JP2014087086A - Uninterruptible power supply device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To surely maintain power supply even when a fault occurs in a converter which obtains single-phase AC.SOLUTION: An uninterruptible power supply device comprises: a converter 12 for converting three-phase AC power to DC power; a storage battery 15 for storing the DC power outputted by the converter 12; an inverter 13 for converting the DC power outputted by the storage battery 15 to three-phase AC power; a first Scott transformer 16 for converting the three-phase AC power outputted by the inverter 13 to two-phase AC power; a second Scott transformer 19 for converting three-phase AC power for bypass use to two-phase AC power; a first uninterruptible switching circuit 17 for selectively switching the first single-phase AC power outputted by the first or the second Scott transformer 16, 19 and outputting the selected AC power; and a second uninterruptible switching circuit 18 for selectively switching the second single-phase AC power outputted by the first or the second Scott transformer 16, 19 and outputting the selected AC power.

Description

  The present invention relates to an uninterruptible power supply.

  A three-phase AC output is generally used in an uninterruptible power supply (hereinafter referred to as “UPS”) having a rated output capacity of about 100 [kVA] or more. Therefore, when a single-phase AC output is required with a UPS of the same capacity, a Scott transformer is provided after the output of the UPS.

  For this reason, when a malfunction occurs in the Scott transformer, there is a problem that power supply to the load side that requires a single-phase output is immediately stopped.

  By the way, a technique is known in which the current balance state on the commercial power supply side can be maintained even if the UPS fails and switches to the bypass power supply path side. (For example, Patent Document 1)

Japanese Patent Laid-Open No. 04-304125

  Also in the technique described in Patent Document 1, when a single-phase AC output is required, a Scott transformer is provided at the subsequent stage of the output as described above. Therefore, when a malfunction occurs in the Scott transformer itself, the problem that the power supply to the load side stops immediately is still not solved.

  The object of the present invention has been made in view of the above circumstances, and the object of the present invention is to reliably maintain power supply even in the case of a malfunction in a converter for obtaining a single-phase alternating current. Is to provide a simple uninterruptible power supply.

  An uninterruptible power supply according to an aspect of the present invention includes a converter that converts three-phase AC power into DC power, a storage battery that stores DC power output from the converter, and three-phase AC power that is output from the storage battery. An inverter that converts power, a first Scott transformer that converts three-phase AC power output from the inverter into two-phase AC power, and three-phase AC power for bypass input through a path that does not go through the inverter A second Scott transformer for converting into two-phase AC power, and a first single-phase AC power output from the first Scott transformer or a first single-phase AC power output from the second Scott transformer And a second single-phase AC power output from the first Scott transformer or a second single-phase output from the second Scott transformer. Phase AC Characterized in that the equipped with a second MuMadoka sever circuit for outputting selectively switched.

  ADVANTAGE OF THE INVENTION According to this invention, even when a malfunction arises in the converter for obtaining a single phase alternating current, the uninterruptible power supply device which can maintain supply of electric power reliably can be provided.

The block diagram which shows the circuit structure of the uninterruptible power supply which concerns on 1st Embodiment. The block diagram which shows the circuit structure of the uninterruptible power supply which concerns on 2nd Embodiment, and an input-output panel.

Hereinafter, embodiments will be described in detail with reference to the drawings.
(First embodiment)
FIG. 1 is a block diagram showing a basic functional circuit configuration of an uninterruptible power supply (UPS) 10 according to the first embodiment. The uninterruptible power supply 10 is a panel-type device housed in a housing.

  Three-phase AC power supplied to the terminal T1 is supplied to the converter 12 via the contactor 11. Contactor 11 interrupts the power supplied to converter 12. The converter 12 rectifies the supplied three-phase AC power into DC. The DC power output from the converter 12 is supplied to the inverter 13 and also to the storage battery 15 connected to the terminal T3 via the contactor 14.

