SU1534635A1 - Blackout-proof power supply system - Google Patents

Abstract

The invention relates to the electrical industry, in particular, to redundant power systems in automatic power installations. The aim of the invention is to increase reliability. The system contains a working and backup rectifier connected in parallel to the load, a charge rectifier, a first, second and third voltage relay, a first and a second rectifier, a thyristor and a diode. The system is equipped with a pulse transformer, the primary winding of which is connected to the positive load through a series-connected capacitor and resistor, and negatively through the closing contact of the first voltage relay. The secondary winding of the pulse transformer is connected between the cathode and the control electrode of the thyristor. The reliability of the system is ensured by the equal charge of additional battery cells. 1 il.

Description

The invention relates to the electrical industry, in particular, to redundant power systems, and concerns the issue of switching partitioned batteries in automatic power plants (EPA).

The purpose of the invention is to increase the reliability of the uninterruptible power system.

The drawing shows the power scheme.

The circuit contains working 1, reserve 2 and charge 3 rectifiers, - the first voltage relay 4, the main elements 5 of the battery, the first 6 and the second 7 groups of additional battery elements,

rectifiers 8 and 9, thyristor 10, diode H, second 12 and third 13 voltage relays, contactors 14 and 15, pulse transformer 16, capacitor 17 and resistor 18. Worker 1 and standby 2 rectifiers are connected in parallel to the load. A sectioned battery consists of the main battery cells 5 connected in series, and two groups 6 and 7 of the additional battery cells. Parallel to the load, voltage relays 12 and 13 and contactors 14 and 15 are also connected.

Parallel to the second group of 7 additional battery cells, the voltage relay 4 is turned on.

Parallel to each group of additional elements of the battery, rectifiers 8 and 9 of the content, respectively, are connected. The positive pole of the main elements 5 of the battery through the closing contact 14 of the contactor 14 is connected to the negative pole of the rectifier 3 and the negative pole of the first group of additional elements of the battery, and through the opening contact 14 of the contactor 14, which opens 15 and closes the 15 contact of the contactor 15 with a positive pole of the second group of 7 additional elements.

The common terminal of the contactors 14 and 151 is connected to the common terminal of the first 6 and second 7 groups of additional battery cells. The contactors 14 and 15 are connected to the negative pole of the load through the corresponding closing contacts 12 and 13, the relays 12 and 13 of the voltage. The anodes of the thyristor 10 and diode 11 are connected to the positive pole of the rectifier 3, the cathodes, respectively, to the negative and positive poles of the second group of additional elements 7.

The primary winding of the pulse thyristor control transformer 16 is connected, via the closing contact of the voltage relay 41, to the negative load pole, and the capacitor 17 and resistor 19 cut to the positive load pole. A secondary winding of the transformer 16 is connected between the cathode and the control electrode of the thyristor 10. The control input of the charging rectifier 3 is connected to the positive pole of the load through parallel connected contact terminals 12j and 13 of the voltage relay 12 and 13.

The system works as follows.

In the presence of mains voltage, the working rectifier 1 feeds the load and contains the main elements 5 of the battery. Standby 2 and charge 3 rectifiers are off at this time. Additional battery cells 6 and 7 contain rectifiers 8 and 9 of contents. The voltage relay 4 is in the loosened state. When the mains voltage drops and the voltage drops to 0

five

0

five

0

five

0

five

0

five

to load up to 59 V, relay 12 operates and, with its contact 12j, closes the supply circuit of the winding of contactor 14, which connects to the load in series with the main elements 5 of the battery the first group of 6 additional elements of the battery. When the mains voltage turned on by working 1 and backup 2 rectifiers, the main elements of the battery 5 and the first group of 6 additional elements of the battery charge up to 66 V on the load, and then releases the voltage relay 12, contact 121 disconnects the supply circuit of the winding of the contactor 14, disconnecting the first group of 6 additional battery cells from the load.

Contact 12 turns on the charging rectifier 3, since this contact breaks the power supply circuit of the relay inside the charging rectifier 3, which keeps the rectifier off.

The charging rectifier 3 is switched on at once into two groups of additional elements through diode 11. If the second group of 7 additional elements is not discharged, the voltage on it instantly becomes 2.3 V per element. In this voltage, voltage relay 4 is activated. By contact 4, it turns on the charge circuit of capacitor 17. At the time of charge, the current passes through the pulse transformer 16. The voltage pulse transformed into the secondary winding turns on the thyristor 10. In this case, the charge rectifier 3 is connected through the thyristor to the first group of additional elements, and the diode 11 is closed by the reverse voltage of the second group of additional elements.

When the first group of additional elements reaches 2.3 V, the element turns on the voltage relay located in the charging rectifier 3, and the charging rectifier turns off.

If, after connecting the first group of 6 additional battery cells, the mains voltage does not appear and the total voltage on the main and first groups of additional battery cells decreases to 59 V, then the voltage relay 13 is activated, which

contact 13 includes a contactor 15, which, in turn, with its contact 15 connects in series with the first group a second group of additional elements.

After the mains voltage appears, the working and backup rectifiers 1 and 2 charge the entire battery to 66 V, then releases the voltage relay 13 and turns off the contactor 15, which disconnects the second group of additional elements 7, then the remaining The battery is charged to the voltage of 59.5 V on the main elements of the battery 5. After this, the first group 6 of the battery is disconnected from the load circuit. After this, the parallel rectifier 12D and 13 turn on the battery rectifier 3 for charging and both groups of additional elements. Further work is similar to that described.

Thus, the invention makes it possible to increase the reliability of uninterrupted power supply systems by providing a more uniform charge for additional battery cells.

Claims (1)

Invention Formula An uninterruptible power supply system containing a group of main elements of a battery, the first and second groups of additional elements of a battery, terminals for connecting the load, in parallel with which the working and backup rectifiers, the charging rectifier, the first voltage relay, are connected in parallel to the load and the third voltage relay, the first and second content rectifiers, connected in parallel, respectively, to the first and second groups of additional battery cells peu connected in series, the thyristor and diode anodes 15 which podJQ 0 five 0 five 0 five The cathodes are connected to the plus of the charge rectifier, respectively, to the minus and plus of the second group of additional battery cells, as well as the first and second contactors connected in parallel to the terminals for connecting the load through the first make contacts of the second and third voltage relays, respectively This negative terminal for connecting the load is connected to the negative pole of the main battery cell group, the positive pole of which is connected to the negative and positive fields. The first group of additional elements of the battery, respectively, through the "closing and opening contacts of the first contactor, the positive terminal for connecting the load is connected to the positive and negative poles of the second group of additional elements, respectively, through the closing and opening contacts of the second contactor, and minus the charge rectifier connected to the minus of the first group of additional battery cells, characterized in that, in order to increase reliability, it provides and a pulse transformer, the primary winding of which is connected to the positive terminal for connecting the load through a series-connected capacitor and resistor, and the negative terminal for connecting the load via the closing contact of the first voltage relay connected in parallel to the second group of additional battery cells a transformer is connected between the cathode and the control electrode of the thyristor, and the control input of the charge rectifier is connected to An output terminal for connecting the load through parallel connected second make contacts of the second and third voltage relays.