SU748669A1 - Continuous power supply system - Google Patents

Description

one

The invention relates to industrial electronics devices, in particular to uninterruptible power systems of a responsible consumer in computing, telecommunications technology, etc.

There are known systems and devices with the help of which uninterrupted power supply systems for a responsible consumer are built, which contain an inverter as the main source, and an alternating current electrical network as a backup source. The inverter and the electrical network are connected to the load through static switches-t5, which are connected to the current-sensing circuit of the switching control circuit of the power sources. The inverter is synchronized in phase and frequency with the back-up electrical network. 20 If the main source fails, the current-sensitive circuit acts on the switching device so that a change in the current from the main source compensates -25 with a change in the current of the backup source, leaving the current in the load constant u.

One of the drawbacks of this system should be considered as constant 30

losses in energy conversion in the inverter, which is the working source, and in the devices that feed it (rectifier, batteries). These losses can reach 30% of the rated load power.

Another disadvantage is the lack of load protection against network interference when operating from a backup source, such as a general-purpose AC network. In addition, under certain climatic conditions, there is a need to use a forced cooling of the working source of this system.

Also known is a system consisting of two AC power sources and a switching device that contains blocks; zero-organs, sensors of the shape of the voltage of the memory sources, generation of a switching command, switching / control of the cut-off control of a charge switch, control of forced switching, switching of control electrodes, switching of power circuits, forced switching, phase selector, control of phase error, network filter compensator. Uninterrupted power supply in the system in case of failure of one source exists by transferring the load to another source. The contactless electronic switch has a high speed and therefore has time to quickly transfer the load to the backup source when a network disturbance occurs, which causes you to reduce the noise immunity of the load. This system significantly reduces power losses, which are limited by losses in the statistical switch not exceeding 3% of the rated power 2.

But the detrimental effect on the load of switching noise, arising during switching, is not completely excluded when the phase mismatch angles of the same phase are 0-60.

The closest technical solution to the invention is a system comprising two power sources, one of which is operational and the other redundant, and a device for uninterrupted power supply consisting of voltage form sensors, switching units, a switching command generation unit. Voltage form sensors are connected via inputs to the phases of the power sources, and via the output to the switch command generation unit, the outputs of which are connected to the inputs of switching units. The other inputs of the switching units are connected to the phases of the power supplies, and the inputs of these units are combined and connected to the load. The principle of operation of this system is that in the event of a failure of a working power source, it provides uninterrupted power to the load by switching it to a backup power source.

The disadvantage of such a system is its inability to operate stably from unsynchronized sources of non-synchronous sources, since the probability of switching sources at a time when the voltages of their like phases are shifted relative to each other by an angle of 180 is not excluded, which would cause interference in the load in in the form of a long deep failure of a voltage equivalent to a power failure. This quality significantly reduces the reliability of the system and makes it unacceptable in the power supply of the responsible consumer from unsynchronized to the power supply.

by frequency of sources of writing.

. The purpose of the invention is to increase the stability of the power supply system.

This goal is achieved by the following: Chtb to sysgema, sbdё ezhaschuyu dya power supply and uninterruptible power supply device, consisting of: form sensors, voltage, connected to the phases of the power supply and the block. power supplies and to the load, a second uninterruptible power supply, an inverter and a phase mismatch sensor of the power supplies are inserted, the inverter being connected to one of the three-phase inputs of the second uninterrupted power supply power supply, the phase error sensor is connected to the power supply phases, voltage form sensors and the switching command generation unit of the first uninterruptible power supply unit, the switching command generation units of both uninterruptible power supply units are connected to each other and to the synchronization input of the inverter connected to each other, connected capacitive filter compensator.

In the proposed system, if a working Power Source fails or fails, the load is directly transferred to the power supply from the backup source, if the sources are in phase, and firstly switched to the inverter with the operating source, and then after the synchronization of the inverter with the backup source to the single source. After the working source is restored, the load switches back to the working source.

The drawing shows a block diagram of the proposed uninterruptible power supply system.

The system contains power supply sources 1, inverter 2, phase mismatch sensor 3, uninterrupted power supply device 4, capacitive filter compensator 5, and load 6. Uninterruptible powering device 4 includes voltage form sensors 7, switching units 8 and switching command generation units 9 .

