JP4568324B2 - Uninterruptible power supply system - Google Patents

Description

  The present invention relates to an uninterruptible power supply system having a function of preventing erroneous stoppage of a load during maintenance inspection work.

An uninterruptible power supply (hereinafter referred to as UPS) is widely applied as a stabilized power source for important load facilities, as compared to power supply insurance. For this reason, great care has been taken in operations such as maintenance and inspection work, and patent proposals for improving these have been made (see, for example, Patent Document 1). However, since the UPS itself is a complicated device, there are many cases in which the load is erroneously stopped due to human error.
JP-A-8-84444

  As described above, since UPS supplies power to important load facilities, there is an operation mode (maintenance inspection mode) in which inspection can be performed while supplying power. However, in this mode, some parts that cannot be inspected remain. To check this part, it is necessary to completely stop the UPS. This complete stop must be performed on the condition that all of the load side is stopped. However, as mentioned above, due to the complexity of the equipment, a part of the load accidentally stops the UPS side accidentally. May cause an abnormal stop of the load.

  An object of the present invention is to provide an uninterruptible power supply system that is interlocked so as not to be erroneously stopped when a load facility is operating.

  The uninterruptible power supply system according to the present invention has a main input terminal, a bypass input terminal, and an output terminal. The main input terminal is connected to the AC terminal of the converter for AC / DC conversion. Connect the DC terminal of the inverter for DC / AC conversion and the charge / discharge terminal of the storage battery. Between the AC terminal of the inverter and the bypass input terminal and the output terminal, the AC terminal side of the inverter An uninterruptible power supply device provided with an uninterruptible switching device for selectively switching between an electric circuit and the bypass input terminal side electric circuit, and a first provided on the input side of the bypass input terminal of the uninterruptible power supply device A first circuit breaker, a second circuit breaker provided between the output terminal and the load side, and a power supply side terminal of the first circuit breaker and a load side terminal of the second circuit breaker. Provided in the maintenance bypass circuit A maintenance bypass panel having three circuit breakers, a current detector for detecting a load current flowing in an electric path from the uninterruptible power supply device or the maintenance bypass panel to a load side, and the second circuit breaker being in the on state or the No load current is set as the openable condition of the third circuit breaker, the third breaker is turned on, or no load current is set as the openable condition of the second circuit breaker, And an interlock circuit in which the second circuit breaker is in the on state or the no load current is set as an openable condition of the first circuit breaker.

  According to the present invention, when the UPS is stopped and inspected, the interlock is configured so that there is no load current, that is, all loads are stopped. It is possible to reliably prevent erroneous stop during load operation.

  Hereinafter, an embodiment of an uninterruptible power supply system according to the present invention will be described in detail with reference to the drawings.

  FIG. 1 is a circuit diagram illustrating this embodiment. In FIG. 1, 11 is an uninterruptible power supply (hereinafter referred to as UPS), which has a main input terminal 11a, a bypass input terminal 11b, and an output terminal 11c. In this UPS 11, the AC terminal of the converter 12 for AC / DC conversion is connected to the main input terminal 11a. The DC terminal of the converter 12 is connected to the DC terminal of the inverter 13 for direct / acverse conversion and the charge / discharge terminal of the storage battery 14 to constitute the main circuit 11m.

  On the other hand, an uninterruptible switching device 15 is provided between the AC terminal of the inverter 13 and the bypass input terminal 11b and the output terminal 11c. This uninterruptible change-over switch 15 includes a switch 15a provided in the electric circuit on the main circuit 11m side including the inverter 13, a switch 15b provided in the bypass electric circuit 11s at the time of failure connected to the bypass input terminal 11b, and a parallel switch therewith. The bidirectional thyristor switch 15c is selectively switched between the main circuit 11m and the failure bypass circuit 11s without instantaneous interruption.

  A maintenance bypass board 17 includes a first circuit breaker 18, a second circuit breaker 19, and a third circuit breaker 20. The first circuit breaker 18 is provided between the bypass input terminal 11b of the uninterruptible power supply 11 and an AC power supply (not shown). Moreover, the 2nd circuit breaker 19 is provided between the said output terminal 11c and the load installation 22 side mentioned later. Further, the third circuit breaker 20 is connected to a maintenance bypass circuit 17a that connects the power supply side terminal (left side in the figure) of the first circuit breaker 18 and the load equipment 22 side terminal (right side in the figure) of the second circuit breaker 19. Is provided.