  The storage battery 15 is a DC power supply, and supplies DC power to the uninterruptible power supply 10 at the time of a power failure when the three-phase AC power supplied to the terminal T1 is interrupted. The contactor 14 intermittently connects the DC power supplied from the storage battery 15.

  The inverter 13 converts the DC power supplied from the converter 12 or the storage battery 15 into three-phase AC power and outputs it to the Scott transformer 16.

  The Scott transformer 16 converts the given three-phase AC power into two-phase AC power, and switches the first single-phase AC power to the uninterruptible switching circuit 17 and the second single-phase AC power to the uninterruptible switching. Each is output to the circuit 18.

  On the other hand, a three-phase AC power supply is applied to a bypass terminal T2 provided in parallel with the terminal T1. The three-phase AC power supplied to the terminal T2 is a power source for supplying power to the uninterruptible switching circuit 17 and the uninterruptible switching circuit 18.

  The three-phase AC power supplied to the terminal T2 is supplied to the Scott transformer 19.

  The Scott transformer 19 converts the given three-phase AC power into two-phase AC power, and converts the first single-phase AC power to the uninterruptible switching circuit 17 and the second single-phase AC power to the uninterruptible power. Each is output to the disconnection switching circuit 18.

  In the uninterruptible switching circuit 17, the first single-phase AC power from the Scott transformer 16 is applied to one end of the contactor 17a. The first single-phase AC power from the Scott transformer 19 is supplied to one end of the contactor 17b and one end of the thyristor switch 17c. The other ends of the contactors 17a and 17b and the thyristor switch 17c are connected to a terminal T4 for supplying single-phase AC power to the load.

  In the uninterruptible switching circuit 18, the second single-phase AC power from the Scott transformer 16 is applied to one end of the contactor 18a. The second single-phase AC power from the Scott transformer 19 is supplied to one end of the contactor 18b and one end of the thyristor switch 18c. The other ends of the contactors 18a and 18b and the thyristor switch 18c are connected to a terminal T5 for supplying single-phase AC power to a load as a bypass power source.

Next, the operation of the embodiment will be described.
In normal times when no power failure occurs, the three-phase AC power supplied from the terminal T1 is converted into DC power by the converter 12 via the contactor 11. The DC power output from the converter 12 charges the storage battery 15 via the contactor 14 and the terminal T3, and is again converted into three-phase AC power by the inverter 13 and is supplied to the Scott transformer 16.

  Then, the first single-phase AC power output from the Scott transformer 16 is selected via the contactor 17a of the uninterruptible switching circuit 17, and is supplied from the terminal T4 to the subsequent load.

  In the event of a power failure, the DC power charged in the storage battery 15 connected so far is converted into three-phase AC power by the inverter 13 via the terminal T3 and the contactor 14, and is supplied to the Scott transformer 16.

  Then, the first single-phase AC power output from the Scott transformer 16 is selected via the contactor 17a of the uninterruptible switching circuit 17, and is supplied from the terminal T4 to the subsequent load.

  If the converter 12 or the inverter 13 fails or at least one of the converter 12 and the inverter 13 does not operate normally due to maintenance work of the uninterruptible power supply 10, the power is supplied from the bypass terminal T2 and the Scott transformer 19 One of the two-phase AC power is switched by the uninterruptible switching circuit 17 and supplied to the subsequent load via the terminal T4.

Further, when a malfunction occurs in the Scott transformer 16, it may be any of a normal time when no power failure occurs, an emergency when a power failure occurs, and a case where at least one of the converter 12 and the inverter 13 does not operate normally. The single-phase AC power supplied from the bypass terminal T2 and converted into the two-phase AC by the Scott transformer 19 is selected and switched by the uninterruptible switching circuit 17 or the uninterruptible switching circuit 18, and the terminal T4 Alternatively, it is supplied to a subsequent load via a terminal T5.
The switching of the uninterruptible switching circuit 17 or the uninterruptible switching circuit 18 in this case is set in advance by a control circuit (not shown) of the uninterruptible power supply 10.

