JP2019161966A - Uninterruptible power supply system, uninterruptible power supply, uninterruptible power supply control program and uninterruptible power supply control method - Google Patents

Abstract

To provide an uninterruptible power supply system in which deterioration of a refrigeration part is detected in early stage, by extracting generation sound of the refrigeration part accurately, and to provide an uninterruptible power supply, an uninterruptible power supply control program, and an uninterruptible power supply control method.SOLUTION: An uninterruptible power supply system includes a power supply unit 20 having an A/D conversion part 21 performing A/D conversion of a supplied AC power, an accumulator battery 22 for charging the DC power supplied from the A/D conversion part 21, and discharging DC power, a D/A conversion part 23 performing D/A conversion of the DC power discharged from the accumulator battery 22, and outputting AC power, and a refrigeration part 28 for cooling at least one of the A/D conversion part 21 and the D/A conversion part 23, a detector 4 for detecting operation sound of the power supply unit 20, and a control section 3 controlling the timing when the detector 4 detects the operation sound, and extracting the generation sound of the refrigeration part 28. Furthermore, a determination part for determining deterioration of the refrigeration part 28, on the basis of the generation sound of the refrigeration part 28, extracted by the control section 3, is provided.SELECTED DRAWING: Figure 2

Description

  The present embodiment relates to an uninterruptible power supply system, an uninterruptible power supply, an uninterruptible power supply control program, and an uninterruptible power supply control method that supply power when a power failure occurs in an electric power system.

  Load facilities such as Internet data centers, banks, and securities company online systems are required to be continuously supplied with constant voltage and constant frequency power. In recent years, the importance of information infrastructure has increased, and a large number of load facilities that can be operated without a power outage have become widespread. For this reason, the demand of the uninterruptible power supply system which supplies power supply to a load facility without an uninterruptible power is increasing.

  When the power applied to the commercial power supply stops, 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 an uninterruptible power supply system includes an AC / DC converter that converts the supplied AC power into an AC / DC converter, a storage battery that is charged by the DC power supplied from the AC / DC converter, and a DC power that is discharged from the storage battery. It has a direct current alternating current conversion section that performs direct current alternating current conversion and outputs alternating current power.

JP 2014-222982 A

  The uninterruptible power supply system as described above has an AC / DC conversion unit that converts supplied AC power into AC / DC, and a DC / AC conversion unit that converts DC power into DC / AC and outputs AC power. The AC / DC converter and the DC / AC converter are constituted by a switching circuit made of a semiconductor and generate heat. The uninterruptible power supply system includes an AC / DC converter and a cooling unit that cools the DC / AC converter.

  However, since the cooling unit is composed of a member having a movable unit such as a cooling fan, it deteriorates over time. The degree of deterioration of the cooling unit over time varies depending on the installation environment, use status, and individual cooling unit of the uninterruptible power supply system. Although the cooling unit is regularly maintained, there is a possibility that the cooling unit may malfunction before the maintenance.

  If the cooling unit malfunctions, the AC / DC conversion unit and the DC / AC conversion unit of the uninterruptible power supply system become hot, and there is a risk of damaging each part of the uninterruptible power supply system. Damage to each part constituting the uninterruptible power supply system is inconvenient because it is impossible to supply stable power to the load facility. Therefore, it is desirable to detect the deterioration of the cooling part having the movable part at an early stage to prevent the uninterruptible power supply system from being damaged.

  The deterioration of the cooling unit can be estimated by extracting the sound generated by the cooling unit. However, the sound generated by the cooling unit may not be accurately extracted due to the operation sound of other devices constituting the uninterruptible power supply system.

  In the present embodiment, an uninterruptible power supply system, an uninterruptible power supply apparatus, an uninterruptible power supply control program, and an uninterruptible power supply apparatus that can accurately extract sound generated from a cooling section and detect deterioration of the cooling section at an early stage An object is to provide a control method.

The uninterruptible power supply system of this embodiment has the following configuration.
(1) A power supply unit having the following configuration.
(1-1) An AC / DC converter that converts the supplied AC power into AC / DC.
(1-2) A storage battery that charges the DC power supplied from the AC / DC converter and discharges the DC power.
(1-3) A DC / AC converter that converts DC power discharged from the storage battery into DC / AC and outputs AC power.
(1-4) A cooling unit that cools at least one of the AC / DC conversion unit and the DC / AC conversion unit.

(2) A detection unit that detects an operation sound of the power supply unit.
(3) A control unit that controls a timing at which the detection unit detects an operation sound and extracts a sound generated by the cooling unit.
(4) A determination unit that determines deterioration of the cooling unit based on the generated sound of the cooling unit extracted by the control unit.

  The uninterruptible power supply, the uninterruptible power supply control program, and the uninterruptible power supply control method having the above characteristics are also included in the present embodiment.

The figure which shows the uninterruptible power supply system concerning 1st Embodiment The figure which shows the structure of the uninterruptible power supply concerning 1st Embodiment. The figure which shows the structure of the judgment part concerning 1st Embodiment. The figure which shows the program flow of the control part of the uninterruptible power supply concerning 1st Embodiment. The figure which shows the program flow of the judgment part concerning 1st Embodiment. The figure which shows the structure of the uninterruptible power supply concerning 2nd Embodiment. The figure which shows the program flow of the control part of the uninterruptible power supply concerning 2nd Embodiment. The figure which shows the uninterruptible power supply system concerning 3rd Embodiment The figure which shows the structure of the uninterruptible power supply concerning 3rd Embodiment. The figure which shows the program flow of the control part of the uninterruptible power supply concerning 3rd Embodiment The figure which shows the structure of the uninterruptible power supply concerning 4th Embodiment. The figure which shows the program flow of the control part of the uninterruptible power supply concerning 4th Embodiment The figure which shows the operation sound detected by the detection part of the uninterruptible power supply concerning 4th Embodiment.

[1. First Embodiment]
[1-1. Constitution]
With reference to FIGS. 1-3, the uninterruptible power supply system 1 as an example of this embodiment is demonstrated.

(1) Overall Configuration of Uninterruptible Power Supply System 1 The uninterruptible power supply system 1 includes an uninterruptible power supply 2 and a determination unit 5. The uninterruptible power supply 2 is disposed on the power supply line 91. The power supply line 91 forms part of the power system 9 and supplies power to the customer. The power system 9 is connected to a commercial power source 92. The AC power output from the uninterruptible power supply 2 is supplied to the load 8.

  In the present embodiment, when there are a plurality of devices and members having the same configuration, the same number is assigned to the description, and it is common when each device and member having the same configuration is described. Distinguish numbers by adding an alphabetic suffix.

In the uninterruptible power supply system 1, the following signals and data are created, stored, or transmitted / received.
Signal data A: Signal data related to the operation sound of the power supply unit 20 (Signal data A1: Signal data related to the operation sound during the entire operation of the power supply unit 20)
(Signal data A2: Signal data relating to operation sound when the AC / DC converter 21 and the DC / AC converter 23 are stopped)
(Signal data A3: Signal data relating to operation sound when the cooling unit 28 is stopped)
Signal data B: Signal data relating to sound generated by the cooling unit 28 Operation command C
(Operation command C1: Operation command for designating the operation frequency of the AC / DC converter 21)
(Operation command C2: Operation command for designating the operation frequency of the DC / AC converter 23)
(Operation command C3: Operation command for designating the rotation speed of the cooling unit 28)
Stop command D
(Stop command D1: Stop command for instructing to stop the operation of the AC / DC converter 21)
(Stop command D2: Stop command for instructing to stop the operation of the DC / AC converter 23)
(Stop command D3: Stop command for instructing to stop the operation of the cooling unit 28)
Reference data E: Data used as a reference for determining deterioration of the cooling unit 28 Alarm signal F: Alarm signal for warning of deterioration of the cooling unit 28 Temperature data G
Power supply command H

(2) Configuration of the uninterruptible power supply 2 The uninterruptible power supply 2 converts the AC power supplied from the power supply line 91 into DC power, charges the storage battery, and converts the DC power discharged from the storage battery into AC power. The power supply device outputs to the load 8. The uninterruptible power supply 2 includes a power supply unit 20, a control unit 3, and a detection unit 4. The uninterruptible power supply 2 is installed in a power distribution room of a power consumer.

(2-1) Configuration of Power Supply Unit 20 The power supply unit 20 includes an AC / DC converter 21a, a storage battery 22, a DC / AC converter 23, a bypass circuit 24, an input terminal 25, an auxiliary input terminal 26, an output terminal 27, and a cooling unit 28. Have

  The input terminal 25 of the power supply unit 20 is connected to the power supply line 91 and supplied with AC power. The load 8 is connected to the output terminal 27 of the power supply unit 20, and AC power is supplied to the load 8 from the power supply unit 20. The auxiliary input terminal 26 of the power supply unit 20 is connected to a backup uninterruptible power supply (not shown in the figure) and supplied with backup AC power. The auxiliary input terminal 26 of the power supply unit 20 may be unconnected.

(AC / DC converter 21)
The AC / DC converter 21 is configured by a converter that converts AC power into DC power. The converter which comprises the alternating current direct current | flow conversion part 21 has switching elements, such as a transistor, and converts alternating current power into direct current power by switching this switching element.

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

  The AC / DC converter 21 converts 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 converter 23.

  The switching frequency of the switching element that is the operating frequency of the AC / DC converter 21 is controlled by the controller 3. The control unit 3 transmits an operation command C1 (an operation command for specifying the operation frequency of the AC / DC conversion unit 21) and a stop command D1 (a stop command for instructing an operation stop of the AC / DC conversion unit 21) to thereby generate an AC / DC. The switching frequency of the switching element of the converter 21 is controlled.

