JP7086655B2 - Uninterruptible power system update method - Google Patents

Description

The present embodiment relates to an uninterruptible power supply system, an uninterruptible power supply monitoring device, and a program for an uninterruptible power supply system, which correspond to an update method and an update method of an uninterruptible power supply system that supplies power when a power system fails.

Load equipment such as broadcasting equipment of broadcasting stations, Internet data centers, banks, and online systems of securities companies are required to be continuously supplied with constant voltage and constant frequency power as a power source. In recent years, the importance of information infrastructure has increased, and many load facilities that operate without power outages have become widespread. Therefore, there is an increasing demand for an uninterruptible power supply system that supplies power to load equipment without power failure.

When the power applied to the commercial power supply is stopped, the uninterruptible power supply system converts the DC power discharged from the storage battery into AC power and supplies the AC power to the load facility without interruption. Such a non-disruptive power supply system has an AC / DC conversion unit that converts the supplied AC power into AC / DC, a storage battery that is charged by the DC power supplied from the AC / DC conversion unit, and a DC power that is discharged from the storage battery. It has a DC-AC converter that converts DC-AC and outputs AC power.

Japanese Unexamined Patent Publication No. 2014-222982

An uninterruptible power supply system as described above requires a system update due to aging or a system update due to a failure. An uninterruptible power supply system is a system for supplying power to a load without a power failure, and it is not desirable that a power failure occurs even when the system is updated.

On the other hand, an uninterruptible power supply system is often composed of a plurality of uninterruptible power supplies. The uninterruptible power supply that is the target of the system update is aging, and generally, the distortion of the output waveform is larger than that of the newly installed uninterruptible power supply. Therefore, when the newly installed uninterruptible power supply and the uninterruptible power supply to be updated are operated in cooperation with each other, the output waveforms of both devices are different, so that unnecessary current flows between the outputs of both devices. There was a possibility. There is a problem that such an unnecessary current may cause inconvenience such as heat generation.

For this reason, conventionally, when updating an uninterruptible power supply system, the work of preparing the same number of new uninterruptible power supplies as the number of uninterruptible power supplies to be updated and switching to the new uninterruptible power supply at the same time has been performed. .. However, when switching to the new uninterruptible power supply at the same time, there is a problem that sufficient installation space for installing the new uninterruptible power supply may not be secured.

In view of the above problems, this embodiment is an uninterruptible power supply system and an uninterruptible power supply monitoring device corresponding to an uninterruptible power supply system update method and an update method that can be updated even when sufficient installation space cannot be secured. , The purpose of which is to provide a program for an uninterruptible power supply system.

The uninterruptible power supply system updating method of the present embodiment is characterized by having the following procedure.
(1) The first new uninterruptible power supply, which is smaller than the existing uninterruptible power supply installed in the installation space and satisfies the power supply to the load, is replaced with the existing uninterruptible power supply. The first step of installing in a temporary space so that it is electrically connected in parallel.
(2) A second procedure in which power is supplied from the newly installed uninterruptible power supply to the load and the existing uninterruptible power supply is removed from the installation space.
(3) Install a second new uninterruptible power supply in the installation space so that it is electrically connected in parallel with the first new uninterruptible power supply installed in the temporary space in the first procedure. Third step.
(4) The first new uninterruptible power supply installed in the temporary space so as to be electrically connected in parallel with the second new uninterruptible power supply installed in the installation space in the third procedure. A fourth step of moving at least one of the devices to the installation space.

The present embodiment also includes an uninterruptible power supply system, a monitoring device for an uninterruptible power supply, and a program for an uninterruptible power supply system corresponding to the above-mentioned uninterruptible power supply system update method.

The figure which shows the uninterruptible power supply system which concerns on 1st Embodiment The figure which shows the structure of the uninterruptible power supply device which concerns on 1st Embodiment The figure which shows the structure of the monitoring apparatus which concerns on 1st Embodiment The figure which shows the procedure of the uninterruptible power supply system update method concerning 1st Embodiment. The figure which shows the program flow of the monitoring measures concerning 1st Embodiment

[1. First Embodiment]
[1-1. Constitution]
The uninterruptible power supply system 1 as an example of the present embodiment will be described with reference to FIGS. 1 to 3.

(1) Overall Configuration of Uninterruptible Power Supply System 1 This uninterruptible power supply system 1 has a plurality of uninterruptible power supply devices 2 and monitoring devices 5. As an example, the uninterruptible power supply system 1 has three uninterruptible power supply devices 2a, 2b, 2c and a monitoring device 5. In the present embodiment, a case where the existing uninterruptible power supply devices 2d, 2e, and 2f are updated with the newly installed uninterruptible power supply devices 2a, 2b, and 2c will be described. The uninterruptible power supply 2b and 2c correspond to the first new uninterruptible power supply in the claim, and the uninterruptible power supply 2a corresponds to the second new uninterruptible power supply in the claim.

In the present embodiment, when there are a plurality of devices and members having the same configuration, they are given the same number and described, and when each device and member having the same configuration are described, they are common. Distinguish by adding alphabetic (lowercase) letters to the numbers. The three new uninterruptible power supply devices 2a, 2b, 2c and the three existing uninterruptible power supply devices 2d, 2e, and 2f in the present embodiment have the same configuration.

In the uninterruptible power supply system 1, the following data is transmitted, received, created, and stored.
Output power W: Data related to the power output from the uninterruptible power supply 2 Required power supply WT: Power required to be supplied to the load 8 Battery remaining amount R: Data related to the remaining amount of the storage battery 22 Supplyable time TA: No power failure Supplyable time during which power can be supplied from the storage battery 22 of the power supply device 2 preset time TS

The uninterruptible power supply 2 is connected to the power system 9. The power system 9 is connected to the commercial power supply 92. The uninterruptible power supply 2 receives commercial power from the commercial power supply 92 via the power supply line 91 of the power system 9. The AC power output from the uninterruptible power supply 2 is supplied to the load 8.