Further, when a malfunction occurs in the Scott transformer 19 on the bypass side, the DC power is converted into DC power by the converter 12 using the three-phase AC power supplied from the terminal T1, similarly to the normal time when the power failure does not occur, and the inverter 13 is converted into two-phase AC power by the Scott transformer 16, and the single-phase AC power is selected by the uninterruptible switching circuit 17 or the uninterruptible switching circuit 18. Switching and supplying to the subsequent load through the terminal T4 or the terminal T5.
Switching of the uninterruptible switching circuit 17 or the uninterruptible switching circuit 18 in this case is also set in advance by a control circuit (not shown) of the uninterruptible power supply 10.

  Further, in the event of a failure in the bypass-side Scott transformer 19 and a power failure, the DC power that has been charged in the storage battery 15 until then is transferred to the three-phase AC power by the inverter 15 via the terminal T3 and the contactor 14. To the Scott transformer 16.

  Then, the first single-phase AC power output from the Scott transformer 16 is selected via the contactor 17a of the uninterruptible switching circuit 17, and is supplied from the terminal T4 to the subsequent load.

  As described above in detail, in this embodiment, the Scott transformer 16 is duplicated by the Scott transformer 16 provided on the path side through the inverter 13 and the Scott transformer 19 provided on the bypass path side, and is duplicated according to this. The configuration is such that the uninterruptible switching circuits 17 and 18 are used.

  As a result, the converter 12 and the inverter 13 in the uninterruptible power supply 10 and the plurality of circuits of the Scott transformer 16 and the uninterruptible switching circuit 18 are surely connected with the power to the load. The supply can be maintained.

(Second Embodiment)
FIG. 2 is a block diagram illustrating a configuration of a functional circuit of the uninterruptible power supply (UPS) 30 according to the second embodiment. Here, the uninterruptible power supply 30 is installed in the power supply facility together with the input / output panel 40 for maintenance and inspection in the same manner as a general uninterruptible power supply.

  The individual components in the uninterruptible power supply 30 are basically the same as those of the uninterruptible power supply 10 shown in FIG. Omitted.

  In the uninterruptible power supply 30, the configuration of the Scott transformer 19 in the uninterruptible power supply 10 of FIG. 1 is abolished, and AC power already single-phased is input from terminals T2a and T2b, respectively, and the uninterruptible switching is performed. It is assumed that the signal is supplied to the circuit 17 and the uninterruptible switching circuit 18.

  In one input / output panel 40, the three-phase AC power supplied to the terminal T6 is led out from the terminal T8 via the contactor 41 and supplied to the terminal T1 of the uninterruptible power supply 30.

  The bypass and maintenance three-phase AC power supplied to the terminal T7 is supplied to the Scott transformer 42 instead of the Scott transformer 19 of FIG.

  The Scott transformer 42 converts the supplied three-phase AC power into two-phase AC power, and derives the first single-phase AC power from the terminal T9a via the contactor 43 and supplies it to the terminal terminal T2a. The second single-phase AC power is derived from the terminal T9b via the contactor 44 and supplied to the terminal terminal T2b.

  In addition, the Scott transformer 42 supplies the first single-phase AC power to a load (not shown) from the terminal T12 via the maintenance bypass line 45a and the contactor 46, and also supplies the second single-phase AC power, The load is supplied from a terminal T13 to a load (not shown) via the maintenance bypass line 45b and the contactor 47.

  Furthermore, the single-phase AC power output from the terminal T4 of the uninterruptible power supply 30 is derived from the terminal T12 via the contactor 48 via the terminal T10 of the input / output panel 40 and supplied to a load (not shown). Is done.

  The single-phase AC power output from the terminal T5 of the uninterruptible power supply 30 is derived from the terminal T13 via the contactor 49 via the terminal T11 of the input / output panel 40 and supplied to a load (not shown). .

