RU209253U1 - Uninterruptible power supply with the possibility of energy recovery - Google Patents

Abstract

The utility model relates to the field of electrical engineering and can be used in power supply systems of enterprises and transport, providing for energy recovery by power receivers. The objective of the utility model is to increase the energy efficiency of an uninterruptible power supply by accumulating the electricity recuperated by the load in a capacitor bank. The problem is solved by the fact that in an uninterruptible power supply with the possibility of energy recovery, operating in the double conversion mode of electricity and containing a bidirectional rectifier-inverter voltage converter, the input terminals of which are connected to the AC mains, and its output terminals are connected via a DC bus to the input inverter and through the first charger-discharge device to the battery, the output of the inverter is connected to the load, a capacitor bank and a second charger-discharge device are introduced, the input terminals of which are connected to the DC bus, and its output terminals are connected to the capacitor bank.

Description

The utility model relates to the field of electrical engineering and can be used in power supply systems of enterprises and transport, providing for energy recovery by power receivers.

Known uninterruptible power supply complex for testing secondary DC power sources with energy recovery in the DC network [RU 129263, IPC G01R 31/40 publ. 06/20/2013 Bull No. 17], containing an uninterruptible power supply operating in the double energy conversion mode, a secondary power supply under test and several modules of a regenerative type load device, and their energy is returned to the DC circuit and charges the battery of the uninterruptible power supply.

The disadvantages of an uninterruptible power supply are: the need to use a special uninterruptible power supply that allows you to connect a regenerative type load device to it, the complexity and cost of the source, as well as its low reliability and efficiency.

Closest to the claimed utility model is an uninterruptible power supply with the possibility of energy recovery [RU 166567 U1, IPC H02J 9/00, H02H 3/00 publ. 12/10/2016 Bull No. 34], selected as a prototype, operating in the double conversion mode of electricity and containing a bidirectional rectifier-inverter voltage converter, the input terminals of which are connected to the AC network, and its output terminals are connected via a DC bus to the input of the inverter and through the first charger-discharge device to the storage battery, the output of the inverter is connected to the load, characterized in that a capacitor bank and a second charger-discharge device are introduced into it, the input terminals of which are connected to the DC bus, and its output terminals are connected to the capacitor bank.

The disadvantage of this uninterruptible power supply with the possibility of energy recovery is low energy efficiency due to significant losses of electricity in the block of ballast resistors during energy recovery by the load and if it is impossible to accept this electricity by the battery.

The objective of the utility model is to increase the energy efficiency of an uninterruptible power supply by accumulating electricity in a capacitor bank recuperated by the load and further using it by the load, as well as when charging the battery.

The problem is solved by the fact that in an uninterruptible power supply with the possibility of energy recovery, operating in the double conversion mode of electricity and containing a bidirectional rectifier-inverter voltage converter, the input terminals of which are connected to the AC mains, and its output terminals are connected via a DC bus to the input inverter and through the first charger-discharge device to the battery, the output of the inverter is connected to the load, a capacitor bank and a second charger-discharge device are introduced, the input terminals of which are connected to the DC bus, and its output terminals are connected to the capacitor bank.

Further, the essence of the proposed utility model is explained with the help of a figure, which shows a block diagram of an uninterruptible power supply with the possibility of energy recovery from a regenerative load.

The uninterruptible power supply contains an AC network 1, to which a bidirectional rectifier-inverter voltage converter 2, a DC bus 3, an inverter 4 and a load 5 are connected in series. The DC bus is connected through the first charger-discharge device 6 to the storage battery 7, and also connected through the second charger-discharge device 8 with the capacitor bank 9.

The uninterruptible power supply can operate both in the presence and absence of voltage in the AC network 1. Load 5 can be active and regenerating.

The operation of the proposed uninterruptible power supply is as follows.