The existing uninterruptible power supplies 2d, 2e, and 2f before the update are electrically connected in parallel to each other, and the input side is electrically connected to the power supply line 91 of the power system 9 and the output side is electrically connected to the load 8. Further, the new uninterruptible power supplies 2a, 2b, and 2c after the update is completed are electrically connected in parallel to each other, and the input side is electrically connected to the power supply line 91 of the power system 9 and the output side is electrically connected to the load 8. Will be done.

(2) Configuration of Uninterruptible Power Supply Device 2 The configuration of the uninterruptible power supply device 2 is shown in FIG. The non-disruptive power supply device 2 is a power supply device that converts the AC power supplied from the power supply line 91 into DC power to charge the storage battery, converts the DC power discharged from the storage battery into AC power, and outputs the DC power to the load 8. be. The uninterruptible power supply 2 includes an AC / DC conversion unit 21, a storage battery 22, a DC / AC conversion unit 23, a bypass circuit 24, an input terminal 25, an auxiliary input terminal 26, an output terminal 27, a measurement unit 31, a detection unit 32, and a transmission / reception unit 33. Has. The uninterruptible power supply 2 is installed in a distribution room or the like of a power consumer.

The input terminal 25 is connected to the power supply line 91, and AC power is supplied. A load 8 is connected to the output terminal 27, and AC power is supplied to the load 8 from the uninterruptible power supply device 2. AC power for backup is supplied to the auxiliary input terminal 26.

(AC / DC converter 21)
The AC / DC conversion unit 21 is composed of a converter that converts AC power into DC power. The converter constituting the AC / DC conversion unit 21 has a switching element such as a transistor, and by switching the switching element, the AC power is converted into DC power.

The AC / DC conversion unit 21 is installed in the vicinity of the storage battery 22. The AC / DC conversion unit 21 is connected to the power supply line 91 on the AC side via the input terminal 25, and to the storage battery 22 and the DC / AC conversion unit 23 on the DC side.

The AC / DC conversion unit 21 converts the AC power supplied from the power supply line 91 via the input terminal 25 into DC power, and supplies the DC power to the storage battery 22 and the DC / AC conversion unit 23.

(Battery 22)
The storage battery 22 is a rechargeable power storage device that charges a charge applied to the supplied DC power and discharges the charged charge as DC power. The storage battery 22 is configured by combining a plurality of rechargeable batteries such as a lithium secondary battery. The storage battery 22 is installed in the vicinity of the AC / DC conversion unit 21 and the DC / AC conversion unit 23. The storage battery 22 is connected to the AC / DC conversion unit 21 and the DC / AC conversion unit 23.

The storage battery 22 is charged by DC power converted to AC / DC by the AC / DC conversion unit 21. Further, the DC power discharged from the storage battery 22 is DC-AC converted by the DC-AC conversion unit 23, output from the output terminal 27 as AC power, and supplied to the load 8.

(DC / AC converter 23)
The DC / AC conversion unit 23 is composed of an inverter that converts DC power into AC power. The inverter constituting the DC / AC conversion unit 23 has a switching element such as a transistor, and by switching the switching element, DC power is converted into AC power.

The DC / AC conversion unit 23 is installed in the vicinity of the storage battery 22. The DC / AC conversion unit 23 is connected to the output terminal 27 on the AC side and to the storage battery 22 and the AC / DC conversion unit 21 on the DC side. The DC / AC conversion unit 23 converts the DC power discharged from the storage battery 22 into AC power, and outputs the AC power to the output terminal 27. The AC power output to the output terminal 27 is supplied to the load 8.

(Bypass circuit 24)
The bypass circuit 24 is composed of a contactor, a relay, or an opening / closing element such as a power electronics semiconductor element that opens / closes a current. The bypass circuit 24 is arranged inside the housing constituting the uninterruptible power supply 2. One of the bypass circuits 24 is connected to the auxiliary input terminal 26 and the other is connected to the output terminal 27.

The bypass circuit 24 is controlled to open or close the circuit manually by an operator or by a control circuit (not instructed in the figure) when an accident occurs. The bypass circuit 24 supplies the AC power supplied from the auxiliary input terminal 26 to the output terminal 27 in the closed state. The AC power supplied to the output terminal 27 is supplied to the load 8.

(Measuring unit 31)
The measuring unit 31 is composed of a circuit in which an electric energy measuring device and an analog-digital converter are combined. The measuring unit 31 is inside the housing constituting the uninterruptible power supply device 2, and is arranged in the vicinity of the DC / AC conversion unit 23. The measuring unit 31 is electrically connected to the DC / AC conversion unit 23 and measures the output power of the DC / AC conversion unit 23. The measuring unit 31 outputs the measured output power of the DC / AC conversion unit 23 to the transmission / reception unit 33 as the output power W.

(Detection unit 32)
The detection unit 32 is composed of a circuit in which an electric energy measuring device and an analog-digital converter are combined. The detection unit 32 is inside the housing constituting the uninterruptible power supply device 2, and is arranged in the vicinity of the storage battery 22. The detection unit 32 is electrically connected to the storage battery 22 and detects the remaining battery level of the storage battery 22. The detection unit 32 outputs the detected remaining battery level of the storage battery 22 to the transmission / reception unit 33 as the remaining battery level R.

(Transmission / reception unit 33)
The transmission / reception unit 33 is composed of a message transmission / reception circuit for local communication and the like. The transmission / reception unit 33 is connected to the measurement unit 31 and the detection unit 32 on the input side and to the monitoring device 5 on the output side. The transmission / reception unit 33 transmits the output power W transmitted from the measurement unit 31 and the remaining battery level R transmitted from the detection unit 32 to the monitoring device 5.

The transmission / reception units 33a, 33b, 33c of the newly installed uninterruptible power supply devices 2a, 2b, and 2c transmit the output powers Wa, Wb, Wc and the remaining battery levels Ra, Rb, and Rc to the monitoring device 5, respectively. The transmission / reception units 33d, 33e, and 33f of the existing uninterruptible power supply devices 2d, 2e, and 2f transmit output powers Wd, We, and Wf to the monitoring device 5, respectively.