Next, the operation of the embodiment will be described.
During normal times when no power failure occurs, the three-phase AC power derived from the terminal T6 of the input / output panel 40 via the contactor 41 and added from the terminal T1 and further supplied from the terminal T1 of the uninterruptible power supply 30 is transmitted via the contactor 11. Then, the converter 12 converts it into DC power. The DC power output from the converter 12 charges the storage battery 15 via the contactor 14 and the terminal T3, and is again converted into three-phase AC power by the inverter 13 and is supplied to the Scott transformer 16.

  And the 1st single phase alternating current power which the Scott transformer 16 outputs is selected via the contactor 17a of the uninterruptible switching circuit 17, and is output from the terminal T4.

  In the input / output panel 40, the single-phase AC power from the uninterruptible power supply 30 is output from the terminal T12 via the contactor 48 from the terminal T10 and supplied to the subsequent load.

  In the event of a power failure, the DC power previously charged in the storage battery 15 connected to the uninterruptible power supply 30 is converted into three-phase AC power by the inverter 13 via the terminal T3 and the contactor 14, and the Scott transformer 16 is given.

  And the 1st single phase alternating current power which the Scott transformer 16 outputs is selected via the contactor 17a of the uninterruptible switching circuit 17, and is output from the terminal T4.

  In the input / output panel 40, the single-phase AC power from the uninterruptible power supply 30 is output from the terminal T12 via the contactor 48 from the terminal T10 and supplied to the subsequent load.

  Further, when the converter 12 or the inverter 13 of the uninterruptible power supply 30 fails or at least one of the converter 12 and the inverter 13 does not operate normally due to maintenance work of the uninterruptible power supply 30, the Scott transformer of the input / output panel 40 The two-phase AC power output from the terminal 42 is output from the terminals T9a and T9b via the contactors 43 and 44, and is supplied to the uninterruptible power supply 30 via the terminals T2a and T2b of the uninterruptible power supply 30.

  In the uninterruptible power supply 30, the single uninterruptible switching circuit 17 selects and switches one single-phase AC power supplied through the bypass terminal T2a out of these supplied powers, via the terminal T4. Output.

  In the input / output panel 40, the single-phase AC power from the uninterruptible power supply 30 is output from the terminal T12 via the contactor 48 from the terminal T10 and supplied to the subsequent load.

  Further, when a failure occurs in the Scott transformer 16 of the uninterruptible power supply 30, a normal time when no power failure occurs, an emergency when a power failure occurs, and at least one of the converter 12 and the inverter 13 does not operate normally. In any case, one single-phase AC power supplied from the bypass terminals T2a and T2b and converted into a two-phase AC by the Scott transformer 42 of the input / output panel 40 is used for the uninterruptible switching circuit 17. Alternatively, the uninterruptible switching circuit 18 selects and switches and outputs via the terminal T4 or the terminal T5.

  In the input / output panel 40, the single-phase AC power from the uninterruptible power supply 30 is output from the terminal T10 or the terminal T11 via the contactor 48 or 49 from the terminal T12 or T13 and supplied to the subsequent load.

  In this case, switching of the uninterruptible switching circuit 17 or the uninterruptible switching circuit 18 in the uninterruptible power supply 30 is set in advance by a control circuit (not shown) of the uninterruptible power supply 30.

Further, when a malfunction occurs in the Scott transformer 42 of the input / output panel 40, the three-phase AC power supplied from the terminal T1 by the uninterruptible power supply 30 is used as in the normal time when the power failure does not occur. The converter 12 converts the DC power into three-phase AC power by the inverter 13 and converts it to two-phase AC power by the Scott transformer 16. One of the single-phase AC power is converted to the uninterruptible switching circuit 17 or the instantaneous The disconnection switching circuit 18 selects and switches, outputs it to the input / output panel 40 via the terminal T4 or the terminal T5, and supplies it to the subsequent load.
The switching of the uninterruptible switching circuit 17 or the uninterruptible switching circuit 18 in the uninterruptible power supply 30 in this case is also set in advance by a control circuit (not shown) of the uninterruptible power supply 30.

