SU902153A1 - Redundancy power supply of load - Google Patents

Description

(54) DEVICE FOR POWER SUPPLY RESERVATION

Claims (2)

The invention relates to electrical engineering and can be used in power supply systems for consumers who do not allow interruptions in operation. A power backup device is known in which switching from a main source to a backup source is carried out using magnetic starters or turnips f. However, this device is not sufficiently reliable and creates large interferences when switching starters on and off. The closest to the proposed technical entity is a power backup device containing the main and backup sources, connected in parallel and capacitor-bridged, a backup battery with a static voltage converter is used, and the backup source is turned on and off. with a composite transistor and a voltage relay (mains voltage sensor) 2. The known device has a limited scope, since only dp low-power power sources connected to the network through a power transformer can be used. When using a device in power sources, the dimensions of the device increase dramatically due to the large size of the power transformer and the need to pass a large current of the battery through the composite transistor, and the efficiency of the backup source drops due to the voltage drop on the composite transistor. When using the device in power sources without a power transformer and powered directly from the network through a controlled rectifier with a soft start device to limit the charging current of the rectifier of directors, the voltage drop at the device output is obtained when the network voltage is restored due to that the backup source is turned off immediately after the restoration of the mains voltage, and the voltage at the output of the main source rises to the nominal value with a time delay. The purpose of the invention is to increase the efficiency of the device. The goal is achieved by the fact that a power backup device containing a controlled rectifier with a soft start unit of the main source and a rectifier of the reserve source, connected in parallel and bridged by a capacitor, is connected to the output winding of the transformer of the static voltage converter , a battery and a mains voltage sensor connected to the secondary of a control transformer secondary winding network switch; a node for turning on the static voltage converter, whose input is connected to the output of the network voltage sensor, and the output to the control input of the static voltage converter, is entered; the input of the controlled rectifier of the main source is assigned to connect to the network, The power input of the static voltage converter is connected to the battery charge terminal. In addition, a diode is inserted in the device, the anode of which is connected to the positive output of the rectifier of the reserve source, and the cathode to the connection point of the positive output of the correcting rectifier of the main source and the capacitor. The drawing shows the principle on the scheme of the proposed device. The device consists of a controlled rectifier 1, the main source of the rectifier 2 of the backup source with a diode 3 connected in parallel and shunted by a capacitor 4. The input of the rectifier 2 of the backup source is connected to the output winding of the transformer 5 of the static voltage converter 6. The power input of the converter 6 is connected to the terminals of the ak-umulator battery 7. The device includes a network voltage sensor 8 connected to the rectifier 9 of the secondary winding of the control transformer 10. Transformer 10 with its primary winding is connected in parallel to the input of controlled rectifier 1. A node 11 of the converter de-energization delay 11 is connected to the output of the network voltage sensor, the output of which is connected to the control input of the converter 6. The electronic switch on the resistor 12 and the transistor 13 and the time relay on the resistor 14, the capacitor 15, the transistor 16 and the resistor 17. The proposed device operates as follows. When the controlled rectifier 1 is turned on, the voltage at its output, gradually increasing, charges the capacitor 4. If the network voltage exceeds the pickup level of the network voltage sensor 8, then at its output and, therefore, at the input of the node 11 the shutdown delay 11 low voltage level. Transistor 13 is closed, capacitor 15 is charged through resistor 14 to open voltage of transistor 16. Transistor 16 is open, a high voltage level appears at the output of node II, turning off voltage converter 6, and the output voltage of rectifier 2 missing . When the network voltage disappears or is lowered to the level of release of the sensor 8, the network voltage at its output and, therefore, at the node input. 11, the turn-off delay, a high voltage level is established, opening the transistor 13. The capacitor 15 through the transistor 13 is quickly discharged, the transistor 16 is closed, and a low voltage level appears at the output of the turn-off delay node 11, turning on the voltage converter 6. At the output of the rectifier 2, a voltage appears, which through diode 3 is connected to the capacitor 4. The magnitude of the capacitor 4 is chosen so that during the switching time less than 1 ms at the operating frequency of the converter 20-25 kHz, it practically does not change Referring voltage across the capacitor. 5 When the grid voltage recovers, the high potential at the output of the sensor 8 of the grid voltage changes to low, the transistor 13 closes and the capacitor 15 starts to charge through the resistor 14. The voltage converter 6 continues to operate until the capacitor 15 charges Before the opening voltage of the transistor 16. This charging time is chosen to be longer than the rise time of the output voltage of the controlled rectifier 1 and therefore the voltage drop across the capacitor 4 is practically absent. Diode 3 serves to eliminate the influence of the drivers 1 and 2 on each other and increases the stability of the device. The proposed solution makes it possible to eliminate the high-power composite transistor used to turn on the voltage converter, as a result of which the efficiency of the device is increased, the size is reduced and the equipment is saved. 1. A power backup device comprising a control rectifier with a soft start unit of a main source and a rectifier of a backup source connected in parallel and shunted by a capacitor. The input of the rectifier 36 of the backup source is connected to the output winding of the transformer of a static pre-transformer, a battery, and a mains voltage sensor connected to a secondary rectifier rectifier of a control transformer intended to be connected to In order to improve the efficiency of the device, a node for switching off the static voltage converter is inputted, the input of which is connected to the output of the network voltage sensor, and the output to the control input of the static voltage converter, the input of the controlled rectifier of the main source It is designed to be connected to the mains and the power input of the static voltage converter is connected to the battery terminals. 2. The device according to Claim 1, which means that, in order to increase the stability of operation, a diode is inserted into it, the anode of which is connected to the positive output of the backup source rectifier, and the cathode to the connection of the positive output of the controlled rectifier main source and capacitor. Sources of information taken into account during the examination 1. USSR author's certificate N 663022, cl. H 02 J 9/06, 1977. 2. USSR author's certificate №661684, cl. H 02 J 9/06, 1974.