(3) Configuration of the monitoring device 5 The configuration of the monitoring device 5 is shown in FIG. The monitoring device 5 is composed of a personal computer or the like. The monitoring device 5 includes a transmission / reception unit 51, an input unit 52, a display unit 53, an alarm output unit 54, a transmission / reception unit 55, and a calculation unit 56. The monitoring device 5 is installed in the power management of the power consumer. Alternatively, the monitoring device 5 may be arranged in one of the plurality of uninterruptible power supply devices 2.

The monitoring device 5 is a designated uninterruptible power supply device among a plurality of uninterruptible power supply devices 2a, 2b, 2c or uninterruptible power supply devices 2d, 2e, and 2f based on the received output power W and the remaining battery level R. The supplyable time TA that can supply electric power is calculated from the remaining battery level R of 2.

(Transmission / reception unit 51)
The transmission / reception unit 51 is composed of a communication port of a personal computer or the like. The transmission / reception unit 51 is connected to the transmission / reception units 33 (33a to 33f) of the plurality of uninterruptible power supply devices 2 (2a to 2f). The transmission / reception unit 51 receives the output power W and the remaining battery level R from the transmission / reception unit 33 of the uninterruptible power supply 2 via the local communication line. The reception operation of the transmission / reception unit 51 is controlled by the calculation unit 56.

(Input unit 52)
The input unit 52 is composed of an input device such as a keyboard and a mouse combined with a display device such as a CRT. The input unit 52 is operated by an operator. The uninterruptible power supply 2 that stops the output of electric power is input to the input unit 52 by the operator. Alternatively, the uninterruptible power supply 2 that continues to output electric power may be input to the input unit 52 by an operator. As a result, among the plurality of uninterruptible power supply devices 2, the uninterruptible power supply device 2 that continues to output power is designated.

(Display unit 53)
The display unit 53 is composed of a display device such as a liquid crystal panel. The display unit 53 displays the available supply time TA that can supply power with the remaining battery level of the designated uninterruptible power supply 2 among the plurality of uninterruptible power supplies 2. The display of the display unit 53 is controlled by the calculation unit 56.

(Alarm output unit 54)
The alarm output unit 54 includes an alarm device that outputs an alarm by an alarm sound and an alarm display. The alarm output unit 54 outputs an alarm when the available supply time TA is equal to or less than the preset time TS.

(Transmission / reception unit 55)
The transmission / reception unit 55 is composed of a communication port of a personal computer or the like. The transmission / reception unit 55 is connected to a communication line such as the Internet (not shown in the figure) or a communication line of a smartphone. The transmission / reception unit 55 communicates with other devices such as computers and smartphones via a communication line. The transmission / reception unit 55 transmits an alarm when the available supply time TA and the available supply time TA are equal to or less than the preset time TS. The transmission / reception operation of the transmission / reception unit 55 is controlled by the calculation unit 56.

(Calculation unit 56)
The calculation unit 56 is composed of a CPU of a personal computer or the like that constitutes the monitoring device 5. The arithmetic unit 56 incorporates a computer program described later. The calculation unit 56 is connected to the transmission / reception unit 51, the input unit 52, the display unit 53, the alarm output unit 54, and the transmission / reception unit 55. The calculation unit 56 performs the following calculation and control.

(A) Control for the transmission / reception unit 51 The calculation unit 56 controls the transmission / reception unit 51 and receives the output power W and the remaining battery level R from the transmission / reception units 33 of the plurality of uninterruptible power supplies 2 via the local communication line.

(B) Control for input unit 52 The calculation unit 56 controls the input unit 52 and stops the output of the power input by the operator, or the uninterruptible power supply 2 that continues to output the power. Receive information about.

(C) Control for display unit 53 The calculation unit 56 can control the display unit 53 and supply power with the remaining battery level of the designated uninterruptible power supply 2 among the plurality of uninterruptible power supply units 2. Display the available supply time TA.

(D) Control for alarm output unit 54 The calculation unit 56 controls the alarm output unit 54 and outputs an alarm when the supplyable time TA is equal to or less than the preset time TS. The alarm is output by an alarm sound and an alarm display.

(E) Control for the transmission / reception unit 55 The calculation unit 56 controls the transmission / reception unit 55 and communicates with a device such as a computer or a smartphone connected via an Internet communication line, a communication line of a smartphone, or the like. The calculation unit 56 controls the transmission / reception unit 55, and transmits an alarm when the supplyable time TA and the supplyable time TA are equal to or less than the preset time TS.

[1-2. Action]
Next, an outline of the method for updating the uninterruptible power supply system and the operation of the uninterruptible power supply system 1 of the present embodiment will be described with reference to FIGS. 1 to 5.

[A. Uninterruptible power supply system update method]
First, the method of updating the uninterruptible power supply system will be described. As an example, a case where three existing uninterruptible power supply devices 2d, 2e, and 2f are replaced with new uninterruptible power supply devices 2a, 2b, and 2c will be described. The three existing uninterruptible power supply devices 2d, 2e, and 2f are updated with the new uninterruptible power supply devices 2a, 2b, and 2c as shown in FIG. FIG. 4 shows a procedure for updating the three existing uninterruptible power supply devices 2d, 2e, and 2f to the three new uninterruptible power supply devices 2a, 2b, and 2c. The uninterruptible power supply system 1 is updated by the following procedures 1 to 5.

(Before update)
As shown in FIG. 4, the three existing uninterruptible power supply devices 2d, 2e, and 2f are installed in an installation space such as an office floor before the update. The three existing uninterruptible power supply devices 2d, 2e, and 2f output the output powers Wd, We, and Wf to the load 8, respectively. The three existing uninterruptible power supply devices 2d, 2e, and 2f input terminals 25d, 25e, and 25f are connected to the commercial power supply 92 via the power supply line 91. Further, the output terminals 27d, 27e, and 27f of the three existing uninterruptible power supply devices 2d, 2e, and 2f are connected so as to supply power to the load 8 via a switch box (not shown in the figure).