  Further, in the event of a failure in the Scott transformer 42 of the input / output panel 40 and a power failure, the DC power that has been charged in the storage battery 15 connected to the uninterruptible power supply 30 is connected to the terminal T3, It is converted into three-phase AC power by the inverter 15 via the contactor 14 and given to the Scott transformer 16.

  And the 1st single phase alternating current power which the Scott transformer 16 outputs is selected via the contactor 17a of the uninterruptible switching circuit 17, and is output from the terminal T4.

  In the input / output panel 40, the single-phase AC power from the uninterruptible power supply 30 is output from the terminal T12 via the contactor 48 from the terminal T10 and supplied to the subsequent load.

  As described above in detail, in this embodiment, in addition to the configuration shown in the first embodiment, a Scott transformer 42 provided on the input / output panel 40 side outputs an output from the input / output panel 40 via a maintenance bypass. Thus, the Scott transformer for obtaining two single-phase AC powers and the Scott transformer for obtaining two single-phase AC powers as bypass power sources in the uninterruptible power supply 30 are combined.

  As a result, it is possible to reliably maintain the supply of power to the load while further simplifying the configuration of the entire facility including the uninterruptible power supply 30 and the input / output panel 40 which is an incidental facility thereof.

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and the equivalents thereof.

  DESCRIPTION OF SYMBOLS 10 ... Uninterruptible power supply device, 11 ... Contactor, 12 ... Converter, 13 ... Inverter, 14 ... Contactor, 15 ... Storage battery, 16 ... Scott transformer, 17 ... Uninterruptible switching circuit, 17a, 17b ... Contactor, 17c ... Thyristor 18 ... uninterruptible switching circuit, 18a, 18b ... contactor, 18c ... thyristor switch, 19 ... Scott transformer, 30 ... uninterruptible power supply, 40 ... I / O panel, 41 ... contactor, 42 ... Scott transformer, 43, 44 ... contactors, 45a, 45b ... maintenance bypass lines, 46-48 ... contactors, T1, T2, T2a, T2b, T3-T8, T9a, T9b, T10-T13 ... terminals.

Claims (2)

A converter that converts three-phase AC power into DC power;
A storage battery for storing DC power output by the converter;
An inverter that converts the DC power output from the storage battery into three-phase AC power;
A first Scott transformer that converts three-phase AC power output from the inverter into two-phase AC power;
A second Scott transformer that converts three-phase AC power for bypassing that is input through a path not through the inverter into two-phase AC power;
First uninterrupted switching for selectively switching and outputting the first single-phase AC power output from the first Scott transformer or the first single-phase AC power output from the second Scott transformer. Circuit,
Second uninterrupted switching for selectively switching and outputting the second single-phase AC power output from the first Scott transformer or the second single-phase AC power output from the second Scott transformer And an uninterruptible power supply. A converter that converts three-phase AC power into DC power;
A storage battery for storing DC power output by the converter;
An inverter that converts the DC power output from the storage battery into three-phase AC power;
A first Scott transformer that converts three-phase AC power output from the inverter into two-phase AC power;
A second Scott transformer for converting three-phase AC power input through a bypass path not passing through the inverter into two-phase AC power;
A maintenance path for transmitting the first and second single-phase AC power output by the second Scott transformer;
First uninterrupted switching for selectively switching and outputting the first single-phase AC power output from the first Scott transformer or the first single-phase AC power output from the second Scott transformer. Circuit,
Second uninterrupted switching for selectively switching and outputting the second single-phase AC power output from the first Scott transformer or the second single-phase AC power output from the second Scott transformer And an uninterruptible power supply.

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