  The AC / DC converter 21 receives the operation command C1 and the stop command D1 from the controller 3. When the AC / DC converter 21 receives the operation command C1, the AC / DC converter 21 performs the switching operation of the switching element at the frequency specified by the operation command C1, and converts AC power into DC power. When the AC / DC converter 21 receives the stop command D1, the AC / DC converter 21 stops the switching operation.

(Storage battery 22)
The storage battery 22 is a chargeable power storage device that charges a charge applied to 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 lithium secondary batteries. The storage battery 22 is installed in the vicinity of the AC / DC converter 21 and the DC / AC converter 23. The storage battery 22 is connected to the AC / DC converter 21 and the DC / AC converter 23.

  The storage battery 22 is charged with DC power that has been AC / DC converted by the AC / DC converter 21. Further, the DC power discharged from the storage battery 22 is DC / AC converted by the DC / AC converter 23, output as AC power from the output terminal 27, and supplied to the load 8.

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

  The DC / AC converter 23 is installed in the vicinity of the storage battery 22. The DC / AC converter 23 is connected to the output terminal 27 on the AC side and to the storage battery 22 and the AC / DC converter 21 on the DC side. The DC / AC converter 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.

  The switching frequency of the switching element that is the operating frequency of the DC / AC converter 23 is controlled by the controller 3. The control unit 3 transmits the operation command C2 (operation command that specifies the operation frequency of the DC / AC conversion unit 23) and the stop command D2 (stop command that instructs to stop the operation of the DC / AC conversion unit 23), thereby The switching frequency of the switching element of the converter 23 is controlled.

  The DC / AC converter 23 receives an operation command C2 and a stop command D2 from the controller 3. When the DC / AC conversion unit 23 receives the operation command C2, the DC / AC conversion unit 23 performs switching operation of the switching element at a frequency specified by the operation command C2, and converts DC power into AC power. When the DC / AC converter 23 receives the stop command D2, the DC / AC converter 23 stops the switching operation.

(Bypass circuit 24)
The bypass circuit 24 is configured by an open / close element such as a contactor, a relay, or a power electronics semiconductor element that opens and closes current. The bypass circuit 24 is disposed inside a casing that forms 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 be opened and closed by the control unit 3. The bypass circuit 24 supplies the AC power supplied to 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.

(Cooling unit 28)
The cooling unit 28 includes a cooling fan that is driven by an electric motor. The cooling unit 28 is inside the casing constituting the uninterruptible power supply 2 and is installed in the vicinity of the AC / DC converter 21 and the DC / AC converter 23. The cooling unit 28 cools the AC / DC conversion unit 21 and the DC / AC conversion unit 23 by rotating a cooling fan and flowing air.

  The rotation speed of the cooling fan of the cooling unit 28 is controlled by the control unit 3. The control unit 3 transmits the operation command C3 (operation command for designating the rotation speed of the cooling unit 28) and the stop command D3 (stop command stop for instructing the operation stop of the cooling unit 28) to cool the cooling unit 28. Controls the fan speed.

  The cooling unit 28 receives the operation command C3 and the stop command D3 from the control unit 3. When the cooling unit 28 receives the operation command C3, the cooling unit 28 rotates the cooling fan at the rotation speed designated by the operation command C3, thereby cooling the AC / DC conversion unit 21 and the DC / AC conversion unit 23. When the cooling unit 28 receives the stop command D3, the cooling unit 28 stops the operation of the cooling fan.

(2-2) Configuration of Detection Unit 4 The detection unit 4 is configured by a device in which a microphone that detects sound and an analog-digital converter are combined. The detection unit 4 preferably has a plurality of microphones. The detection unit 4 is installed inside the housing constituting the uninterruptible power supply 2 and in the vicinity of the cooling unit 28.

  The detection unit 4 detects the operation sound of the power supply unit 20, performs analog-digital conversion, and outputs the signal data relating to the operation sound of the power supply unit 20 that has been converted from analog to digital as signal data A to the control unit 3. The signal data A includes signal data relating to at least one of the sound generated by the cooling unit 28 of the power supply unit 20, the operation sound of the AC / DC conversion unit 21, the DC / AC conversion unit 23, and the environmental sound.

(2-3) Configuration of Control Unit 3 The control unit 3 includes a microcomputer, a DSP (digital signal processor), and the like. The control unit 3 is arranged in a housing that forms the uninterruptible power supply 2. The control unit 3 performs control for extracting the sound generated by the cooling unit 28 from the operation sound of the power supply unit 20. Signal data B (signal data related to the sound generated by the cooling unit 28), which is data related to the generated sound of the cooling unit 28 extracted by the control unit 3, is transmitted to the determination unit 5.

  The control unit 3 includes an input unit 31, an output unit 32, a transmission unit 33, and a calculation unit 34.

(Input unit 31)
The input unit 31 is configured by a telegram receiving circuit including a microcomputer port or the like. The input unit 31 has an input side connected to the detection unit 4 and an output side connected to the calculation unit 34. The input unit 31 receives the signal data A (signal data related to the operation sound of the power supply unit 2) transmitted from the detection unit 4 via a telegram, and outputs the signal data A to the calculation unit 34.

(Output unit 32)
The output unit 32 is configured by a message transmission circuit including a port of a microcomputer. The output unit 32 has an input side connected to the calculation unit 34 and an output side connected to the power supply unit 20, the AC / DC conversion unit 21, the DC / AC conversion unit 23, the cooling unit 28, and the bypass circuit 24.

  The output unit 32 is controlled by the calculation unit 34, and the operation command C1 (operation command for designating the operation frequency of the AC / DC conversion unit 21) and the stop command D1 (operation stop of the AC / DC conversion unit 21) are transmitted to the AC / DC conversion unit 21. Send a stop command).

  Further, the output unit 32 is controlled by the calculation unit 34, and the operation command C <b> 2 (operation command for specifying the operation frequency of the DC / AC conversion unit 23) and the stop command D <b> 2 (of the DC / AC conversion unit 23) Stop command to stop operation).

  Further, the output unit 32 is controlled by the calculation unit 34, and the operation command C 3 (operation command for designating the rotation speed of the cooling unit 28) and the stop command D 3 (stop for instructing the operation stop of the cooling unit 28) to the cooling unit 28. Command stop). The output unit 32 is controlled by the calculation unit 34 and transmits a command for instructing opening and closing of the bypass circuit 24.

(Transmitter 33)
The transmission unit 33 includes a telegram transmission circuit including a microcomputer port. The transmission unit 33 has an input side connected to the calculation unit 34 and an output side connected to the determination unit 5. The transmission unit 33 transmits the signal data B (signal data relating to the sound generated by the cooling unit 28) created by the calculation unit 34 to the determination unit 5.

(Calculation unit 34)
The computing unit 35 is configured by a microcomputer or a DSP (digital signal processor) CPU. The calculation unit 34 incorporates a computer program to be described later. The calculation unit 34 is connected to the input unit 31, the output unit 32, and the transmission unit 33. The calculation unit 34 performs the following calculation and control.

(A) Control with respect to the input part 31 The calculating part 34 controls the input part 31, and receives the signal data A (signal data concerning the operation sound of the power supply part 2) transmitted from the detection part 4.

(B) Control for the output unit 32 The calculation unit 34 controls the output unit 32 to send an operation command C1 (an operation command for designating an operating frequency of the AC / DC conversion unit 21), a stop command D1 ( A stop command for instructing to stop the operation of the AC / DC converter 21 is transmitted.

  Further, the calculation unit 34 controls the output unit 32 to send an operation command C2 (an operation command for designating an operating frequency of the DC / AC conversion unit 23) and a stop command D2 (of the DC / AC conversion unit 23) to the DC / AC conversion unit 23. Stop command to stop operation).

  In addition, the calculation unit 34 controls the output unit 32, and instructs the cooling unit 28 to operate the command C3 (operation command specifying the number of rotations of the cooling unit 28) and stop command D3 (stop the operation of the cooling unit 28). Command stop). The calculation unit 34 controls the output unit 32 and transmits a command for instructing an open circuit to the bypass circuit 24.

(C) Control for Transmitter 33 The calculator 34 controls the transmitter 33 to transmit the signal data B (signal data relating to the sound generated by the cooling unit 28) to the determination unit 5. The calculation unit 34 performs calculation based on the signal data A (signal data related to the operation sound of the power supply unit 2) received from the detection unit 4, and generates signal data B (signal data related to the sound generated by the cooling unit 28). .

(3) Configuration of Determination Unit 5 The configuration of the determination unit 5 is shown in FIG. The determination unit 5 is a device that determines the deterioration of the cooling unit 28 of the uninterruptible power supply 2. The determination unit 5 is configured by a personal computer or the like. The determination unit 5 includes a reception unit 51, a storage unit 52, a display unit 53, an alarm output unit 54, a transmission / reception unit 55, and a calculation unit 56. The determination unit 5 is installed in a power management room of a power consumer.

(Receiver 51)
The receiving unit 51 includes a communication port of a personal computer. The reception unit 51 is connected to the transmission unit 33 of the control unit 3. The receiving unit 51 receives the signal data B (signal data related to the sound generated by the cooling unit 28) from the transmitting unit 33 of the control unit 3 via the local communication line. The receiving operation of the receiving unit 51 is controlled by the control unit 56.