(Procedure 1: Install two new uninterruptible power supplies 2b and 2c)
As shown in step 1 of FIG. 4, two new uninterruptible power supply devices 2b and 2c are installed. The two new uninterruptible power supplies 2b and 2c will be installed in a temporary space such as a prefab provided on the roof of an office or the like. The two new uninterruptible power supplies 2b and 2c are electrically connected in parallel with the three existing uninterruptible power supplies 2d, 2e and 2f. The input terminals 25b and 25c and the auxiliary input terminals 26b and 26c of the two newly installed uninterruptible power supplies 2b and 2c are connected to the commercial power supply 92 via the power supply line 91. Further, the output terminals 27b and 27c of the two newly installed uninterruptible power supplies 2b and 2c are connected so as to supply electric power to the load 8 via a switch box (not shown in the figure).

The bypass circuits 24b and 24c provided in the two newly installed uninterruptible power supply devices 2b and 2c are closed. The bypass circuits 24b and 24c are manually closed by the operator. In the stage of step 1, the electric power from the commercial power supply 92 is supplied to the load 8 via the bypass circuits 24b and 24c. At the stage of step 1, the power output from the DC / AC conversion unit 23b of the uninterruptible power supply 2b and the DC / AC conversion unit 23c of the uninterruptible power supply 2c is not supplied to the load 8. When a failure occurs in the uninterruptible power supply devices 2b and 2c, the bypass circuits 24b and 24c are opened by the control circuit (not shown in the figure) that detects the failure.

The three existing uninterruptible power supplies 2d, 2e, and 2f are likely to be older models. Further, the three existing uninterruptible power supply devices 2d, 2e and 2f may be manufactured by a different manufacturer from the newly installed uninterruptible power supply devices 2b and 2c.

Therefore, the voltage waveforms output from the two new uninterruptible power supplies 2b and 2c DC AC converters 23b and 23c and the three existing uninterruptible power supplies 2d, 2e and 2f DC AC converters 23d, The voltage waveforms output from 23e and 23f may be different waveforms. Therefore, when the three existing uninterruptible power supplies 2d, 2e, and 2f are outputting power, the two newly installed uninterruptible power supplies 2b and 2c electrically connected in parallel are converted to DC and AC. When power is output from the units 23b and 23c, an output conflift is generated between the three existing uninterruptible power supplies 2d, 2e and 2f and the two new uninterruptible power supplies 2b and 2c. Unwanted current may be generated.

Such an unnecessary current causes heat generation and is inconvenient. In order to avoid the generation of unnecessary current, in the stage of step 1, the power from the commercial power supply 92 is used instead of the power output from the DC / AC converters 23b and 23c of the two newly installed uninterruptible power supplies 2b and 2c. It is supplied to the load 8 via the bypass circuits 24b and 24c.

The remaining battery levels of the storage batteries 22b and 22c of the newly installed uninterruptible power supply devices 2b and 2c are the remaining battery levels Rb and Rc, respectively.

(Procedure 2: Remove 3 existing uninterruptible power supplies 2d, 2e, 2f)
As shown in step 2 of FIG. 4, the three existing uninterruptible power supply devices 2d, 2e, and 2f are removed. The three existing uninterruptible power supplies 2d, 2e, and 2f will be removed from the installation space such as the floor of the office. As a result, the installation space such as the office floor becomes an empty space.

After removing the three existing uninterruptible power supply devices 2d, 2e, and 2f, power is supplied to the load 8 from the DC AC conversion units 23b and 23c of the newly installed uninterruptible power supply devices 2b and 2c. After that, the bypass circuits 24b and 24c provided in the two newly installed uninterruptible power supply devices 2b and 2c are opened, and the supply of electric power to the load 8 via the bypass circuits 24b and 24c is stopped. The bypass circuits 24b and 24c are manually opened by the operator.

The DC / AC converters 23b and 23c of the newly installed uninterruptible power supply 2b and 2c output the output powers Wb and Wc, respectively. The output power Wb + Wc is supplied to the load 8.

(Procedure 3: Install a new uninterruptible power supply 2a)
As shown in step 3 of FIG. 4, one new uninterruptible power supply 2a is installed. One new uninterruptible power supply 2a is installed in an installation space such as an office floor, which became an empty space in step 2. The new uninterruptible power supply 2a is electrically connected in parallel with the two new uninterruptible power supplies 2b and 2c. The input terminal 25a of the newly installed uninterruptible power supply 2a is connected to the commercial power supply 92 via the power supply line 91. Further, the output terminal 27a of the newly installed uninterruptible power supply 2a is connected so as to supply electric power to the load 8 via a switch box (not shown in the figure).

The DC / AC conversion unit 23a of the uninterruptible power supply 2a outputs the power of the output power Wa. The output power Wa + Wb + Wc is supplied to the load 8. Further, the remaining battery level of the storage battery 22a of the uninterruptible power supply device 2a is the remaining battery level Ra.

(Procedure 4: Relocate uninterruptible power supply 2b)
As shown in step 4 of FIG. 4, one uninterruptible power supply device 2b is relocated. The uninterruptible power supply 2b installed in the temporary space in step 2 is moved to an installation space such as an office floor that became an empty space in step 2.

The uninterruptible power supply 2b is electrically connected in parallel with the two uninterruptible power supplies 2a and 2c. The input terminal 25b of the uninterruptible power supply 2b is connected to the commercial power supply 92 via the power supply line 91. Further, the output terminal 27b of the uninterruptible power supply 2b is connected so as to supply electric power to the load 8 via a switch box (not shown in the figure).

