 mtela and the plus of the buffer rectifier, the minus of which is connected to the minus load, and the cathode of the BQro uninterrupted switching valve: 4 connected to the plus load.

Description

The invention relates to reserving power systems, namely to the field of commutation of partitioned battery batteries in automatic power plants (EPU) The device is known to automatically disassemble a load on an EPA automatic battery. and it holds eleven main batteries of the battery in continuous charge mode. When the power supply fails, the equipment is powered from the main elements The two additional elements are connected to the system as the contactor is discharged. During the switching time of the contacts, the current flows through the continuous switching valve. When the voltage is applied to the power supply, the children turn on the buffer rectifier and the backup rectifier in the stabilization mode When the voltage rises, the additional elements are disconnected by the contactor and switched on for a charge from an additional charge rectifier (the charging current is continuous during switching through another safe valve main components, and the main elements continue to charge up to a voltage of 2.3 V per cell. The batteries from the buffer and reserve charge rectifiers. When the voltage of 2.3 V per cell is reached, the backup charge rectifier is turned off, and The rectifier switches to voltage stabilization mode. Additional elements are charged by an additional charge rectifier, which, at the end of the charge, is turned off, and additional elements are connected to the content rectifier l, the disadvantage and the diagrams are: the presence of an additional charge rectifier; the overvoltage that occurs when the buffer and standby charge rectifiers are turned on to charge thirteen battery cells. In this case, the voltage on the load exceeds the emf of thirteen elements and reaches, for example, for lead batteries more than 27 V with the upper norm of 24.6 V (24 V t10%). The closest in technical terms to the proposed system is a system for backing up the load with a constant, current, consisting of a main and auxiliary batteries, connected in series, a voltmeter relay connected in parallel to the main battery, a buffer rectifier connected in parallel load, current sensor in the load circuit, backup charge rectifier, the minus of which is connected to the minus of the buffer rectifier and two contactors, the coils of which are switched on parallel to the load, the plus of the additional battery is connected to the load through the closing contact of one and the opening contact of the other contactors, minus the main battery is connected to the load directly, the connection point of the main battery is connected to the connection point of the positive backup rectifier closing the contacts of one and the other contact contactors through the disconnecting contact of one contactor, in parallel with which the valve is turned on in the forward direction, and the thyristor, the anode and cathode of which is connected They are parallel to the opening contacts of the other contactor and the source of the reference voltage, the plus of which is connected to the plus of the additional battery, and the minus to the control electrode of the thyristor 2. In this circuit, there is no additional charge rectifier, however, the circuit also has a number of significant drawbacks: when the batteries are disconnected from the load, when they are charged, the current of the buffer rectifiers drops sharply, which causes significant overvoltages in the load; when the mains voltage fails during charging, all thirteen elements of the battery are connected to the load, and if the battery voltage is high (the end of the charge), the load (especially when its value is small) is overestimated; the thyristor at the appearance of the network at the beginning of the charge of the batteries, since the cathode of the thyristor is connected to the output of the buffer rectifier, the voltage of which increases gradually, therefore the cathode of the thyristor may appear atelnym with respect to the anode, wherein the thyristor falsely triggered, connects the battery Thorne. the battery is loaded, as a result of which the work of the entire power unit is disturbed until the thyristor burns, which are not designed for long-term operation. The aim of the invention is to increase the reliability of the load and the entire power supply system by providing a predetermined voltage across the load in all modes of operation of the power supply system, including transients. The goal is achieved by the fact that the system for the backup power supply of the load with direct current, consisting of the main and additional batteries, connected in series, the first volt-meter relay connected in parallel to the main

battery battery, a buffer rectifier, the minus of which is connected to the minus of the backup rectifier, and through the current sensor with the 1 sine of the MAIN battery and two contactors, the coils of which are connected in parallel to the load, and the backup rectifier is connected through a locking the contact of the first contactor with the plus of the additional battery, through the disconnecting contact of the first contactor - with the connection point of the main and additional batteries and with the anode of the first in Continuous switching, and through the disconnecting contact of the second contactor with positive load, a second voltmeter relay connected in parallel to the main and auxiliary batteries and counter elements, connected in parallel to the disconnecting contact of the second contactor and the second open switching valve, the cathode of which is connected to X plus additional battery of the secondary battery, and the anode - to the plus of the backup charge of the detector and the plus of the buffer rectifier, the minus of which is connected to the negative of the load, with it first cathode venti l hitless switching is connected to the plus load.

Fig, 1 shows a diagram of the proposed system; in fig. 2 is a timing diagram of the load voltage.

The system contains a buffer rectifier 1, a current sensor 2, a backup charge rectifier 3, a main battery 4, an additional battery 5, a rectifier of content b, the first gateless valve 7, the first voltmeter relay 8, contactors 9 and 10 , the second gateless switching valve 11, the second voltmeter relay 12, counter elements 13, the control unit 14.