(Storage unit 52)
The storage unit 52 is configured by a hard disk memory or a semiconductor memory of a personal computer that constitutes the determination unit 5. The storage operation of the storage unit 52 is controlled by the control unit 56. The storage unit 52 stores reference data E serving as a reference for determining the deterioration of the cooling unit 28. The reference data E is set in advance before the operation of the uninterruptible power supply 2 is started.

(Display unit 53)
The display unit 53 is configured by a display device such as a liquid crystal panel. The display unit 53 receives the signal data B (signal data related to the sound generated by the cooling unit 28) received by the receiving unit 51 and the deterioration of the cooling unit 28 stored in the storage unit 52. The reference data E as a reference for the determination is also displayed. The display of the display unit 53 is controlled by the calculation unit 56.

(Alarm output unit 54)
The alarm output unit 54 is configured by an alarm device that outputs an alarm signal based on an alarm sound and an alarm display. The calculation unit 56 includes signal data B (signal data related to the sound generated by the cooling unit 28) that is a sound generated by the cooling unit 28, and reference data that is a reference for determining deterioration of the cooling unit 28 stored in the storage unit 52. When it is determined that the difference from E is equal to or greater than a preset value, an alarm signal F (an alarm signal for warning of deterioration of the cooling unit 28) is output to the alarm output unit 54. The alarm output unit 54 is controlled by the calculation unit 56 and outputs an alarm with an alarm sound and an alarm display based on the alarm signal F transmitted from the calculation unit 56.

(Transmitter / Transmitter 55)
The transmission / reception unit 55 includes a communication port of a personal computer. The transmission / reception unit 55 is connected to a communication line (not shown) such as the Internet. The transmission / reception unit 55 communicates with devices such as other computers via a communication line. The transmission / reception unit 55 stores the signal data B (signal data related to the sound generated by the cooling unit 28), which is generated by the cooling unit 28, in the storage unit 52 in response to a request signal transmitted from a device such as another computer. The reference data E and the warning signal F (the warning signal for warning the deterioration of the cooling unit 28) are transmitted. 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 configured by a CPU of a personal computer that constitutes the determination unit 5. The calculation unit 56 incorporates a computer program to be described later. The calculation unit 56 is connected to the reception unit 51, the storage 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 with respect to the receiving part 51 The calculating part 56 controls the receiving part 51, and receives signal data B (signal data concerning the sound generated by the cooling part 28) from the transmitting part 33 of the control part 3 via the local communication line. Receive.

(B) Control for the storage unit 52 The calculation unit 56 controls the storage unit 52 and reads the stored reference data E that is a reference for determining the deterioration of the cooling unit 28. The reference data E is set in advance before the operation of the uninterruptible power supply 2 is started.

(C) Control for display unit 53 The calculation unit 56 controls the display unit 53 to store in the storage unit 52 signal data B (signal data related to the generated sound of the cooling unit 28) that is generated by the cooling unit 28. The reference data E as a reference for judging the deterioration of the cooling unit 28 is also displayed.

(D) Control for the alarm output unit 54 The calculation unit 56 controls the alarm output unit 54 and outputs an alarm with an alarm sound and an alarm display. The calculation unit 56 includes signal data B (signal data related to the sound generated by the cooling unit 28) that is a sound generated by the cooling unit 28, and reference data that is a reference for determining deterioration of the cooling unit 28 stored in the storage unit 52. A difference with E is calculated, and when it is determined that the difference is equal to or greater than a preset value, an alarm signal F (an alarm signal for warning of deterioration of the cooling unit 28) is output to the alarm output unit 54. Based on the alarm signal F, the alarm output unit 54 outputs an alarm with an alarm sound and an alarm display.

(E) Control for transmission / reception unit 55 The calculation unit 56 controls the transmission / reception unit 55 to communicate with other devices such as a computer connected via a communication line. The calculation unit 34 controls the transmission / reception unit 55 to receive a request signal transmitted from a device such as another computer. In response to the request signal, the calculation unit 56 controls the transmission / reception unit 55 to transmit the signal data B (signal data related to the sound generated by the cooling unit 28) generated by the cooling unit 28 and the cooling stored in the storage unit 52. Reference data E serving as a reference for determining deterioration of the unit 28 or an alarm signal F (an alarm signal for warning of deterioration of the cooling unit 28) is transmitted.

[1-2. Action]
Next, the outline | summary of operation | movement of the uninterruptible power supply system 1 of this embodiment is demonstrated based on FIGS.

[A. When the sound generated by the cooling unit 28 is not extracted]
In the case of normal operation in which the generated sound of the cooling unit 28 is not extracted and when a power failure has not occurred in the power supply line 91, the power supply line 91, Electric power is supplied from the commercial power supply 92 via the input terminal 25. The AC / DC converter 21 converts the supplied AC power into DC power, and supplies the DC power to the storage battery 22 and the DC / AC converter 23.

  The DC power output from the AC / DC converter 21 of the power supply unit 20 is converted into AC power by the DC / AC converter 23 and supplied to the load 8. Further, the DC power output from the AC / DC converter 21 charges the storage battery 22. Since the amount of charge of the storage battery 22 decreases due to discharge or consumption due to consumption during a power failure, the storage battery 22 is charged by the AC / DC converter 21 as needed.

  When a power failure occurs in the power supply line 91, the DC power discharged from the storage battery 22 of the power supply unit 20 is converted into AC power by the DC / AC conversion unit 23 and supplied to the load 8. When a power failure occurs in the power supply line 91, power is not supplied from the commercial power supply 92 via the power supply line 91 and the input terminal 25. For this reason, the AC / DC converter 21 of the power supply unit 20 stops its operation.

  The AC / DC converter 21 converts AC power into DC power by switching a switching element built in the AC / DC converter 21. The DC / AC converter 23 converts DC power into AC power by switching a switching element built in the DC / AC converter 23.

[B. When sound generated by the cooling unit 28 is extracted]
As described above, the AC / DC converter 21 and the DC / AC converter 23 perform power conversion by switching the built-in switching elements. The switching frequency of the switching element, which is the operating frequency of the AC / DC converter 21 and the DC / AC converter 23, is controlled so as to change as appropriate according to the magnitudes of the input voltage and output current. For this reason, the switching frequency of the switching element which is the operating frequency of the AC / DC converter 21 and the DC / AC converter 23 changes randomly.

  The AC / DC converter 21 and the DC / AC converter 23 generate an operation sound called switching noise generated by switching of the switching element. The frequency of the operating sound applied to the switching noise corresponds to the switching frequency of the switching element that is the operating frequency of the AC / DC converter 21 and the DC / AC converter 23. For this reason, the frequency of the operating sound applied to the switching noise of the AC / DC converter 21 and the DC / AC converter 23 changes randomly.

  For this reason, when the frequency of the operating sound applied to the switching noise of the AC / DC converter 21 and the DC / AC converter 23 is the same as or close to the frequency of the generated sound of the cooling unit 28, only the generated sound generated by the cooling unit 28 is accurately detected. It was difficult to detect.

[B1. Operation of uninterruptible power supply 2]
When the sound generated by the cooling unit 28 is extracted, the calculation unit 34 performs the following control on each unit. An outline of the operation of the uninterruptible power supply 2 when the generated sound of the cooling unit 28 is extracted will be described focusing on the operation of the calculation unit 34 of the control unit 3. The calculation unit 34 of the control unit 3 operates according to the program shown in FIG. The program shown in FIG. 4 is built in the calculation unit 34 of the control unit 3. The program shown in FIG. 4 is repeatedly executed at regular intervals by the calculation unit 34 of the control unit 3.

(Step S01: Send the operation command C1 to the AC / DC converter 21)
The computing unit 34 transmits an operation command C1 (an operation command for designating an operating frequency of the AC / DC converter 21) to the AC / DC converter 21 via the output unit 32. As the operating frequency of the AC / DC converting unit 21 according to the operating command C1, for example, a high frequency separated from the frequency of the sound generated by the cooling unit 28 is selected. The operating frequency of the AC / DC converter 21 according to the operation command C1 is set in advance in the calculator 34 before the operation of the uninterruptible power supply 2 is started.

  As a result, the AC / DC converter 21 performs the switching operation of the switching element at a frequency specified by the operation command C <b> 1 higher than the frequency of the sound generated by the cooling unit 28, and converts AC power into DC power.

(Step S02: Send the operation command C2 to the DC / AC converter 23)
The computing unit 34 transmits an operation command C2 (an operation command for designating an operating frequency of the DC / AC conversion unit 23) to the DC / AC conversion unit 23 via the output unit 32. As the operating frequency of the DC / AC converting unit 23 according to the operating command C2, for example, a high frequency that is separated from the frequency of the sound generated by the cooling unit 28 is selected. The operating frequency of the DC / AC converter 23 applied to the operation command C2 is set in the calculator 34 in advance before the operation of the uninterruptible power supply 2 is started.

  As a result, the DC / AC converter 23 performs the switching operation of the switching element at a frequency specified by the operation command C2, which is higher than the frequency of the sound generated by the cooling unit 28, and converts DC power into AC power.

(Step S03: Send the operation command C3 to the cooling unit 28)
Next, the computing unit 34 transmits an operation command C3 (an operation command for designating the rotation speed of the cooling unit 28) to the cooling unit 28 via the output unit 32. As the rotation speed (rotation frequency) of the cooling unit 28 according to the operation command C3, for example, a low frequency separated from the frequency of the operation sound of the AC / DC conversion unit 21 and the DC / AC conversion unit 23 is selected. The rotation speed (rotation frequency) of the cooling unit 28 according to the operation command C3 is set in the calculation unit 34 in advance before the operation of the uninterruptible power supply 2 is started.