The DC / AC conversion unit 23b of the uninterruptible power supply 2b outputs the power of the output power Wb. The load 8 is supplied with an output power of Wa + Wb + Wc. Further, the remaining battery level of the storage battery 22b of the uninterruptible power supply device 2b is the remaining battery level Rb.

(Procedure 5: Relocate the uninterruptible power supply 2c)
As shown in step 5 of FIG. 4, one uninterruptible power supply device 2c is relocated. The uninterruptible power supply 2c installed in the temporary space in step 2 is moved to an installation space such as an office floor that became an empty space in step 2.

The uninterruptible power supply 2c is electrically connected in parallel with the two uninterruptible power supplies 2a and 2b. The input terminal 25c of the uninterruptible power supply 2c is connected to the commercial power supply 92 via the power supply line 91. Further, the output terminal 27c of the uninterruptible power supply 2c is connected so as to supply electric power to the load 8 via a switch box (not shown in the figure).

The DC / AC conversion unit 23c of the uninterruptible power supply 2c outputs the power of the output power Wc. The output power Wa + Wb + Wc is supplied to the load 8. The remaining battery level of the storage battery 22c of the uninterruptible power supply device 2c is the remaining battery level Rc.

(completion)
This completes the work of updating the three existing uninterruptible power supply devices 2d, 2e, and 2f to the new uninterruptible power supply devices 2a, 2b, and 2c. The work of updating the uninterruptible power supply 2 is performed by a worker or a work robot. The three new uninterruptible power supplies 2a, 2b, and 2c at the time of completion are shown in the completion of FIG. In the above procedure, the three existing uninterruptible power supply devices 2d, 2e, and 2f are updated with the three new uninterruptible power supply devices 2a, 2b, and 2c.

[B. Operation of uninterruptible power supply system 1]
Next, the operation of the uninterruptible power supply system 1 will be described. When a power failure occurs in the power supply line 91, the uninterruptible power supply 2 converts the DC power charged in the storage battery 22 into AC power by the DC AC conversion unit 23 and supplies it to the load 8. When the power supply line 91 does not have a power failure, the uninterruptible power supply 2 converts the DC power output from the AC / DC conversion unit 21 into AC power by the DC / AC conversion unit 23 and supplies it to the load 8. do.

The uninterruptible power supply 2 monitors the current output power W output from the DC / AC conversion unit 23 from the transmission / reception unit 33 and the remaining battery level R of the current storage battery 22 at preset fixed time intervals. Send to 5. The transmission / reception units 33a, 33b, 33c of the uninterruptible power supply devices 2a, 2b, and 2c transmit the output powers Wa, Wb, Wc and the remaining battery levels Ra, Rb, and Rc to the monitoring device 5, respectively.

The monitoring device 5 receives the output power W and the remaining battery level R from the uninterruptible power supply device 2. The uninterruptible power supply 2 transmits the output power W and the remaining battery level R to the monitoring device 5 at preset fixed time intervals, and the monitoring device 5 transmits the output power transmitted from the uninterruptible power supply 2. Based on W and the remaining battery level R, the uninterruptible power supply 2 that is currently supplying power to the load 8 is identified.

The monitoring device 5 is a battery of the uninterruptible power supply 2 that is left behind among the plurality of uninterruptible power supplies 2 during the work of updating the uninterruptible power supply system based on the received output power W and the remaining battery level R. With the remaining amount R, the supplyable time TA that can supply electric power to the load 8 by the storage battery 22 is calculated. The operator refers to the available supply time TA calculated by the monitoring device 5 and determines whether it is possible to stop the power supply to the load 8 of the uninterruptible power supply 2 due to the relocation.

Further, the monitoring device 5 outputs an alarm from the alarm output unit 54 when the supplyable time TA is equal to or less than the preset time TS. The operator recognizes that the remaining amount of the storage batteries 22a and 22b of the uninterruptible power supply devices 2a and 2c is low by the alarm output from the monitoring device 5.

The arithmetic unit 56 of the monitoring device 5 executes the following processing. The arithmetic unit 56 of the monitoring device 5 operates according to the program shown in FIG. The program shown in FIG. 5 is built in the calculation unit 56 of the determination unit 5.

The program shown in FIG. 5 is started by inputting a start command instructing the start of the program by the operator to the input unit 52 at the start of the work of updating the uninterruptible power supply system. After the program is started, the program shown in FIG. 5 is repeatedly and continuously executed at regular intervals by the arithmetic unit 56 of the monitoring device 5.

The operation of the monitoring device 5 when the procedure 4 of the above-mentioned uninterruptible power supply system update method is performed as an example will be described below. Before relocating the uninterruptible power supply 2b in step 4, a command for designating the uninterruptible power supply 2 that continues to output power is input to the input unit 52 by the operator. The command for designating the uninterruptible power supply 2 that continues to output power may be one in which the uninterruptible power supplies 2a and 2c that continue to output power are input to the input unit 52, or the output of power may be output. The uninterruptible power supply 2b to be stopped may be input to the input unit 52.

(Step S01: Identify the uninterruptible power supply 2 that continues to output power)
The calculation unit 56 is based on a command for designating an uninterruptible power supply 2 that continues to output the power input to the input unit 52, and the uninterruptible power supply 2 that continues to output the power and the uninterruptible power supply that stops the output of the power. Identify the power supply 2.

An uninterruptible power supply device 2a or 2c that continues to output power, or an uninterruptible power supply device 2b that stops power output is input to the input unit 52. The program is repeatedly and continuously executed at regular intervals, and the monitoring device 5 receives the output power W and the remaining battery level R from the uninterruptible power supply device 2 at regular time intervals.

The calculation unit 56 stores the uninterruptible power supply 2 that is currently supplying power to the load 8 based on the output power W and the battery remaining amount R transmitted from the uninterruptible power supply 2. Therefore, the calculation unit 56 receives power by inputting at least one of the uninterruptible power supply devices 2a and 2c that continue to output power or the uninterruptible power supply 2b that stops power output to the input unit 52. An uninterruptible power supply 2a and 2c that continue to output power and an uninterruptible power supply 2b that stops power output can be identified.