Sources 1 serve to supply the load with a variable three-phase toom, one of which is working and the other is backup.

The static inverter 2 is used to power the load when switching from source to source, it is constantly synchronized in phase with the working power source due to the connection between the blocks 9 to generate the switching command for both uninterruptible power supply devices and the synchronization input of the inverter 2.

The phase mismatch sensor 3 is designed to form a phase mismatch signal of the power sources, i.e. it sets, for any time, an in-phase or non-phase working and backup power sources and, in case of a working source failure, it gives a signal to blocks 9

developing a switching command to turn on the backup power source or inverter.

Uninterruptible power devices 4 are used to transfer the load according to a predetermined algorithm to a backup power source or an inverter.

Filter compensator 5 use to smooth out the residual noise that can pass to the input of the load when switching its power from source to source.

Each three-phase power source 1 is connected to the corresponding voltage sensor 7 and the switching unit 8 of the first uninterruptible power supply device 4. Phase-difference sensor 3 inputs are connected to the phases of both power sources 1 and the output of the command output unit 9 switching of the specified device 4. Two outputs of the specified block 9 are connected to the inputs of the switching blocks 8, and the third output is connected to the input of the similar block 9 of the second device 4 for uninterrupted power supply and time synchronization ation of the inverter 2 are connected to the inverter 2 sensor 7 forms a voltage switching unit 8 and the second device 4 for an uninterruptible power supply.

The specified sensor 7 is connected to a switching command generation unit 9 which is connected to a switching unit 8 of said second device 4. The outputs of all three switching units 8 are interconnected and connected to the inputs of the filter compensator 5 and the load 6.

During normal operation, the load is powered by the working source. If the working source fails, the voltage sensor 7 of the first uninterruptible power supply device 4, monitoring the operating power supply 1, outputs an alarm signal to the switching command generation unit 9 and the phase error sensor 3. If at the same time the working and backup sources are not in phase, then Chick 3 issues to block 9 of primary 4 a signal to turn on W 2. This block 9 generates a command to switch 8, disconnecting the working power supply to command 9 of the second device 4, which through the unit 8 of the second device 4 turns on the inverter 2, after which the load is received by the LT of the inverter.

Next, the inverter 2 is synchronized in phase with the backup power source and at the time of the arrival of the common mode, the inverter 2 is turned off and the backup power source is turned on.

If at the failure of the working source sensor.3 phase mismatch

establishes that the sources of naTerHaft are in-phase, then it issues in block 9 of the first device 4 a signal to turn on the backup source.

Unit 9 generates the corresponding commands in the switching units 8 of the first device 4, as a result of which the working source 1 is turned off and the backup source is turned on.

After restoring the working source of the source 1 sensor

0, the voltage form controlling its voltage ceases to give an alarm signal and the load power switches from the backup source to the working source in the reverse order,

5 i.e. by turning on the inverter, if the sources are non-phase, and immediately to the working source, if the sources are in phase.

Due to high speed

0 device 4 for uninterrupted power supply and availability of capacitance of filter-compensators 5 switching of common-mode sources proceeds in the proposed uninterruptible power supply system practically without a transition process in the load b.

In case of simultaneous failure of both power sources, the load for a long time may

0 powered by an inverter, which is also xa. It measures the proposed system as more reliable than the known one. In addition, due to its high speed, the system has time

5 also respond to short-term network interference, which increases the noise immunity of the load. In this case, the process of switching from the working source to the backup source and after passing the interference back to the working one occurs in the same way as described

above.

Thus, the use of the proposed invention allows to provide a reliable and reliable power supply.

45 losing your work; tt: ny ga pereklycheyi nag | 1zzki from an emergency source of power gag, g. jj j j jjjjggji

 rM r6KSk ril WS 1 Mpi8fi5 rsir

50 interference at the output of the power supply sources, thereby significantly reducing the network filtering requirements of consumers of the proposed power supply system and consumers who are not included in this power supply system.

Claims (1)

Invention Formula 60 An uninterruptible power supply system containing two power sources and an uninterruptible power supply unit consisting of voltage form sensors connected to the phases of the sources 65. Power and command generation unit -J -.- Chii :: vefta i iti Viii i -iii fcfts j