  Thereby, the cooling unit 28 rotates the cooling fan at a rotation frequency specified by the operation command C3, which is lower than the frequency of the operation sound of the AC / DC conversion unit 21 and the DC / AC conversion unit 23.

(Step S04: Receive signal data A from the detection unit 4)
Next, the calculation unit 34 receives the signal data A (signal data related to the operation sound of the power supply unit 20) from the detection unit 4 via the input unit 31. The detection unit 4 always detects the operation sound of the power supply unit 20 and performs analog-digital conversion, and outputs signal data related to the operation sound of the power supply unit 20 as signal data A. The signal data A includes signal data related to the sound generated by the cooling unit 28 of the power supply unit 20, the operation sound of the AC / DC conversion unit 21, the DC / AC conversion unit 23, and the environmental sound. The signal data A is always output from the detection unit 4.

(Step S05: The sound generated by the cooling unit 28 is extracted to generate signal data B)
Next, the calculation unit 34 extracts the sound generated by the cooling unit 28 based on the signal data A (signal data related to the operation sound of the power supply unit 20) received in step S04. As described above, the signal data A includes sound generated by the cooling unit 28, operation sounds of the AC / DC conversion unit 21, and the DC / AC conversion unit 23.

  However, the AC / DC converter 21 is based on the operation command C1 transmitted in step S01, and the DC / AC converter 23 is based on the operation command C2 transmitted in step S02. The frequency is higher than the frequency of the generated sound of the cooling unit 28. Switching operation is performed at. On the other hand, the cooling unit 28 rotates the cooling fan at a frequency lower than the frequency of the operation sound of the AC / DC converter 21 and the DC / AC converter 23 based on the operation command C3 transmitted in step S03.

  Therefore, the frequency of the sound generated by the cooling unit 28 is a low frequency separated from the frequency of the operating sound of the AC / DC converter 21 and the DC / AC converter 23. The calculation unit 34 performs filtering processing using FFT (Fast Fourier Transform) or the like, removes the frequency band applied to the operation sound of the AC / DC conversion unit 21 and the DC / AC conversion unit 23 from the signal data A, and generates the cooling unit 28. Extract sound.

  Alternatively, when the detection unit 4 includes a plurality of microphones, the calculation unit 34 performs beam forming processing with increased directivity in the cooling unit 28 direction, independent component analysis (ICA), independent vector analysis (IVA, Independent). Processing such as sound source separation processing based on Vector Analysis) is performed, operation sounds of the AC / DC converter 21 and the DC / AC converter 23 are removed from the signal data A, and sound generated by the cooling unit 28 is extracted. The calculation unit 34 extracts the sound generated by the cooling unit 28 from the signal data A, and creates signal data B (signal data related to the sound generated by the cooling unit 28).

(Step S06: Transmit signal data B)
Next, the calculation unit 34 transmits the signal data B extracted in step S05 (signal data related to the sound generated by the cooling unit 28) to the determination unit 5 via the transmission unit 33.

  The above is the operation of the calculation unit 34 of the control unit 3. As described above, based on the signal data A (signal data concerning the operation sound of the power supply unit 20), the signal data B (signal data concerning the sound generated by the cooling unit 28) is created.

[B2. Operation of determination unit 5]
The determination unit 5 that has received the signal data B (signal data related to the sound generated by the cooling unit 28) from the transmission unit 33 of the control unit 3 of the uninterruptible power supply 2 performs the following operation. The determination unit 5 determines deterioration of the cooling unit 28 of the power supply unit 20 of the uninterruptible power supply 2 based on the signal data B, and outputs it by display, alarm, or the like.

  An outline of the operation of the determination unit 5 when the determination of the deterioration of the cooling unit 28 of the power supply unit 20 of the uninterruptible power supply 2 by the determination unit 5 will be described focusing on the operation of the calculation unit 56 of the determination unit 5. The calculation unit 56 of the determination unit 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 repeatedly executed by the calculation unit 56 of the determination unit 5.

(Step R01: Determine whether signal data B is received)
First, the calculation unit 56 determines whether the reception unit 51 has received the signal data B (signal data related to the sound generated by the cooling unit 28) from the uninterruptible power supply 2.

  When the calculation unit 56 determines that the signal data B has been received from the uninterruptible power supply 2 (YES in step R01), the process proceeds to step R02. When the calculation unit 56 does not determine that the signal data B has been received from the uninterruptible power supply 2 (NO in step R01), the process proceeds to step R01 again, and the signal data B reception wait state is entered.

(Step R02: Call the reference data E stored in the storage unit 52)
When it is determined in step R01 that the signal data B (signal data related to the sound generated by the cooling unit 28) has been received, the calculation unit 56 stores the reference data E (deterioration of the cooling unit 28) stored in the storage unit 52. Call the data that is the basis for judgment. The reference data E is signal data relating to the sound generated by the cooling unit 28 in a state where there is no deterioration.

(Step R03: Display the signal data B and the reference data E on the display unit 53)
Next, the calculation unit 56 receives the signal data B (signal data relating to the sound generated by the cooling unit 28) received in step R01 and the reference data E (reference for determining deterioration of the cooling unit 28) called in step R02. Are displayed on the display unit 53 together. By displaying the signal data B and the reference data E together on the display unit 53, the operator can visually grasp the deterioration state of the cooling unit 28.

(Step R04: Determine whether the difference between the signal data B and the reference data E is greater than or equal to the reference value)
Next, the calculation unit 56 receives the signal data B (signal data related to the sound generated by the cooling unit 28) received in step R01 and the reference data E (reference for determining deterioration of the cooling unit 28) called in step R02. It is determined whether or not the difference between the data is equal to or greater than a preset reference value.

  The calculation unit 56 calculates the difference between the volume of the signal data B and the volume of the reference data E. Alternatively, the calculation unit 56 calculates a difference between frequency domain signal data such as a power spectrum obtained by frequency conversion of the signal data B and frequency domain signal data such as a power spectrum obtained by frequency conversion of the reference data E. The frequency conversion is performed using fast Fourier transform or the like. If this difference is greater than or equal to a preset reference value, the calculation unit 56 determines that the cooling unit 28 has deteriorated. The difference between the signal data B and the reference data E is calculated for a specific frequency at which the cooling unit 28 emits abnormal noise.

  Alternatively, a neural network such as an auto encoder (self-encoder) is set in advance using machine learning from the reference data E, and a distance that is an output when the signal data B is input to the neural network is calculated. When the distance is equal to or greater than a preset reference value, the calculation unit 56 may determine that the cooling unit 28 has deteriorated.

  For example, when the cooling unit 28 is deteriorated, the volume of the wind noise generated by the cooling fan and the noise generated by rubbing between the cooling fan and the support member increases. The above-described difference calculation is performed for the wind noise generated by the cooling fan and the frequency band of the rubbing sound between the cooling fan and the support member. When the volume of the signal data B is equal to or higher than a reference value set in advance from the volume of the reference data E, the calculation unit 56 increases the volume of the wind noise generated by the cooling fan and the noise generated by the friction between the cooling fan and the support member. Then, it is determined that the cooling unit 28 has deteriorated.

  When the calculating part 56 judges that it is more than a reference value (YES of step R04), it transfers to step R05. If the calculation unit 56 does not determine that the value is greater than or equal to the reference value (NO in step R04), the series of programs is terminated.

(Step R05: Output an alarm from the alarm output unit 54)
When it is determined in step R04 that the value is equal to or greater than the reference value, the calculation unit 56 outputs an alarm signal F (an alarm signal for warning of deterioration of the cooling unit 28) to the alarm output unit 54. Based on the alarm signal F, the alarm output unit 54 outputs an alarm with an alarm sound and an alarm display.

  If it is determined in step R04 that the value is greater than or equal to the reference value, it is estimated that the cooling unit 28 has deteriorated. For example, the alarm signal F includes a signal indicating a distinction between “increase in wind noise by the cooling fan” or “increase in rubbing noise between the cooling fan and the support member”. For example, when the alarm signal F indicates “increase in wind noise by the cooling fan”, the alarm output unit 54 turns on the yellow lamp and outputs an alarm.

  Further, for example, when the alarm signal F indicates “increase in rubbing noise between the cooling fan and the support member”, the alarm output unit 54 outputs a warning by turning on the red lamp and generating a buzzer sound. Based on the alarm signal F, the alarm output unit 54 outputs an alarm with an alarm sound and an alarm display. Further, the alarm may be output from the transmission / reception unit 55 by a message.

  The above is the operation of the determination unit 5. As described above, the determination unit 5 determines the deterioration of the cooling unit 28 based on the signal data B (signal data relating to the sound generated by the cooling unit 28).

[1-3. effect]
(1) According to the present embodiment, the uninterruptible power supply system 1 charges an AC / DC converter 21 that converts the supplied AC power into an AC / DC converter, and DC power supplied from the AC / DC converter 21. At least one of a storage battery 22 for discharging power, a DC / AC conversion unit 23 for converting DC power discharged from the storage battery 22 and outputting AC power, an AC / DC conversion unit 21, and a DC / AC conversion unit 23 is used. A power supply unit 20 having a cooling unit 28 for cooling, a detection unit 4 for detecting an operation sound of the power supply unit 20, and a timing at which the detection unit 4 detects the operation sound is controlled to extract a sound generated by the cooling unit 28 Control unit 3 and a determination unit 5 that determines deterioration of the cooling unit 28 based on the sound generated by the cooling unit 28 extracted by the control unit 3, so that the generated sound of the cooling unit 28 can be accurately extracted. The deterioration of the cooling part It is possible to provide an uninterruptible power supply system 1 can be detected in the period.