The calculation unit 56 is an uninterruptible power supply 2 in which the uninterruptible power supplies 2a and 2c continue to output power based on a command for designating the uninterruptible power supply 2 that continues to output the power input to the input unit 52. It is identified that the uninterruptible power supply 2b is the uninterruptible power supply 2 that stops the output of electric power.

(Step S02: Receives output power W from uninterruptible power supply 2)
Next, the arithmetic unit 56 receives the current output power W from the uninterruptible power supply device 2. At the stage before the relocation work in step 4, the uninterruptible power supply devices 2a, 2b, and 2c are supplying power to the load 8. The calculation unit 56 receives the output powers Wa, Wb, and Wc, which are the current output powers, from the uninterruptible power supply devices 2a, 2b, and 2c.

(Step S03: Receives the remaining battery level R from the uninterruptible power supply device 2)
Next, the calculation unit 56 receives the battery remaining amount R, which is the current remaining amount (electric energy amount) of the storage battery 22, from the uninterruptible power supply device 2. The calculation unit 56 receives the output powers Ra, Rb, and Rc, which are the remaining amounts (electric energy) of the storage batteries 22a, 22b, and 22c at present, from the uninterruptible power supply devices 2a, 2b, and 2c. Since the uninterruptible power supply devices 2a, 2b, and 2c are newly installed uninterruptible power supply devices 2, the storage battery 22 may not be sufficiently charged.

(Step S04: Calculate the required power supply WT for the load 8)
Next, the calculation unit 56 calculates the required power supply WT, which is the amount of power supply required to be supplied to the load 8. The required power supply WT is calculated based on the output powers Wa, Wb, and Wc of the uninterruptible power supply devices 2a, 2b, and 2c that are currently supplying power to the load 8. The required power supply WT = Wa + Wb + Wc. The required power supply WT is the total power of the output powers of the plurality of uninterruptible power supplies 2a, 2b, and 2c. During the relocation work of the uninterruptible power supply 2b in step 4, it is required to supply the required power supply WT = Wa + Wb + Wc to the load 8.

(Step S05: Calculate and display the available supply time TA)
Next, the calculation unit 56 determines the supplyable time TA capable of supplying electric power to the load 8 by the remaining battery level R of the uninterruptible power supply 2 that is left behind among the plurality of uninterruptible power supplies 2. calculate. The supplyable time TA is calculated based on the remaining battery levels Ra and Rc of the designated uninterruptible power supply devices 2a and 2c and the required supply power WT.

The available supply time TA is calculated by the available supply time TA = (Ra + Rc) / WT = (Ra + Rc) / (Wa + Wb + Wc). The calculated available supply time TA is displayed on the display unit 53. Further, the arithmetic unit 56 controls the transmission / reception unit 55, and transmits the supplyable time TA to the computer, the smartphone, etc. connected via the Internet communication line, the communication line of the smartphone, and the like.

The operator refers to the available supply time TA displayed on the display unit 53 of the monitoring device 5 or the available supply time TA transmitted from the transmission / reception unit 55 to the computer, smartphone, etc., and the uninterruptible power supply accompanying the relocation in step 4. It is determined whether the power supply to the load 8 of the device 2b can be stopped.

The supplyable time TA is the remaining battery levels Ra and Rc of the uninterruptible power supply devices 2a and 2c that are left behind among the plurality of uninterruptible power supply devices 2, and can supply power from the storage battery 22 to the load 8. It's time. Since the uninterruptible power supply devices 2a and 2c are newly installed uninterruptible power supply devices 2, the storage batteries 22a and 22c may not be sufficiently charged. The operator refers to the available supply time TA calculated by the monitoring device 5 and determines whether it is possible to stop the power supply to the load 8 by the uninterruptible power supply device 2b due to the relocation.

When the operator determines that the supplyable time TA is sufficient, the operator temporarily suspends the power supply to the load 8 by the uninterruptible power supply 2b installed in the temporary space, and moves the uninterruptible power supply 2b to the installation space. do. If the worker determines that the supplyable time TA is insufficient, the worker interrupts the work of relocating the uninterruptible power supply 2b to the installation space, and the uninterruptible power supply until the supplyable time TA becomes sufficient. Wait for the 2a and 2c storage batteries 22a and 22c to be charged.

The supplyable time TA is preferably a time that satisfies the time for relocating the uninterruptible power supply device 2b to the installation space. However, normally, the power supplyable time by the storage batteries 22a and 22c of the uninterruptible power supply 2a and 2c, which is the supplyable time TA, is 10 minutes to several tens of minutes, and it is necessary to relocate the uninterruptible power supply 2b to the installation space. Often shorter than the time required.

Even during the relocation work, commercial power is supplied to the uninterruptible power supplies 2a and 2c from the commercial power supply 92 via the power supply line 91. Therefore, the remaining amount of the storage batteries 22a and 22b of the uninterruptible power supply devices 2a and 2c may not decrease during the relocation work. Therefore, the available supply time TA suitable for the relocation work is appropriately determined by the worker.

(Step S06: It is determined whether the available supply time TA is equal to or less than the preset time TS).
Next, the calculation unit 56 determines whether the supplyable time TA is equal to or less than the preset time TS. The preset time TS is an arbitrary time preset by the operator. The preset time TS is recovered by the operator even when a power failure occurs during the relocation work of the uninterruptible power supply device 2b and the power supply to the load 8 by the uninterruptible power supply devices 2a and 2c is stopped. It is desirable to have enough time to be able to.

When the calculation unit 56 determines that the available supply time TA is equal to or less than the preset time TS (YES in step S06), the program shifts to step S07. If the calculation unit 56 does not determine that the available supply time TA is equal to or less than the preset time TS (NO in step S06), the series of programs ends.

