RU26700U1 - AUTOMATIC RESERVE DEVICE - Google Patents

Description

AUTOMATIC RESERVE DEVICE

The device for automatic input of the R&& pvA relates to power supply and distribution schemes: bins and is designed to automatically switch the load from the main supply network to the backup and full (the load from the mains in case the network parameters exceed the permissible limits.

A device is known for guaranteed power supply of low-voltage high-current direct current consumers with automatic switching on of a fast-acting one (Н 02 J / see RF application No. 97121469 09 of 08.12. 1997, publ. BI No. 30 for 1999), containing a network converter and a backup system electrical consumptions (assumed in the claimed object), pulse generator battery connected via isolation diodes w of the guaranteed power bus, it is equipped with a capacitive storage device connected through a separation diode to garantirovashchvp buses) power supply, with back-circuits of a capacitive energy storage device, a charging resistor R is connected to the connection point of the energy storage tank and its isolation diode by one output, and the normally closed S 1 and normally open contactors Ш, the second terminal of the normally closed contactor S 1 connected to the% W connection of the network converter and its isolation diode, and the ISHRO output of the normally open contactor S2 is connected to the connection point of the backup power system with its separate flax diode. € | 1shnm at the analogue with the claimed object is the automatic inclusion of SRMstredeystva reserve, however, the implementation of the analogue and prototype is different:

The impossibility of a general technical result of the claimed object is due to || the result is a bath of low-voltage direct current consumers, a mechanical contactor.

Another well-known {Tsgadopny claimed technical solution is a device for the consumer's eshty from unacceptable values (deviations) of the voltages I of the alternating current and direct current (N 02 N, see certificate model No. 19435, publ. BI No. 24 for 2001), containing the first 41: and input terminals for connecting to a power source, a transmitter and a second output terminals for connecting to load terminals (available in an encrypted object), an electromagnetic relay with a switching contact and a TB limiting element connected between the first and second input conclusions that additionally between

IPC 7 H02J,

the first and second input terminals through the disconnecting power contacts of the first electromagnetic element with one stable state, responding to an abrupt increase in voltage, a chain of serially connected disconnecting devices is connected,

current-limiting elem | nta and a second electromagnetic element with one stable state having closing and opening power contacts, the first input terminal being connected through the opening contacts of the first electromagnetic element with one stable state and closing power contacts of the second electromagnetic element with one stable state with the first output terminal for connection to the terminals of the load, and the second input terminal is connected through the disconnecting power koshst of the first electromagnetic element with one stable condition and the closing power contact of the second electromagnetic element with one stable state with the second output terminal, while the first output terminal is also connected through the opening power contact of the second electromagnetic element with one stable state with the first output terminal of the alternative power source, and the second output terminal is connected through the disconnecting power contact of the second electromagnetic element with one stable state with the second output terminal of an alternative power source.

The inability to ensure the technical result of the claimed object in the analogue is due to the choice of a simplified protection scheme without switching to the reserve.

The closest technical solution for functional purpose and technical essence is a device for automatically turning on the backup power source (see utility model certificate No. 19436 Н02 J, 9Ш, publ. BI No. 24 for 2001), containing the main and backup power sources, connected to the load through separation diodes, and their switching circuit, the power sources are connected to the network through two heistors, the cathodes of which are connected to the network inputs of the power sources, the anodes to the phases of the mains, and the circuit itself is switched Ia (control unit in the inventive apparatus) comprises two switching circuits seven hundred | PB (wiring diagrams in the claimed object), connected to the control outputs of the semistors (available in the claimed object), two control circuits for the upper limit of the mains voltage (available in the claimed object), the inputs of which receive mains voltage, and the outputs are connected to the switching circuits of the seven-voltors control circuits for the lower limit of the voltage of the mains voltage (available in the claimed object), the inputs of which receive mains voltage, and the outputs are connected to the switching circuits of the seven-cell and two control circuits for malfunction s of power, the inputs of which are connected to the outputs of the power sources, and the outputs to the circuitry for turning on the seven-voltors (semiconductor switching elements in the claimed object).

The inability to ensure the technical result of the claimed object is due to the simplicity of the design of the prototype, designed for a single-phase network, the lack of protection of the heistor current and voltage.

The technical result of the utility model is to increase the reliability of the electrical network of any production, to expand the functionality (the ability to control voltage and control the load current).