  When the detection unit 4 detects the operation sound, the control unit 3 controls the operation of the AC / DC conversion unit 21, the DC / AC conversion unit 23, or the cooling unit 28, and the detection unit 4 detects the operation sound at this timing. The sound generated by the cooling unit 28 can be extracted with high accuracy.

(2) According to this embodiment, the control unit 3 controls the AC / DC conversion unit 21 and the DC / AC conversion unit 23 to operate at a predetermined frequency, and the AC / DC conversion unit 21 and the DC / AC conversion unit 23 Since the detection unit 4 is controlled so as to detect the operation sound of the power supply unit 20 at the timing of operating at a predetermined frequency, the frequency band of the operation sound of the AC / DC conversion unit 21 and the DC / AC conversion unit 23, and the cooling unit 28 can be separated from the frequency band of the generated sound, and by removing the sound of the frequency components of the AC / DC converter 21 and the DC / AC converter 23 from the operation sound detected by the detector 4, The sound generated by the cooling unit 28 can be extracted with certainty.

(3) According to the present embodiment, the control unit 3 controls the cooling unit 28 to operate at a predetermined frequency, and the operation sound of the power supply unit 20 at the timing when the cooling unit 28 operates at the predetermined frequency. Since the detection unit 4 is controlled so as to detect the noise, the frequency band of the operation sound of the AC / DC conversion unit 21 and the DC / AC conversion unit 23 and the frequency band of the generated sound of the cooling unit 28 can be separated. By removing the sound of the frequency components of the AC / DC conversion unit 21 and the DC / AC conversion unit 23 from the operation sound detected by the unit 4, the generated sound of the cooling unit 28 can be more reliably extracted.

[1-4. Modified example]
(1) In the above embodiment, the operation command C1 (operation command for specifying the operation frequency of the AC / DC conversion unit 21) set in advance in the calculation unit 34 of the uninterruptible power supply 2 is transmitted to the AC / DC conversion unit 21, The AC / DC converter 21 performs the switching operation of the switching element at the frequency specified by the operation command C1.

  In addition, an operation command C2 (an operation command designating an operation frequency of the DC / AC conversion unit 23) set in advance in the calculation unit 34 of the uninterruptible power supply 2 is transmitted to the DC / AC conversion unit 23, and the DC / AC conversion unit 23 The switching operation of the switching element is performed at the frequency specified by the operation command C2.

  There may be a plurality of operating frequencies of the AC / DC converting unit 21 applied to the operation command C1 set in advance in the calculating unit 34 and operating frequencies of the DC / AC converting unit 23 applied to the operating command C2.

  The calculation unit 34 operates the AC / DC conversion unit 21 and the DC / AC conversion unit 23 at a plurality of frequencies, and outputs signals from the detection unit 4 for each of the plurality of frequencies at which the AC / DC conversion unit 21 and the DC / AC conversion unit 23 operate. Data A (signal data relating to the operation sound of the power supply unit 20) may be received. The calculation unit 34 extracts the sound generated by the cooling unit 28 from the signal data A for each of a plurality of frequencies at which the AC / DC conversion unit 21 and the DC / AC conversion unit 23 operate, and generates signal data B (the generated sound of the cooling unit 28). Such signal data) is created. By doing in this way, the sound generated by the cooling unit 28 can be extracted with higher accuracy.

(2) In the above embodiment, the operation command C3 (operation command for designating the rotation speed of the cooling unit 28) preset in the calculation unit 34 of the uninterruptible power supply 2 is transmitted to the cooling unit 28, and the cooling unit 28 The operation of rotating the cooling fan at the rotation frequency specified by the operation command C3 (operation command for specifying the rotation speed of the cooling unit 28) is performed.

  The number of rotations of the cooling unit 28 according to the operation command C3 set in advance in the calculation unit 34 may be plural. The calculation unit 34 operates the cooling unit 28 at a plurality of rotation speeds, and the signal data A (signal data relating to the operation sound of the power supply unit 20) from the detection unit 4 for each of the plurality of rotation speeds at which the cooling unit 28 operates. May be received. The calculation unit 34 extracts sound generated by the cooling unit 28 from the signal data A for each of a plurality of rotation speeds at which the cooling unit 28 operates, and creates signal data B (signal data related to the sound generated by the cooling unit 28). . By doing in this way, the sound generated by the cooling unit 28 can be extracted with higher accuracy.

(3) In the above embodiment, the operation command C1 is transmitted to the AC / DC converter 21 in step S01, and the operation command C2 is transmitted to the DC / AC converter 23 in step S02. The unit 23 is operated at a predetermined frequency, and an operation command C3 is transmitted to the cooling unit 28 in step S03 so that the cooling unit 28 is operated at a predetermined number of revolutions.

  The steps S01 and S02 for operating the AC / DC conversion unit 21 and the DC / AC conversion unit 23 at a predetermined frequency may be executed, and the step S03 for operating the cooling unit 28 at a predetermined rotation speed may not be executed. Alternatively, steps S01 and S02 for operating the AC / DC conversion unit 21 and the DC / AC conversion unit 23 at a predetermined frequency may not be performed, and step S03 for operating the cooling unit 28 at a predetermined number of rotations may be performed. Good. By executing in this way, it is possible to perform quick processing by the program.

[2. Second Embodiment]
[2-1. Constitution]
As an example of the present embodiment, an uninterruptible power supply system 1 according to the second embodiment will be described. The uninterruptible power supply system 1 according to the second embodiment differs from the first embodiment in the process of extracting sound generated by the cooling unit 28. In the uninterruptible power supply system 1, signals and data created, stored or transmitted / received are the same as those in the first embodiment. The signal data A1 (signal data relating to the operation sound during the entire operation of the power supply unit 20) is the first operation sound in the claims, the signal data A3 (signal data relating to the operation sound when the cooling unit 28 is stopped), This corresponds to the second operation sound in the claims.

  The configuration of the uninterruptible power supply 2 of the second embodiment is shown in FIG. The uninterruptible power supply 2 of 2nd Embodiment has the power supply part 20, the control part 3, the detection part 4, and the temperature measurement part 6. FIG. The uninterruptible power supply 2 of the second embodiment is different from the uninterruptible power supply 2 of the first embodiment in that it has a temperature measuring unit 6. Moreover, the control part 3 of the uninterruptible power supply 2 of 2nd Embodiment incorporates the program different from 1st Embodiment in the calculating part 34. FIG. The entire configuration of the uninterruptible power supply system 1 of the second embodiment is the same as the configuration of the first embodiment shown in FIG.

  The temperature measuring unit 6 is configured by a device in which a temperature sensor such as a resistance temperature detector or a thermocouple and an analog-digital converter are combined. The temperature measuring unit 6 is preferably configured by a plurality of temperature sensors. The temperature measurement unit 6 is inside the casing that forms the uninterruptible power supply 2, and is installed in the vicinity of the AC / DC conversion unit 21, the storage battery 22, and the DC / AC conversion unit 23. The temperature measuring unit 6 is connected to the input unit 31 of the control unit 3.

  The temperature measurement unit 6 detects the temperature inside the uninterruptible power supply 2 such as the AC / DC conversion unit 21, the storage battery 22, the DC / AC conversion unit 23, etc., and converts the temperature into analog-digital conversion. Output.

[2-2. Action]
Next, the outline | summary of operation | movement of the uninterruptible power supply system 1 of this embodiment is demonstrated based on FIGS. The operation in the normal operation in which the generated sound of the cooling unit 28 is not extracted is the same as that in the first embodiment. When the sound generated by the cooling unit 28 is extracted, the calculation unit 34 performs the following control on each unit. An outline of the operation of the uninterruptible power supply 2 when the generated sound of the cooling unit 28 is extracted will be described focusing on the operation of the calculation unit 34 of the control unit 3. The calculation unit 34 of the control unit 3 operates according to the program shown in FIG. The program shown in FIG. 7 is built in the calculation unit 34 of the control unit 3. The program shown in FIG. 7 is repeatedly executed at regular intervals by the calculation unit 34 of the control unit 3.

(Step S11: The operation command C3 is transmitted to the cooling unit 28)
First, the calculation unit 34 transmits an operation command C3 (an operation command for designating the rotation speed of the cooling unit 28) to the cooling unit 28 via the output unit 32. The number of rotations (rotational frequency) of the cooling unit 28 according to the operation command C3 is the temperature inside the uninterruptible power supply 2 such as the AC / DC conversion unit 21, the storage battery 22, and the DC / AC conversion unit 23. A high-speed rotation speed that can be lower than that during normal operation without extraction is selected. The rotation speed (rotation frequency) of the cooling unit 28 according to the operation command C3 is set in the calculation unit 34 in advance before the operation of the uninterruptible power supply 2 is started.

  Thereby, the cooling unit 28 rotates the cooling fan at the rotation frequency specified by the operation command C3, and changes the temperature inside the uninterruptible power supply 2 such as the AC / DC conversion unit 21, the storage battery 22, and the DC / AC conversion unit 23, The temperature of the cooling unit 28 is set to a lower temperature than during normal operation in which the generated sound is not extracted.

(Step S12: It is determined whether the temperature inside the uninterruptible power supply 2 is equal to or lower than the temperature T1)
Next, the calculation unit 34 receives the temperature data G from the temperature measurement unit 6 via the input unit 31. The temperature data G is data relating to the temperature inside the uninterruptible power supply 2 such as the AC / DC converter 21, the storage battery 22, and the DC / AC converter 23. Based on the temperature data G, the calculation unit 34 determines whether the temperature inside the uninterruptible power supply 2 such as the AC / DC conversion unit 21, the storage battery 22, and the DC / AC conversion unit 23 is equal to or lower than a preset temperature T <b> 1.