(Step S07: An alarm is output from the alarm output unit 54)
When it is determined in step S06 that the available supply time TA is equal to or less than the preset time TS, the calculation unit 56 issues an alarm indicating that the available supply time TA is equal to or less than the preset time TS. Output from the output unit 54. The operator recognizes that the remaining amount of the storage batteries 22a and 22b of the uninterruptible power supply devices 2a and 2c is low by the alarm output from the monitoring device 5.

Further, the calculation unit 56 controls the transmission / reception unit 55, and the supplyable time TA to the computer, smartphone, etc. connected via the Internet communication line, the communication line of the smartphone, etc. shall be less than or equal to the preset time TS. Sends an alarm indicating. After that, the arithmetic unit 56 ends a series of programs.

The above steps S01 to S07 are repeatedly executed. Therefore, steps S01 to S07 are repeatedly executed even during the relocation work of the uninterruptible power supply device 2b in step 4, and the monitoring device 5 sequentially outputs powers Wa, Wc and remaining battery level Ra from the uninterruptible power supply devices 2a and 2c. Receive Rc. As a result, the available supply time TA is sequentially updated. As a result, even if the remaining amount of the storage batteries 22a and 22c of the uninterruptible power supply 2a and 2c decreases during the relocation work of the uninterruptible power supply 2b in step 4, the operator can supply the time TA in real time. Can be known.

The above is the operation of the monitoring device 5. As described above, the monitoring device 5 sequentially calculates the available supply time TA.

In the above, as an example, in the procedure 4 relating to the uninterruptible power supply system update method, the power output is continued by the uninterruptible power supply devices 2a and 2c, and the power output by the uninterruptible power supply device 2b is stopped for relocation. The possible time TA was calculated. In step S05, the available supply time TA is calculated by the available supply time TA = (Ra + Rc) / WT = (Ra + Rc) / (Wa + Wb + Wc).

In step 5 of the uninterruptible power supply system update method, the power output by the uninterruptible power supply devices 2a and 2b is continued, the power output by the uninterruptible power supply device 2c is stopped for relocation, and the supplyable time TA is calculated. It also applies to cases. In step S05, the available supply time TA is calculated by the available supply time TA = (Ra + Rb) / WT = (Ra + Rb) / (Wa + Wb + Wc).

Further, in step 2 of the uninterruptible power supply system update method, the power output by the uninterruptible power supply devices 2b and 2c is continued, and the power output by the uninterruptible power supply devices 2d, 2e, and 2f is stopped and supplied in order to remove the power output. It is also applied when calculating the possible time TA. In step S05, the available supply time TA is calculated by the available supply time TA = (Rb + Rc) / WT = (Rb + Rc) / (Wd + We + Wf).

When the existing uninterruptible power supply devices 2d, 2e, 2f do not have the function of transmitting the output powers Wd, We, Wf, the output powers Wd, Wee of the uninterruptible power supply devices 2d, 2e, 2f measured by the operator. , Wf may be input from the input unit 52 of the monitoring device 5.

[1-3. effect]
(1) According to the present embodiment, the uninterruptible power supply system update method is a smaller number than the existing uninterruptible power supplies 2d, 2e, and 2f installed in the installation space, and satisfies the power supply to the load 8. The first procedure of installing the first new uninterruptible power supply 2b, 2c, which is the number of units, in the temporary space so as to be electrically connected in parallel with the existing uninterruptible power supply 2d, 2e, 2f. In the second procedure and the first procedure, the first new uninterruptible power supply 2b, 2c supplies power to the load 8 and the existing uninterruptible power supply 2d, 2e, and 2f are removed from the installation space. With the third procedure of installing the second new uninterruptible power supply 2a in the installation space so that it is electrically connected in parallel with the first new uninterruptible power supply 2b and 2c installed in the temporary space. , The first new uninterruptible power supply 2b installed in the temporary space so as to be electrically connected in parallel with the second new uninterruptible power supply 2a installed in the installation space in the third procedure. Since it has the fourth procedure of moving at least one of 2c to the installation space, it corresponds to the update method and the update method of the uninterruptible power supply system that can be updated even if sufficient installation space cannot be secured. , Uninterruptible power supply system, uninterruptible power supply monitoring device, uninterruptible power supply system program can be provided.

(2) According to the present embodiment, the method of updating the uninterruptible power supply system is the fourth method until all the first new uninterruptible power supply devices 2b and 2c installed in the temporary space are relocated to the installation space. Since the procedure is repeated, the uninterruptible power supply system can be updated even if sufficient installation space cannot be secured.

(3) According to the present embodiment, in the uninterruptible power supply system update method, power is supplied to the load 8 by a commercial power supply before the second procedure, and the power from the existing uninterruptible power supply to the load is supplied. Since there is a procedure to stop the supply, the voltage waveform output from the two new uninterruptible power supplies 2b and 2c DC AC converters 23b and 23c and the three existing uninterruptible power supplies 2d, 2e, 2f Even if the voltage waveforms output from the DC / AC converters 23d, 23e, and 23f are different, the output between the existing uninterruptible power supply 2d, 2e, 2f and the new uninterruptible power supply 2b, 2c. It is possible to avoid the generation of unnecessary current due to the conflift.

(4) According to the present embodiment, the non-disruptive power supply system 1 transmits data regarding the output power W and the remaining battery level R, and is the output power from the plurality of non-disruptive power supply devices 2 and the plurality of non-disruptive power supply devices 2. Based on the transmission / reception unit 51 that receives data related to W and the remaining battery level R, and the received output power W, the required supply power WT, which is the total power of the output powers of the plurality of uninterrupted power supply devices 2, is calculated and received. Based on the remaining amount R, the required supply power WT, which is the calculated total power, can be supplied by the battery remaining amount R of the designated uninterrupted power supply device 2 among the plurality of uninterrupted power supply devices 2. Since the operator has a calculation unit 56 for calculating the power supply, the operator can obtain the supplyable time TA displayed on the display unit 53 of the monitoring device 5 or the supplyable time TA transmitted from the transmission / reception unit 55 to the computer, smartphone, or the like. With reference to this, it is possible to determine whether it is possible to stop the power supply to the load 8 of the non-disruptive power supply device 2b due to the relocation of the procedure 4.