A current detector 23 is provided in the load facility 22 and detects a load current flowing in the electric path 21 from the uninterruptible power supply 11 or the maintenance bypass board 17 to the load side. In the load facility 22, the power supply circuit 21 is branched into a plurality of loads (not shown), and a power switch 24 is provided for each load. FIG. 2 shows the first circuit breaker 18 and the second circuit breaker. An interlock circuit for the device 19 and the third circuit breaker 20 is shown. FIG. 4A shows the opening condition of the third circuit breaker 20. The third circuit breaker 20 is set so that the second circuit breaker 19 can be opened on condition that the second circuit breaker 19 is in the on state or no load current (current detected by the current detector 23). FIG. 2B shows an open condition of the second circuit breaker 19. The second circuit breaker 19 is set so that the third circuit breaker 20 can be opened on condition that the third circuit breaker 20 is in the on state or no load current. FIG. 3C shows the opening condition of the first circuit breaker 18. The first circuit breaker 18 is set such that the third circuit breaker 20 can be opened on condition that the third circuit breaker 20 is turned on, the second circuit breaker 19 is turned on, or no load current.

  In the above configuration, the uninterruptible power supply system shown in FIG. 1 has the first circuit breaker 18 and the second circuit breaker 19 closed and the third circuit breaker 20 as shown in FIG. Is controlled to open. In this case, an input from an AC power source (commercial power source, etc.) not shown is converted into a direct current by a converter 12 constituting the main circuit 11m of the USP 11, as shown by a thick line, and a part of the input charges the storage battery 14 and others. Is reversely converted into alternating current by the inverter 13, output to the power supply circuit 21 through the switch 15 a and the second circuit breaker 19, and supplied to a load (not shown) through the power circuit breaker 24 of the load facility 22.

  When a power failure occurs with the AC power supply, the DC power from the converter 12 is not supplied in the UPS 11 as shown in FIG. At this time, the storage battery 14 is in a discharge state in which the power that has been charged is discharged, and maintains power supply to the load side through the inverter 13.

  When a failure occurs in the UPS 11, as shown in FIG. 5, the uninterruptible switch 15 operates to open the switch 15a provided in the main circuit 11m including the inverter 13, and to the bypass input terminal 11b. The switch 15b of the connected bypass electric circuit 11s at the time of failure and the bidirectional thyristor switch 15c in parallel therewith are turned on to switch the electric circuit, and the power supply from the AC power source to the load side without passing through the failure part of the UPS 11 To maintain. At the time of this switching, the bidirectional thyristor switch 15c is turned on at high speed with the opening operation of the switch 15a. In this case, because of the difference between the operating speeds of the two differences, the parallel state is instantaneously changed, so that the main circuit 11m can be switched to the failure bypass circuit 11s without causing a power interruption due to the opening operation of the switch 15a. Instantaneous interruption switching is performed. Thereafter, since the switch 15b that operates relatively slowly is closed, the bidirectional thyristor switch 15c is turned off to maintain power supply from the switch 15b to the load side.

  When the UPS 11 is inspected, as shown in FIG. 6, the third circuit breaker 20 is closed, the first circuit breaker 18 and the second circuit breaker 19 are opened, and power is supplied to the load side to maintain the bypass circuit. While maintaining through 17a, UPS 11 is stopped and inspected. That is, since the inside of the UPS 11 is in a no-voltage state, the inspection can be performed safely.

  However, when viewed from the entire uninterruptible power supply system, for example, an AC voltage is applied to the load side of the second circuit breaker 19 through the maintenance bypass circuit 17a, and the second circuit breaker 19 is inspected. It is difficult for safety. Thus, it is difficult to inspect the second circuit breaker 19 portion, that is, the outlet portion of the UPS 11 even when the UPS 11 shown in FIG. 6 is stopped. Normally, many outlets (not shown) are provided at the outlet portion of the UPS 11, and it is preferable that these portions can be inspected when the UPS 11 is stopped.