The technical result of the utility model is achieved by the fact that in the device for automatic input of the reserve, containing two semiconductor switching elements, two control circuits for the upper and lower limits of the voltage, two switching circuits integrated in the control unit, the outputs of which are connected to the control electrodes of the semiconductor switching elements four power semiconductor switching elements combined in a block of semiconductor structures, four control circuits of the upper o and the lower limits of the voltage of the mains, combined in the control unit of the upper and lower limits of voltage, six voltage sensors, the inputs of the first, second and third voltage sensors are connected to the inputs of the main network of three-phase alternating current, and the inputs of the fourth, fifth and sixth voltage sensors are connected to the inputs backup network, the inputs of six voltage sensors through the control unit of the upper and lower voltage limits and the control unit are connected to the control electrodes of the three power semiconductor commutators of the main network elements of the block of semiconductor structures and three power semiconductor switching elements of the backup network of the block of semiconductor structures, and the current control unit, consisting of a current control circuit and three current sensors, the outputs of which are connected to the inputs of the current control circuit, and the output of the current control block through the block control is connected to the control electrodes of the three power semiconductor switching elements of the main network of the block of semiconductor structures and three power semiconductor comms pscx of elements of the backup network of the block of semiconductor structures, the inputs of the block of semiconductor structures are connected to the main and backup networks, respectively, and the outputs of the block of semiconductor structures are connected to the inputs of current sensors, the outputs of which are connected to the inputs of the load.

The achievement of the technical result is possible due to the use of a reserve input device in the electric networks of three-phase alternating current at the production site.

The figure shows a functional diagram of a device for automatically entering a reserve .: where 1,2,3,4,5,6 are voltage sensors; 7, 72.7 zvvoda main network three-phase alternating current; 8i, 82, 8c - inputs of the backup network; 9 - control unit for the upper and lower limits of the voltage, consisting of six circuits for monitoring the voltage of the upper and lower limits of the voltage; 10- control unit, consisting of two switching circuits; 11- block of semiconductor structures, consisting of

J (i

three power semiconductor switching elements of the axis network and three power semiconductor | new switching elements of the backup network; 12,13, 14 - three sensors15-current control circuit; 16 DT controllers

electrodes of the main and cut networks, respectively; ISi, 182, 18z- load inputs, 19- koshrmsmMJZha unit, consisting of a current control circuit 15 and three current sensors 12,13,14.

The device for motor input of the reserve consists of six voltage sensors 1,2,3,4,5,6, Bjeiflu three voltage sensors 1,2,3 are connected to the inputs of the main triz | zhv: © st "burn 7i, 72, 7z, inputs of voltage sensors 4,5,6 are connected from the input | § three-phase network 8i, 82, 8z, outputs of six voltage sensors, 2,3,4,5,6 through the control unit the upper and lower voltage limits of the control voltage 9, containing six control circuits of the upper and lower voltage preferences, is connected to the control unit 10, which contains two circuits; block of creep-conductor structures 11, consisting of three power semiconductor switching elements of the main network and three power-supply semiconductor switching elements of the backup network, negiliro inputs, the second and third voltage sensors 1,2,3 are connected to the inputs of the power semiconductor switching elements, outputs 1 | semiconductor structures 11 of the main and backup networks connected to the inputs of three current sensors 12, 13, 14. The outputs of three current sensors 12,13,144X) are connected to the input of the current monitoring circuit 15. The control unit 10 is connected to the control electrodes 16 and 17 of the three power semiconductor co1 | 1 | The main elements of the main network of the semiconductor block 11 and the three power semiconductor switching elements of the Central network of the block of semiconductor structures 11.

The outputs of the three sensors skinny 12,13,14 are connected to the load inputs 18i, 182, 18z, respectively. DaR1fi current 12,13,14 and the current control circuit 15 are combined in the block counter-current 19.

The Shad Reserve device operates as follows:

The device contains the main 7i, 72, 7z and inputs of the redundant network 81.82, 8z of a three-phase switch of industrial frequency and outputs for connecting the load 18), 18 2, 18 s. Switching from the main to the backup network and the complete disconnection of the load from the power supply occurs due to the supply of control signals to the controllers. The evolving electrodes of the main and backup networks are respectively 16 and 17. The control signals are transmitted through the control unit 10. Switching from 1 main supply to the backup network occurs in cases of:

- Power failure Yaltspovpoy supply network;

-a significant reduction in voltage recovery from the nominal value in the main network. Hanpifi im is completely disconnected from the mains in the following cases:

- excess in the load of the gok from the nominal value during operation, both the main and

backup power networks.