The plus of the buffer rectifier 1 is connected to the plus of the backup rectifier 3, the bus of the closing contact 9, the anode of the second valve 11, - the bus of the opening contact 9 and through the normally open contact 10 - with the plus of the load. The minus of the buffer rectifier 1 is connected to the minus of the backup rectifier 3, the minus of the load and through the current sensor 2 to the minus of the main battery 4, plus of which is connected to the minus of the additional battery 5, disconnecting bus 9 and the first valve 7, whose cathode is connected to the plus load. Plus an additional battery 5 is connected to the cathode of the second valve 11 and the closing contact bus 9, in parallel

The main battery 4 is connected to the first voltmeter relay 8, parallel to the additional battery 5 is connected the rectifier 6 content, and parallel to the sum of the additional and main battery is connected the second voltmeter relay 12. Parallel to the disconnecting contact 10 are connected counter elements 13, which can be drawn, for example, four series-connected diodes. The coils of contactors 9 and 10, as well as the control unit 14 are connected in parallel to the load,

The device works as follows

In the buffer mode, the buffer rectifier 1 supplies the load through the opening contact 10, and through the opening contact 9 is connected to the main battery 4, which it contains in the continuous charge mode. a small current is flowing into the battery, which compensates for its self-discharge, and the executive relay of the current sensor 2 is released. Executive relays of blocks 8 and 12 are activated. Backup charge rectifier 3 is off. The coils of contactors 9 and 10 are de-energized.

When the mains supply voltage fails (moment t, f g 2), the buffer rectifier 1 is turned off and the battery 4 is discharged to the load. When the voltage on the battery 4 is reduced to 22.8 V, it releases the volt-meter relay 8, which follows the voltage on the battery 4 and the control unit 14 gives the command to first turn on the contactor 10 and then the contactor 9. Before closing contact 9 power supply is carried out through the first gateless switching valve 7 (time t / Fig. 2). Taking into account the voltage drop on the valve 7, the voltage on the load can decrease to 21.8 -V, which is higher than the lower allowable mink. At the time of contact closure 9 (time b, Fig. 2), an additional battery 5 is connected to the main battery 4 and the voltage on the load is the total battery voltage minus the voltage drop on the counter elements 13 of 3.5-4 B. At the same time, the voltage is 23-24 V. As the main 4 and additional 5 batteries discharge, the voltage of the voltmeter relay 12 and the control unit 14 disconnects the contactor 10, which bypins 10 bypasses the counter elements, when the main voltage of the battery decreases. 13 and the voltage on the load rises to 25.8 V (time tM in Fig. 2). When the mains voltage develops, the buffer rectifier 1 is turned on and the control unit 14 gives the command to turn on the backup charge converter 3, Rectifier The switches 1 and 3 are turned on in the current limiting mode and the batteries 4, 5 begin to charge (time 1, fig 2) As the batteries are charged, their voltage rises even when the voltage on the main battery is 4 23.2 -24 V triggers the voltmeter relay 8 actuator, and the executive device The meter volt relay 12 is configured at a total voltage of 26.2 V. The control unit 14 turns on the contactor 10, counter elements 13 are turned on between the battery and the load, and the voltage on the load decreases by 3.5-4 V (time t, fig .2) As the battery voltage increases, and when it reaches 2.3 V per cell (29.9 V for the entire battery 4 and 5), the rectifiers automatically exit from the limit-current mode ( which is provided for by the BUT and VUK serial rectifier circuit) and goes into voltage stabilization mode (time t, fig 2). By charging the battery, the charging current na gives And when its value approaches the content of the current, the executive relay of the current sensor 2 is released and, at its command, the control unit 14 turns off the backup charging terminal 3 and the contactor 9, at the time of the flight of the contacts This current flows through the second valve 11, and switches the buffer rectifier 1 to the voltage stabilization mode at an output voltage of 24.2 V, - The contactor 10 releases after the contactor 9 is released. At the same time, for the release time of the contactors 9 and 10, the current enters the load what cutting the first valve 7 (time point tg of Fig. 2). After closing the contacts 10, the circuit returns to the initial state (time point t, Fig 2). At the same time, the additional losses on counterstrips 13 are insignificant at discharge: l, because at full load their operation time is short, and at charge, the losses in the rectifier rectifier, which, like all short and high current rectifiers, are inherent low efficiency. In addition, the time of their work is sporadic only when the network is lost. Thus, the proposed system for back-up power supply with direct current provides a predetermined voltage to the load in all operating modes, including transients, and eliminates unreliable elements (thyristor and reference source), leading to disruption of the entire EPU, which significantly increases the reliability of the load and the power supply system as a whole.

Claims (1)

A DC BACKUP SYSTEM FOR DC LOADING, consisting of the main and additional batteries connected in series, the first voltmeter relay connected in parallel with the main battery, a buffer rectifier, the minus of which is connected to the minus of the backup charging rectifier, and through the current sensor - with minus the main battery and two contactors, the coils of which are connected in parallel with the load, with the plus of the backup charging rectifier connected via short-circuit the contact of the first contactor with the plus of the additional battery, through the opening contact of the first contactor - with the connection point of the main and additional batteries and with the anode of the first valve of uninterrupted switching, and through the opening contact of the second contactor with the plus of the load, characterized in that, in order to improving the reliability of the load and the entire power supply system by providing a specified voltage on the load in all modes of operation of the power supply systems, a second voltmeter relay connected parallel to the main and auxiliary batteries, anti-cells, § connected in parallel to the NC contact of the second contactor and the second uninterrupted switching valve, the cathode of which is connected to the plus of the additional battery and the anode to the plus of the backup charging rectifier and plus of the buffer rectifier, minus which connected to the load minus, the cathode of the first valve of the uninterrupted switching connected to the load plus.