  Therefore, if the third circuit breaker 20 is opened, the second circuit breaker 19 will be in a non-voltage state, and these parts can be inspected. However, opening up to the third circuit breaker 20 means that the power supply to the load side is completely stopped, and as a condition for that purpose, all loads are stopped normally and the load equipment 22 is stopped. It is an absolute condition that all the power supply switches 24 provided in are opened and there is no load current. If a server of a certain system is operating as a load and the system is accidentally stopped completely and no power is supplied, the server will be stopped abnormally and a large amount of data will be lost.

  In general, when the entire uninterruptible power supply system including the above-described second circuit breaker 19 is inspected, first, the normal power supply state shown in FIG. 3 is shifted to the inspection mode described in FIG. In this case, the UPS 11 is stopped in a state where the power supply to the operating load is maintained. For this reason, the third circuit breaker 20 is closed and power is supplied from the maintenance bypass circuit 17a. However, if the third circuit breaker 20 is suddenly turned on and the maintenance bypass circuit 17a is utilized while the inverter 13 is in operation, even if the second circuit breaker 19 is opened, both circuits are temporarily in parallel. A cross current flows due to a difference in impedance between the inverter 13 side electric circuit and the maintenance bypass electric circuit 17a, and the inverter 13 becomes an overcurrent state.

  Therefore, while the inverter 13 is in operation, the failure connected to the bypass input terminal 11b from the main circuit 11m including the inverter 13 by the uninterruptible switch 15 without first turning on the third circuit breaker 20 first. When switching to the bypass electric circuit 11s at high speed. At this time, since there is no instantaneous switching, the main circuit 11m and the fault bypass circuit 11s are in parallel for a moment, and a cross current tends to flow due to the difference in impedance between the two. However, since the parallel time is extremely short, literally instantaneous, depending on the operating speed of the thyristor switch 15c, there is no influence of cross current. That is, the inverter 13 does not rip with an overcurrent.

  After switching from the main circuit 11m to the failure bypass circuit 11s, the main circuit 11m is controlled to stop and the third circuit breaker 20 is turned on, and the maintenance bypass circuit 17a is parallel to the failure bypass circuit 11s. Connect and supply power to the load side from both electric circuits. In this case, there is almost no difference in impedance between the bypass bypass circuit 11s and the maintenance bypass circuit 17a, and an excessive cross current does not flow between the two due to this parallel connection. Thereafter, the first circuit breaker 18 and the second circuit breaker 19 are opened at an arbitrary timing, and the power supply to the load side is maintained by the maintenance bypass electric circuit 17a (in the inspection mode state of FIG. 6).

  That is, in the state where the third circuit breaker 20 is closed and the power supply to the load side is maintained, the first circuit breaker 18 and the second circuit breaker 19 are opened to stop the UPS 11 to enable the inspection. Thereafter, the operating load is sequentially stopped while checking the UPS 11 itself. When all loads are stopped, after confirming that, the third circuit breaker 20 is opened, and the entire uninterruptible power supply system including the second circuit breaker 19 can be inspected.

  As described above, the third circuit breaker 20 is opened after confirming that all loads have stopped. However, if the inspection operator is not familiar with the UPS 11, the UPS 11 itself is already in the inspection mode. Therefore, there is a possibility that the third circuit breaker 20 is opened without confirming the stop of all loads. At this time, if even one of the loads is in operation, the load will stop abnormally, causing the problems described above.

  Therefore, the presence / absence of the load current flowing in the electric circuit 21 to the load side is detected by the current detector 23 provided in the load facility 22, and the interlock circuit shown in FIG. In other words, the interlock is set so that the uninterruptible power supply system cannot be completely stopped unless there is no load current as a system condition, in other words, all loads are not stopped.

  FIG. 2A shows the opening condition of the third circuit breaker 20. In this case, it is a premise that the third circuit breaker 20 is closed. If the second circuit breaker 19 is in the on state, the above-described failure bypass circuit 11s and the maintenance bypass circuit 17a are connected in parallel. It is in the state. Therefore, even if the third circuit breaker 20 is opened, the power supply from the bypass bypass circuit 11s is maintained, so that the third circuit breaker 20 can be opened.

  Further, even if the second circuit breaker 19 is not in the on state, that is, in the power supply state only by the maintenance bypass circuit 17a, all loads are stopped if there is no load current. There is no problem even if the third circuit breaker 20 is opened, and the third circuit breaker 20 can be opened.