  The preset temperature T1 is equal to the time until the sound generated by the cooling unit 28 is extracted, and even if the operation of the cooling unit 28 is stopped, the uninterruptible power supply 2 is increased due to an increase in the internal temperature of the uninterruptible power supply 2. The temperature at which no deterioration or failure occurs. The temperature T1 is set in the calculation unit 34 in advance before the operation of the uninterruptible power supply 2 is started.

  When it is determined that the temperature is equal to or lower than the temperature T1 (YES in step S12), the process proceeds to step S13. If it is not determined that the temperature has become equal to or lower than the temperature T1 (NO in step S12), the process proceeds to step S12 again to wait for the temperature inside the uninterruptible power supply 2 to become equal to or lower than a preset temperature T1.

(Step S13: The signal data A1 is received from the detection unit 4)
When it is determined in step S12 that the temperature inside the uninterruptible power supply 2 has become equal to or lower than a preset temperature T1, the calculation unit 34 receives signal data A1 (the entire power supply unit 20) from the detection unit 4 via the input unit 31. The signal data relating to the operation sound during operation is received. The signal data A includes signal data related to the sound generated by the cooling unit 28 of the power supply unit 20, the operation sound of the AC / DC conversion unit 21, the DC / AC conversion unit 23, and the environmental sound.

(Step S14: A stop command D3 is transmitted to the cooling unit 28)
Next, the computing unit 34 transmits a stop command D3 (a stop command for instructing to stop the operation of the cooling unit 28) to the cooling unit 28 via the output unit 32. Thereby, the cooling unit 28 stops the operation of the movable unit such as the cooling fan. Therefore, the sound generated by the cooling unit 28 is silent.

(Step S15: Receive signal data A3 from the detection unit 4)
Next, the calculation unit 34 receives the signal data A3 (signal data related to the operation sound when the cooling unit 28 is stopped) from the detection unit 4 via the input unit 31. The signal data A3 includes signal data relating to the operation sound and environmental sound of the AC / DC converter 21 and DC / AC converter 23 of the power supply unit 20, and does not include the sound generated by the cooling unit 28.

(Step S16: The sound generated by the cooling unit 28 is extracted to generate signal data B)
Next, the calculation unit 34 applies the signal data A1 received in step S13 (signal data related to the operation sound when the entire power supply unit 20 operates) and the signal data A3 received in step S15 (applies to the operation sound when the cooling unit 28 is stopped). Based on the signal data, the sound generated by the cooling unit 28 is extracted.

  As described above, the signal data A1 includes signal data related to the sound generated by the cooling unit 28 of the power supply unit 20, the operation sound of the AC / DC conversion unit 21, the DC / AC conversion unit 23, and the environmental sound. Further, the signal data A3 includes signal data related to the operation sound and the environmental sound of the AC / DC converter 21 and the DC / AC converter 23 of the power supply unit 20, and does not include the sound generated by the cooling unit 28.

  The calculation unit 34 subtracts the signal data A3 from the signal data A1, removes the operation sound and the environmental sound of the AC / DC conversion unit 21 and the DC / AC conversion unit 23 from the signal data A1, and extracts the generated sound of the cooling unit 28. . The calculation unit 34 extracts the sound generated by the cooling unit 28 and creates signal data B (signal data related to the sound generated by the cooling unit 28).

(Step S17: Send the operation command C3 to the cooling unit 28)
Next, the computing unit 34 transmits an operation command C3 (an operation command for designating the rotation speed of the cooling unit 28) to the cooling unit 28 via the output unit 32. The number of rotations (rotation frequency) of the cooling unit 28 according to the operation command C3 is the number of rotations during normal operation in which sound generated by the cooling unit 28 is not extracted. As a result, the cooling unit 28 rotates the cooling fan at the number of rotations during normal operation where the sound generated by the cooling unit 28 is not extracted.

(Step S18: Transmit signal data B)
Next, the calculation unit 34 transmits the signal data B extracted in step S <b> 16 (signal data related to the sound generated by the cooling unit 28) to the determination unit 5 via the transmission unit 33.

  The above is the operation of the calculation unit 34 of the control unit 3. As described above, the signal data B is created based on the signal data A1 (signal data related to the operation sound when the power supply unit 20 operates as a whole) and the signal data A3 (signal data related to the operation sound when the cooling unit 28 is stopped). .

[2-3. effect]
(1) According to the present embodiment, the control unit 3 controls the detection unit 4 to detect the first operation sound of the power supply unit 20 at the timing when the cooling unit 28 is operating, and stops the operation. The cooling unit 28 is controlled as described above, and the detection unit 4 is controlled to detect the second operation sound of the power supply unit 20 at the timing when the cooling unit 28 is stopped, and the first detected by the detection unit 4 Since the second operation sound is subtracted from the operation sound and the generated sound of the cooling unit 28 is extracted, the generated sound of the cooling unit 28 can be extracted accurately and the deterioration of the cooling unit can be detected at an early stage. A system 1 can be provided.

  When the detection unit 4 detects an operation sound, the control unit 3 controls to stop the operation of the cooling unit 28, and the AC / DC conversion unit 21 and the DC / AC conversion unit 23 continue to operate. For this reason, the generated sound of the cooling unit 28 can be accurately extracted without stopping the power supply to the load 8.

(2) According to the present embodiment, the control unit 3 operates the cooling unit 28 so as to stop the operation of the cooling unit 28 when the temperature of the power supply unit 20 is equal to or lower than a predetermined temperature. And the detection unit 4 is controlled so as to detect the second operation sound of the power supply unit 20 at the timing when the cooling unit 28 is stopped. For this reason, the second operating sound can be detected by the detection unit 4 when the temperature inside the power supply unit 20 including the AC / DC conversion unit 21 and the DC / AC conversion unit 23 is equal to or lower than a predetermined temperature, and the temperature rises. It is possible to reduce deterioration and failure of the power supply unit 20 including the AC / DC conversion unit 21 and the DC / AC conversion unit 23.

  Further, when the detection unit 4 detects the first operation sound and the second operation sound, the AC / DC conversion unit 21 and the DC / AC conversion unit 23 continue to operate, so that the power supply to the load 8 is stopped. Therefore, the sound generated by the cooling unit 28 can be extracted with high accuracy.

[2-4. Modified example]
(1) In the above embodiment, the operation command C3 (an operation command for designating the rotation speed of the cooling unit 28) is transmitted to the cooling unit 28 in step S11, and the AC / DC conversion unit 21, the storage battery 22, and the DC / AC conversion unit 23 are transmitted. The temperature inside the uninterruptible power supply 2 was forcibly lowered. However, when the temperature inside the uninterruptible power supply 2 such as the AC / DC converter 21, the storage battery 22, and the DC / AC converter 23 is equal to or lower than the preset temperature T1, step S11 is omitted. Also good.

(2) In the above embodiment, the rotation speed (rotation frequency) of the cooling unit 28 according to the operation command C3 is set in the calculation unit 34 in advance before the operation of the uninterruptible power supply 2 is started. The rotation speed (rotation frequency) of the cooling unit 28 according to the command C3 may be appropriately selected by the calculation unit 34 according to the temperature measured by the temperature measurement unit 6.

(3) In the above embodiment, when the temperature is detected by the temperature measurement unit 6 and the temperature inside the uninterruptible power supply 2 is equal to or lower than the preset temperature T1, the control unit 3 generates the cooling unit 28. Added an operation to extract sound. The power or current output from the uninterruptible power supply 2 is detected in addition to or in place of the temperature measurement unit 6 and is cooled by the control unit 3 when the power or current is below a preset threshold value. The operation of extracting the sound generated by the unit 28 may be performed.

[3. Third Embodiment]
[3-1. Constitution]
As an example of the present embodiment, an uninterruptible power supply system 1 according to a third embodiment will be described. The uninterruptible power supply system 1 according to the third embodiment is different from the first embodiment in that the uninterruptible power supply system 2 has a plurality of uninterruptible power supply devices 2a and 2b and the sound extraction process of the cooling unit 28. The uninterruptible power supply 2b corresponds to a second power supply unit in the claims. In the uninterruptible power supply system 1, signals and data created, stored or transmitted / received are the same as those in the first embodiment.

  The configuration of the uninterruptible power supply system 1 of the third embodiment is shown in FIG. The uninterruptible power supply system 1 includes uninterruptible power supply apparatuses 2 a and 2 b and a determination unit 5. The uninterruptible power supply system 1 of the third embodiment is different from the uninterruptible power supply system 1 of the first embodiment in that it has an uninterruptible power supply 2b.

  In the uninterruptible power supply 2a, the sound generated by the cooling unit 28 is extracted in the same manner as the uninterruptible power supply 2 of the first embodiment. The uninterruptible power supply 2b is a backup uninterruptible power supply that outputs power based on a power supply command H that requests supply of power transmitted from the uninterruptible power supply 2a. The configuration of the uninterruptible power supply 2b is the same as that of the uninterruptible power supply 2a.

  The configuration of the uninterruptible power supply 2a of the third embodiment is shown in FIG. The uninterruptible power supply 2a of 3rd Embodiment has the power supply part 20, the control part 3, and the detection part 4, and the control part 3 is the input part 31, the output part 32, the transmission part 33, the calculating part 34, and the transmission / reception part 35. Have The uninterruptible power supply 2a of the third embodiment differs from the uninterruptible power supply 2 of the first embodiment in that the control unit 3 includes a transmission / reception unit 35. Moreover, the control part 3 of the uninterruptible power supply 2a of 3rd Embodiment incorporates the program different from 1st Embodiment in the calculating part 34. FIG.