The supplyable time TA is the remaining battery levels Ra and Rc of the uninterruptible power supply devices 2a and 2c that are left behind among the plurality of uninterruptible power supply devices 2, and can supply power from the storage battery 22 to the load 8. It's time. Since the uninterruptible power supply devices 2a and 2c are newly installed uninterruptible power supply devices 2, the storage batteries 22a and 22c may not be sufficiently charged. The operator can refer to the supplyable time TA calculated by the monitoring device 5 and determine whether it is possible to stop the power supply to the load 8 by the uninterruptible power supply device 2b due to the relocation.

When the operator determines that the supplyable time TA is sufficient, the operator temporarily suspends the power supply to the load 8 by the uninterruptible power supply 2b installed in the temporary space, and moves the uninterruptible power supply 2b to the installation space. do. If the worker determines that the supplyable time TA is insufficient, the worker interrupts the work of relocating the uninterruptible power supply 2b to the installation space, and the uninterruptible power supply until the supplyable time TA becomes sufficient. It is possible to wait for the storage batteries 22a and 22b of 2a and 2c to be charged. As a result, even if a power failure occurs during the relocation work, power can be supplied to the load 8 by the uninterruptible power supply devices 2a and 2c for an appropriate time.

(5) According to the present embodiment, the monitoring device 5 of the uninterruptible power supply system 1 has an alarm output unit 54 that outputs an alarm when the supplyable time TA is equal to or less than the preset time TS. The person can recognize that the remaining amount of the storage batteries 22a and 22b of the uninterruptible power supply devices 2a and 2c is low by the alarm output from the monitoring device 5.

[4. Other embodiments]
Although embodiments including modifications have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These embodiments can be implemented in various other embodiments, and various omissions, replacements, and changes can be made without departing from the gist of the invention. These embodiments and variations thereof are included in the scope of the invention described in the claims and the equivalent scope thereof, as are included in the scope and gist of the invention. The following is an example.

(1) In the above embodiment, the number of uninterruptible power supply units 2 newly installed in step 1 is assumed to be two, but the number is not limited to this. The number of uninterruptible power supplies 2 newly installed in step 1 may be smaller than the number of existing uninterruptible power supplies 2 installed in the installation space, and may be any number that satisfies the power supply to the load 8.

(2) In the above embodiment, the uninterruptible power supply device 2 newly installed in the procedure 3 is assumed to be one unit, but may be a plurality of units.

(3) In the above embodiment, the uninterruptible power supply device 2 relocated in the procedure 4 or the procedure 5 is assumed to be one unit, but may be a plurality of units.

(4) In the above embodiment, the monitoring device 5 is assumed to be one device, but the monitoring device 5 may be built in the uninterruptible power supply devices 2a, 2b, and 2c. Further, it is desirable that the monitoring device 5 is built in the uninterruptible power supply device 2a that is newly installed without relocation.

1 ... Uninterruptible power supply system 2,2a, 2b, 2c ... Uninterruptible power supply device 5 ... Monitoring device 8 ... Load 9 ... Power system 21 ... AC / DC converter 22 ... Storage battery 23 ... DC / AC converter 24 ... Bypass circuit 25, 25a, 25b, 25c ... Input terminals 26, 26a, 26b, 26c ... Auxiliary input terminals 27, 27a, 27b, 27c ... Output terminal 31 ... Measurement unit 32 ... Detection unit 33 ... Transmission / reception unit 51 ... Transmission / reception unit 52 ... Input unit 53 ... Display unit 54 ... Alarm output unit 55 ... Transmission / reception unit 56 ... Calculation unit 91 ... Power supply line 92 ... Commercial power supply

Claims (6)

An uninterruptible power supply system update method that updates multiple uninterruptible power supplies.
The first new uninterruptible power supply, which is smaller than the existing uninterruptible power supply installed in the installation space and is the number that satisfies the power supply to the load, is electrically replaced with the existing uninterruptible power supply. The first procedure to install in the temporary space so that it will be connected in parallel to
A second procedure of supplying power to the load from the first new uninterruptible power supply and removing the existing uninterruptible power supply from the installation space.
A second new uninterruptible power supply is installed in the installation space so as to be electrically connected in parallel with the first new uninterruptible power supply installed in the temporary space in the first procedure. Step 3 and
The first new uninterruptible power supply installed in the temporary space so as to be electrically connected in parallel with the second new uninterruptible power supply installed in the installation space in the third procedure. The fourth procedure to move at least one of them to the installation space,
Uninterruptible power supply system update method. The fourth procedure is repeated until all the first new uninterruptible power supplies installed in the temporary space are relocated to the installation space.
The method for updating an uninterruptible power supply system according to claim 1. Prior to the second procedure, there is a procedure for supplying electric power to the load with a commercial power source and stopping the supply of electric power to the load from the existing uninterruptible power supply device.
The method for updating an uninterruptible power supply system according to claim 1 or 2. The method for updating an uninterruptible power supply system according to any one of claims 1 to 3, wherein the second new uninterruptible power supply device installed in the third procedure is a single unit or a plurality of uninterruptible power supplies. The uninterruptible power supply system updating method according to any one of claims 1 to 4, wherein the first new uninterruptible power supply device to be relocated in the fourth procedure is a single unit or a plurality of uninterruptible power supplies. Receiving procedure for receiving data on output power and battery level from multiple uninterruptible power supplies,
A calculation procedure for calculating the total power of the output powers of the plurality of uninterruptible power supplies based on the received output powers, and a calculation procedure.
Based on the received remaining battery level, the available supply time during which the calculated total power can be supplied is calculated from the remaining battery level of the designated uninterruptible power supply device among the plurality of uninterruptible power supply devices. The calculation procedure to be performed and
The method for updating an uninterruptible power supply system according to any one of claims 1 to 5.

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