  FIG. 2B shows an opening condition of the second circuit breaker 19. In this case, it is assumed that the second circuit breaker 19 is closed. If the third circuit breaker 20 is in the on state, the above-described failure bypass circuit 11s and the maintenance bypass circuit 17a are connected in parallel. In this state, even if the second circuit breaker 19 is opened, the power supply from the maintenance bypass circuit 17a is maintained, so that the second circuit breaker 19 can be opened.

  Even if the third circuit breaker 20 is not in the on state, that is, in the power supply state from the bypass bypass circuit 11s or the main circuit 11m, all loads are stopped if there is no load current. Therefore, there is no problem even if the second circuit breaker 19 is opened, and the second circuit breaker 19 can be opened.

  FIG. 2C shows an opening condition of the first circuit breaker 18. In this case, it is assumed that the first circuit breaker 18 is closed. If the third circuit breaker 20 is in the on state, the above-described failure bypass circuit 11s and the maintenance bypass circuit 17a are connected in parallel. In this state, even if the first circuit breaker 18 is opened, the power supply from the maintenance bypass circuit 17a is maintained, so that the first circuit breaker 19 can be opened.

  Even if the third circuit breaker 20 is not in the on state, if the second circuit breaker 19 is in the on state, the power supply from the main circuit 11m is maintained, so the first circuit breaker 19 can be opened. It becomes.

  Furthermore, even if either the second circuit breaker 19 or the third circuit breaker 20 is in the on state, that is, even if power is supplied from either the maintenance bypass circuit 17a or the main circuit 11m, the load current If there is none, all loads are stopped, so there is no problem even if the first circuit breaker 18 is opened, and the first circuit breaker 18 can be opened.

  As described above, the circuit breakers 18, 19, and 20 are opened under the condition that there is no load current, that is, all loads are stopped, and when there is load current, that is, the load is in operation. Then, by configuring the interlock on the condition that power is supplied from another electric circuit, it is possible to reliably prevent erroneous stop during load operation accompanying system inspection.

1 is a circuit diagram showing an embodiment of an uninterruptible power supply system according to the present invention. It is a logic circuit diagram which shows the interlock circuit used for one embodiment same as the above. It is a circuit diagram which shows the normal electric power feeding state of the uninterruptible power supply system by one Embodiment same as the above. It is a circuit diagram which shows the electric power feeding state at the time of a power failure of the uninterruptible power supply system by one Embodiment same as the above. It is a circuit diagram which shows the electric power feeding state at the time of UPS failure of the uninterruptible power supply system by one Embodiment same as the above. It is a circuit diagram which shows the electric power feeding state at the time of UPS check of the uninterruptible power supply system by one Embodiment same as the above.

Explanation of symbols

11 Uninterruptible power supply (UPS)
11a Main input terminal 11b Bypass input terminal 11c Common output terminal 12 Converter 13 Inverter 14 Storage battery 15 Uninterruptible switching machine 17 Maintenance bypass panel 18 First circuit breaker 19 Second circuit breaker 20 Third circuit breaker 21 Load side Electrical path to 23 Current detector

Claims (1)

It has a main input terminal, bypass input terminal, and output terminal. The main input terminal is connected to the AC terminal of the converter for AC / DC conversion, and the DC terminal of this converter is connected to the inverter for AC / DC conversion. A DC terminal and a charging / discharging terminal of the storage battery are connected, and the AC terminal side circuit of the inverter and the bypass input terminal side circuit are connected between the AC terminal of the inverter and the bypass input terminal and the output terminal. An uninterruptible power supply with an uninterruptible switching device that selects and switches between
A first circuit breaker provided on an input side of the bypass input terminal of the uninterruptible power supply, a second circuit breaker provided between the output terminal and a load side, and the first circuit breaker. A maintenance bypass panel having a third circuit breaker provided in a maintenance bypass circuit for connecting the power supply side terminal of the second circuit breaker and the load side terminal of the second circuit breaker;
A current detector for detecting a load current flowing in the electric path from the uninterruptible power supply or the maintenance bypass panel to the load side;
The second circuit breaker is in the on state or no load current is set as the openable condition of the third circuit breaker, and the third circuit breaker is in the on state or no load current is the second circuit breaker. The interlock circuit in which the third circuit breaker is turned on, the second circuit breaker is turned on, or no load current is set as the openable condition of the first circuit breaker. And an uninterruptible power supply system.

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