Voltage sensing of the shray network is provided by voltage sensors 1-6. Voltage control is carried out by the control unit of the upper and lower limits of the voltage of the mains 9. Current sensors 12, 13, 14 measure the current level in the load (load terminals 18i, 182, 18z. Voltage sensors 1-6, the control unit for the upper and lower limit of the voltage of the mains 9, the switching unit 10, the current control unit in the load 19 provide the formation of the control When the device is connected to the network, the control unit 10 along the lines of the control signal on the control electrode of the main network 16 and the control signal on the control electrode of the backup network 17 blocks the operation of the block of semiconductor structures 11 for the time required to complete transient processes in the device.This is necessary to exclude the possible simultaneous inclusion of power semiconductor switching elements of the main and backup networks.After the device has entered the operating mode, the control unit for the upper and lower voltage limits 9 polls the state of the voltage sensors 1,2,3 of the main network and, if network parameters are within tolerances, block 9 gives a signal to block 10, allowing the inclusion of power switching elements of the main network of the block of semiconductor structures 11. Next, produces I continuous monitoring of the core network parameters. In the case of an increase or decrease in the voltage in the main network, the voltage control unit 9 supplies a signal to the control 10 that disconnects the power switching elements of the main network of the block of semiconductor structures 11 through the main network line and, after a time necessary for reliable locking of the switching elements of the main network, through the line the control electrode 17 is fed a signal for switching on the switching elements of the backup network. Next, the control unit of the upper and lower voltage limits monitors the state of voltage sensors 1-6 of the main and backup power networks. In the case of normalizing the voltage in the main network, block 10 removes the enable signal from line 17, disconnects the switching elements of the backup network and, after a period of time necessary for locking the reserve power switching elements, connects the main network via line 16 through the power switching elements of the main network. If in the operating mode when the backup network is turned on from the voltage sensors 4-6 of the backup network, a signal is received to the voltage control unit 9, informing that the voltage of the backup network is outside the set parameters, the voltage control unit 9, through the control unit 10, removes a signal on line 17 allowing the operation of power switching elements of the backup network and the load is de-energized. But the voltage monitoring unit 9, through voltage sensors 1-6, continues to monitor the status of both the backup and the main network and, in the event of normalization of the voltage of any of them, connects the load of the corresponding network through power switching elements. To prevent possible failure of power switching elements between

current sensors 12,13,14 continuously monitor the load current during operation from both the main and the backup network, are outputs of the switching elements of the main and backup networks. If the current exceeds a certain value in one or all phases, the signal from the current sensors 12,13,14 is fed to the current control circuit 15, which in turn generates a signal "blocking through the control unit 10, blocking the power switching elements of the main and backup networks via line control electrodes 16 and 17, thereby completely disconnecting the load. After eliminating the causes of the overcurrent, the device is switched on again.

Current sensors 12,13,14 are sealed magnetically controlled contacts (reed switches). The current control circuit 15 is assembled on the basis of the R-S trigger on the integrated circuit of the K561 series. Voltage sensors 1-6 are rectifiers. The control unit of the upper and lower voltage limits 9 is made in the form of integrated comparators.

This device for automatic input of a reserve, in comparison with analogs, provides high reliability of operation of the electric network of any production due to the monitoring of the load current.

Claims (1)

A device for automatic input of a reserve, containing two semiconductor switching elements, two control circuits for the upper and lower limits of the voltage of the mains voltage, two switching circuits combined in a control unit, the outputs of which are connected to the control electrodes of the semiconductor switching elements, characterized in that four additional power semiconductor switching elements are additionally introduced elements combined in a block of semiconductor structures, four control circuits for the upper and lower limits of voltage network connected to the control unit of the upper and lower limits of the voltage, six voltage sensors, the inputs of the first, second and third voltage sensors are connected to the inputs of the main network of three-phase alternating current, and the inputs of the fourth, fifth and sixth voltage sensors are connected to the inputs of the backup network, outputs six voltage sensors through the control unit of the upper and lower voltage limits and the control unit are connected to the control electrodes of the three power semiconductor switching elements of the main a unit of a semiconductor structure unit and three power semiconductor switching elements of a backup network of a semiconductor structure unit, a current control unit consisting of a current control circuit and three current sensors, the outputs of which are connected to the input of the current control circuit, and the output of the current control unit through the control unit is connected to the control electrodes of three power semiconductor switching elements of the main network of the block of semiconductor structures and three power semiconductor switching elements of the backup network eye semiconductor structures inputs of unit semiconductor structures connected to the primary and backup networks, respectively, and outputs a block of semiconductor structures connected to the inputs of the current sensors whose outputs are connected to inputs of the load.