  The transmission / reception unit 35 includes a communication port of a microcomputer. The transmission / reception unit 35 is connected to a dedicated communication line or a communication line (not shown) such as the Internet. The transmission / reception unit 35 of the uninterruptible power supply 2a communicates with the uninterruptible power supply 2b via a communication line. The transmission / reception unit 35 of the uninterruptible power supply 2a transmits a power supply command H for requesting power supply to the uninterruptible power supply 2b.

  The uninterruptible power supply 2b receives the power supply command H via the transmitter / receiver 35 inside the uninterruptible power supply 2b, and supplies power to the auxiliary input terminal 26 of the uninterruptible power supply 2a. The electric power supplied to the auxiliary input terminal 26 of the uninterruptible power supply 2a is supplied to the load 8 through the bypass circuit 24 of the uninterruptible power supply 2a.

[3-2. Action]
Next, the outline | summary of operation | movement of the uninterruptible power supply system 1 of this embodiment is demonstrated based on FIGS. The operation in the normal operation in which the generated sound of the cooling unit 28 is not extracted is the same as that in the first embodiment. When the generated sound of the cooling unit 28 of the uninterruptible power supply 2a is extracted, the calculation unit 34 of the uninterruptible power supply 2a performs the following control on each part.

  An outline of the operation of the uninterruptible power supply 2a when the generated sound of the cooling unit 28 is extracted will be described focusing on the operation of the calculation unit 34 of the control unit 3. The calculation unit 34 of the control unit 3 operates according to the program shown in FIG. The program shown in FIG. 10 is built in the calculation unit 34 of the control unit 3. The program shown in FIG. 10 is repeatedly executed at regular intervals by the calculation unit 34 of the control unit 3.

(Step S21: Transmit power supply command H to uninterruptible power supply 2b)
First, the calculation unit 34 of the uninterruptible power supply 2a transmits a power supply command H for requesting supply of power to the uninterruptible power supply 2b via the transmission / reception unit 35. The uninterruptible power supply 2b receives the power supply command H via the transmitter / receiver 35 inside the uninterruptible power supply 2b, and supplies power to the auxiliary input terminal 26 of the uninterruptible power supply 2a.

(Step S22: The bypass circuit 24 is closed)
Next, the calculating part 34 makes the bypass circuit 24 of the uninterruptible power supply 2a a closed state. Thereby, the electric power supplied to the auxiliary input terminal 26 of the uninterruptible power supply 2a is supplied to the load 8 through the bypass circuit 24.

(Step S23: A stop command D1 is transmitted to the AC / DC converter 21)
The computing unit 34 transmits a stop command D1 (a stop command for instructing to stop the operation of the AC / DC converter 21) to the AC / DC converter 21 via the output unit 32. The stop command D1 is a command for instructing to stop the switching operation of the switching element of the AC / DC converter 21. As a result, the AC / DC converter 21 stops the switching operation of the switching element, and the operating sound of the AC / DC converter 21 is silenced.

(Step S24: Send stop command D2 to DC / AC converter 23)
The computing unit 34 transmits a stop command D2 (a stop command for instructing to stop the operation of the DC / AC converter 23) to the DC / AC converter 23 via the output unit 32. The stop command D2 is a command for instructing to stop the switching operation of the switching element of the DC / AC converter 23. As a result, the DC / AC converter 23 stops the switching operation of the switching element, and the operating sound of the DC / AC converter 23 is silenced.

(Step S25: Receive the signal data A2 from the detection unit 4)
Next, the calculation unit 34 receives the signal data A2 (signal data related to the operation sound when the AC / DC conversion unit 21 and the DC / AC conversion unit 23 are stopped) from the detection unit 4 via the input unit 31. The signal data A2 includes signal data related to the sound generated by the cooling unit 28 of the power supply unit 20, and does not include the operation sounds of the AC / DC conversion unit 21 and the DC / AC conversion unit 23 of the power supply unit 20. The calculation unit 34 uses the signal data A2 as signal data B (signal data related to the sound generated by the cooling unit 28) from which the sound generated by the cooling unit 28 is extracted.

(Step S26: Send the operation command C1 to the AC / DC converter 21)
The calculation unit 34 transmits an operation command C1 (an operation command for designating the operation frequency of the AC / DC conversion unit 21) to the AC / DC conversion unit 21 via the output unit 32, and the generated sound of the cooling unit 28 is not extracted. Resumes normal operation.

(Step S27: Send the operation command C2 to the DC / AC converter 23)
The calculation unit 34 transmits an operation command C2 (an operation command for designating an operation frequency of the DC / AC conversion unit 23) to the DC / AC conversion unit 23 via the output unit 32, and the generated sound of the cooling unit 28 is not extracted. Resumes normal operation.

(Step S28: Transmit signal data B)
Next, the calculation unit 34 transmits the signal data B (signal data related to the sound generated by the cooling unit 28) created in step S25 to the determination unit 5 via the transmission unit 33.

  The above is the operation of the calculation unit 34 of the control unit 3. As described above, the signal data B (signal data relating to the sound generated by the cooling unit 28) is created.

[3-3. effect]
(1) According to the present embodiment, the control unit 3 controls the AC / DC conversion unit 21 and the DC / AC conversion unit 23 to stop the operation, and the AC / DC conversion unit 21 and the DC / AC conversion unit 23 stop. In addition, the detection unit 4 is controlled so as to detect the operation sound of the power supply unit 20 at the timing when the cooling unit 28 is operating, and the generated sound of the cooling unit 28 is extracted. It is possible to provide the uninterruptible power supply system 1 that can be extracted accurately and can detect the deterioration of the cooling unit at an early stage.

  When the detection unit 4 detects an operation sound, the control unit 3 performs control so as to stop the operations of the AC / DC conversion unit 21 and the DC / AC conversion unit 23, and the cooling unit 28 continues to operate. For this reason, the sound generated by the cooling unit 28 can be extracted with high accuracy.

(2) According to the present embodiment, when the control unit 3 performs control to stop the operations of the AC / DC conversion unit 21 and the DC / AC conversion unit 23, the second power source provided outside the power source unit 20. Since the control for operating the uninterruptible power supply 2b, which is a unit, is performed, when the detection unit 4 detects an operation sound, the power supply to the load 8 is not stopped and the generated sound of the cooling unit 28 is accurately extracted. can do.

[3-4. Modified example]
(1) In the above embodiment, the power supply command H for requesting power supply to the uninterruptible power supply 2b is transmitted from the computing unit 34 of the uninterruptible power supply 2a in step S21. The power is supplied to the auxiliary input terminal 26 of the uninterruptible power supply 2a. However, when power supply to the load 8 is unnecessary, step S21 may be omitted.

[4. Fourth Embodiment]
[4-1. Constitution]
As an example of the present embodiment, an uninterruptible power supply system 1 according to a fourth embodiment will be described. The uninterruptible power supply system 1 according to the fourth embodiment differs from the first embodiment in the process of extracting sound generated by the cooling unit 28.

  The configuration of the uninterruptible power supply 2 of the fourth embodiment is shown in FIG. The uninterruptible power supply 2 of 4th Embodiment has the power supply part 20, the control part 3, the detection part 4, and the reference | standard sound generation part 7. FIG. The detection unit 4 includes a first sound detection unit 41 and a second sound detection unit 42. The uninterruptible power supply 2 of the fourth embodiment is different from the first embodiment in that the reference sound generating unit 7 and the detection unit 4 have a first sound detection unit 41 and a second sound detection unit 42. Different from the uninterruptible power supply 2. Moreover, the control part 3 of the uninterruptible power supply 2 of 4th Embodiment incorporates the program different from 1st Embodiment in the calculating part 34. FIG. The overall configuration of the uninterruptible power supply system 1 of the fourth embodiment is the same as the configuration of the first embodiment shown in FIG.

  The reference sound generator 7 is configured by a device in which an oscillator is combined with a sound generating member such as a speaker or a ceramic vibrator. The reference sound generator 7 generates a reference sound with a predetermined volume and frequency. The reference sound generating unit 7 is inside the casing constituting the uninterruptible power supply 2 and is installed in the vicinity of the AC / DC converter 21 and the DC / AC converter 23. The reference sound generating unit 7 is connected to the output unit 32 of the control unit 3.

  The reference sound generating unit 7 is controlled by the control unit 3 and generates a reference sound with a predetermined volume and frequency. The reference sound is preferably a sound having a frequency outside the audible range, such as an ultrasonic wave. The reference sound generated by the reference sound generation unit 7 is a first operation sound detected by the first sound detection unit 41 and a second sound detection when the generated sound of the cooling unit 28 is extracted by the control unit. This is used when determining the adjustment amount for adjusting the volume level with the second operation sound detected by the unit 42.

  The detection unit 4 includes a first sound detection unit 41 and a second sound detection unit 42. The first sound detection unit 41 is disposed in the vicinity of the cooling unit 28. The first sound detection unit 41 detects sound generated by the cooling unit 28, reference sound generated by the reference sound generation unit 7, and operation sound of the AC / DC conversion unit 21 and the DC / AC conversion unit 23.

  The second sound detection unit 42 is disposed in the vicinity of the AC / DC conversion unit 21 or the DC / AC conversion unit 23. The first sound detection unit 41 detects sound generated by the cooling unit 28, reference sound generated by the reference sound generation unit 7, and operation sound of the AC / DC conversion unit 21 and the DC / AC conversion unit 23. FIG. 13 shows the relationship between the sound frequency detected by the first sound detector 41 and the second sound detector 42 and the volume level.