First mode. All elements of the uninterruptible power supply are in a normal state, the load 5 is active, there is voltage in the AC network 1, which is supplied to the bidirectional rectifier-inverter voltage converter 2 and is converted into a constant rectified and stabilized voltage at its output. This voltage is supplied to the input of inverter 4 via the DC bus and is converted into an alternating stabilized voltage at the output of inverter 4. Therefore, this voltage is supplied to the receivers of the load alternating voltage 5. The active power consumed by the load is transferred from the alternating current network 1 through the converter 2, DC bus 3 and inverter 4.

The constant rectified and stabilized voltage on the tires 3 is also supplied to the first charger-discharge device 6, which provides, in accordance with a given algorithm, charging or recharging the battery 7. In the same mode, the voltage on the DC buses 3 is supplied to the second charger-discharge device. device 8, which provides recharging of the capacitor bank 9 to a predetermined value of the stored energy of direct voltage.

Second mode. AC mains 1 is working properly. The difference from the first mode is that load 5 is regenerative. AC electrical power recuperated by load 5 is converted by inverter 4 into DC electrical power and is supplied via DC bus 3 to bidirectional rectifier-inverter converter 2, which converts it in inverting mode into AC active electrical power and regenerates it into AC network. current 1. In this case, the first 6 and second 8 charger-discharge devices, the battery 7 and the capacitor battery 9 work similarly to their work in the first mode.

Third mode. The AC mains 1 is off and therefore out of operation of the uninterruptible power supply. The nature of the load 5 is active and all the power consumed by the load 5 is provided by the storage battery 7 pre-charged during the normal operation of the AC mains 1, for example, the first or second modes. The DC voltage power of the storage battery 7 is supplied through the first charger-discharge device 6 and the DC bus 3 to the input of the inverter 4, which converts it into AC voltage power and transmits it to the load AC voltage 5 power receivers.

fourth mode. AC mains 1 is out of service, as in the third mode. The nature of the load 5 is active, the storage battery 7 is out of service due to discharge, malfunction or maintenance. In this case, the entire power consumed by the load 5 is provided by the capacitor bank 9, pre-charged during normal operation of the AC supply network 1. The DC voltage power of the capacitor bank 9 is supplied through the second charger-discharge device 8 and the DC bus 3 to the input of the inverter 4 , which converts it into AC power and transfers it to load 5.

Fifth mode. AC mains 1 is out of service, as in the third mode. The nature of the load 5 is active, the storage battery 7 and the capacitor bank 9 are charged. The power consumed by load 5 is provided simultaneously by battery 7 and capacitor 9 batteries through, respectively, the first 6 and second 8 chargers, DC bus 3 and inverter 4.

sixth mode. AC mains 1 is out of service, as in the third mode. The nature of the load 5 is recuperative. AC electrical power recovered by load 5 is converted by inverter 4 into DC electrical power and is supplied via DC bus 3 to first 6 and second 8 charger-discharge devices. This power from the DC bus 3 is transmitted by the first 6 and second 8 chargers, respectively, to the storage battery 7 or the capacitor bank 9 or simultaneously to both batteries 7 and 9, depending on their pre-charge.

As a result, all the electrical energy recuperated by the load 5, except for minor losses in the elements 3, 4, 6 and 8 of the uninterruptible power supply, is accumulated in the battery 7 and capacitor 9 batteries and is used by AC power receivers when the load 5 switches to active mode. This will significantly increase the energy efficiency of an uninterruptible power supply with the possibility of energy recovery by a load with AC power receivers.

Claims (1)

Uninterruptible power supply with the possibility of energy recovery, operating in the mode of double conversion of electricity and containing a bidirectional rectifier-inverter voltage converter, the input terminals of which are connected to the AC mains, and its output terminals are connected via a DC bus to the input of the inverter and through the first charge-discharge device to the storage battery, the output of the inverter is connected to the load, characterized in that a capacitor bank and a second charge-discharge device are introduced into it, the input terminals of which are connected to the DC bus, and its output terminals are connected to the capacitor bank.

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