[4-2. Action]
Next, the outline | summary of operation | movement of the uninterruptible power supply system 1 of this embodiment is demonstrated based on FIGS. An outline of the operation of the uninterruptible power supply 2 relating to the extraction of sound generated by the cooling unit 28 will be described focusing on the operation of the calculation unit 34 of the control unit 3. The calculation unit 34 of the control unit 3 operates according to the program shown in FIG. The program shown in FIG. 12 is built in the calculation unit 34 of the control unit 3. The program shown in FIG. 12 is repeatedly executed at regular intervals by the calculation unit 34 of the control unit 3.

(Step S31: Generate a reference sound from the reference sound generator 7)
First, the calculation unit 34 controls the reference sound generation unit 7 via the output unit 32 and generates a reference sound from the reference sound generation unit 7. The reference sound generated from the reference sound generator 7 has a predetermined volume and frequency. The reference sound is generated from the reference sound generator 7 installed in the vicinity of the AC / DC converter 21 and the DC / AC converter 23. Therefore, in the first operation sound A41 detected by the first sound detection unit 41 and the second operation sound A42 detected by the second sound detection unit 42, the reference sound, the AC / DC converter 21 and the DC The volume ratio with the operation sound of the AC converter 23 is equivalent.

(Step S32: Receive the first operation sound A41 from the first sound detection unit 41)
Next, the calculation unit 34 receives the first operation sound A41 from the first sound detection unit 41 of the detection unit 4 via the input unit 31. The generated sound X of the cooling unit 28, the AC / DC converter 21, the operating sound Y of the DC / AC converter 23, and the reference sound Z generated by the reference sound generator 7 are included.

(Step S33: The second operation sound A42 is received from the second sound detection unit 42)
Next, the calculation unit 34 receives the second operation sound A 42 from the second sound detection unit 42 of the detection unit 4 via the input unit 31. In the second operation sound A42, the operation sound Y of the AC / DC conversion unit 21, the DC / AC conversion unit 23, and the reference sound Z generated by the reference sound generation unit 7 have a volume level different from that of the first operation sound A41. included.

(Step S34: Match the volume levels of the first operation sound A41 and the second operation sound A42)
Next, the computing unit 34 matches the volume levels of the first operation sound A41 received in step S32 and the second operation sound A42 received in step S33. The volume level α of the first operation sound A41 received by the first sound detection unit 41 and the volume level β of the second operation sound A42 received by the second sound detection unit 42 are expressed by the following equations. be able to.
α = x + m (y + z) (1)
β = n (y + z) (2)

  In Expressions (1) and (2), x is the volume of the generated sound X of the cooling unit 28, y is the volume of the operating sound Y of the AC / DC converter 21 and the DC / AC converter 23, and z is the reference sound generator 7. The volume of the generated reference sound Z, and m and n are arbitrary counts. The calculation unit 34 adjusts the volume level α of the first operation sound A41 or the volume level β of the second operation sound A42 so that the volume z of the reference sound Z becomes equal, and the first operation sound A41 and The volume level of the second operation sound A42 is adjusted.

  As an example, in the present embodiment, as the adjustment of the volume level α of the first operation sound A41 and the volume level β of the second operation sound A42, β in Expression (2) is multiplied by m / n (m / n). It is assumed that β is created and the volume levels of the first operation sound A41 and the second operation sound A42 are matched.

(Step S35: Extract the sound generated by the cooling unit 28)
Next, the computing unit 34 extracts the sound X generated by the cooling unit 28 and creates signal data B. Extraction of the sound X generated by the cooling unit 28 is performed using the first operation sound A41 and the second operation sound A42 whose volume levels are adjusted in step S34.

As an example, in this embodiment, as shown in Expression (3), (m / n) β whose volume level is adjusted in step S34 is subtracted from α to extract the generated sound X of the cooling unit 28. To do.
α- (m / n) β
= X + m (y + z)-(m / n) .n (y + z) = x (3)
Thereby, the generated sound X of the cooling unit 28 can be extracted. The calculation unit 34 extracts the sound X generated by the cooling unit 28 and creates signal data B (signal data related to the sound generated by the cooling unit 28).

  In the above, the volume level α of the first operation sound A41 and the volume level β of the second operation sound A42 received by the second sound detection unit 42 are adjusted, and the generated sound X of the cooling unit 28 is extracted. However, the specific frequency applied to the first operation sound A41 and the second operation sound A42 may be extracted, the power of the specific frequency may be adjusted, and the generated sound X of the cooling unit 28 may be extracted. .

(Step S36: The reference sound generator 7 stops the generation of the reference sound)
Next, the computing unit 34 controls the reference sound generating unit 7 via the output unit 32 and causes the reference sound generating unit 7 to stop generating the reference sound.

(Step S37: Transmit signal data B)
Next, the calculation unit 34 transmits the signal data B (signal data relating to the sound generated by the cooling unit 28) created in step S35 to the determination unit 5 via the transmission unit 33.

  The above is the operation of the calculation unit 34 of the control unit 3. The volume of the reference sound Z generated by the reference sound generator 7 included in the second operation sound A42 detected by the second sound detector 42 as described above, and the first sound detector 41 The volume level of the first operation sound A41 or the second operation sound A42 so that the volume of the reference sound Z generated by the reference sound generator 7 included in the detected first operation sound A41 matches. Is adjusted, signal data B (signal data relating to the sound generated by the cooling unit 28) is created.

[4-3. effect]
(1) According to this embodiment, the control unit 3 is generated by the reference sound generation unit 7 included in the second operation sound A42 detected by the second sound detection unit 42 as described above. The volume of the reference sound Z and the volume of the reference sound Z generated by the reference sound generator 7 included in the first operation sound A41 detected by the first sound detector 41 are matched with each other. The volume level of the first operation sound A41 or the second operation sound A42 is adjusted, the difference between the first operation sound A41 and the second operation sound A42 is calculated, and the sound generated by the cooling unit 28 is extracted. It is possible to provide the uninterruptible power supply system 1 that can accurately extract the sound generated by the unit 28 and detect the deterioration of the cooling unit at an early stage.

  The first operation sound A41 detected by the first sound detection unit 41 includes the sound X generated by the cooling unit 28, the operation sound Y of the AC / DC conversion unit 21, and the DC / AC conversion unit 23. Therefore, in order to detect the sound X generated by the cooling unit 28, it is desirable to accurately remove the operation sound Y from the first operation sound A41.

  According to the present embodiment, the reference sound Z generated by the reference sound generator 7 is included in the first operation sound A41 detected by the first sound detector 41. Further, in the first operation sound A41 detected by the first sound detection unit 41 and the second operation sound A42 detected by the second sound detection unit 42, the reference sound Z, the AC / DC conversion unit 21, and the DC The volume ratio with the operation sound Y of the AC converter 23 is the same.

  Therefore, the volume level of the first operation sound A41 or the second operation sound A42 is adjusted so that the volume of the reference sound Z included in the first operation sound A41 and the second operation sound A42 matches, and the difference is obtained. By calculating, the generated sound X of the cooling unit 28 can be extracted with high accuracy.

(2) According to the present embodiment, since the reference sound Z generated by the reference sound generator 7 has a frequency outside the audible range, it reduces the discomfort caused by the reference sound Z to surrounding people. be able to.

[4-4. Modified example]
(1) In the above-described embodiment, the detection unit 4 includes the two sound detection units, the first sound detection unit 41 and the second sound detection unit 42. The number is not limited to this. For example, the number of sound detection units included in the detection unit 4 may be three or more. The sound detection unit may be arranged in the vicinity of the cooling unit 28, the AC / DC conversion unit 21, and the DC / AC conversion unit 23.

(2) In the above embodiment, the reference sound generator 7 is arranged in the vicinity of the AC / DC converter 21 or the DC / AC converter 23. However, the plurality of reference sounds 7 are connected to the AC / DC converter. 21 may be arranged in the vicinity of the DC / AC converter 23. Further, the plurality of reference sound generators 7 may generate reference sounds having different frequencies.

(3) In the above embodiment, the reference sound is stopped in step S36. However, the reference sound may be constantly generated by the reference sound generator 7.

[5. Other Embodiments]
Although the 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 forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. These embodiments and modifications thereof are included in the invention described in the claims and equivalents thereof as well as included in the scope and gist of the invention. The following is an example.

(1) In the above embodiment, the uninterruptible power supply 2 has the power supply unit 20, the control unit 3, and the detection unit 4. However, the configuration of the uninterruptible power supply 2 is not limited to this. The uninterruptible power supply 2 may include a determination unit 5 in addition to the power supply unit 20, the control unit 3, and the detection unit 4. The uninterruptible power supply 2 may include a power supply unit 20 and a detection unit 4, and the control unit 3 and the determination unit 5 may be configured by devices outside the uninterruptible power supply 2.

(2) In the above embodiment, the AC / DC converter 21 is configured by a converter that converts AC power into DC power, but the configuration of the AC / DC converter 21 is not limited thereto. The AC / DC converter 21 may be configured by a bidirectional inverter / converter that converts AC power into DC power and DC power into AC power. When the AC / DC converter 21 operates as an inverter, the DC power discharged from the storage battery 22 may be converted into AC power and output to the power supply line 91 via the input terminal 25. By comprising in this way, the electric power of the storage battery 22 is utilized for energy saving.

(3) In the above embodiment, the cooling unit 28 is configured by a cooling fan driven by an electric motor, but the configuration of the cooling unit 28 is not limited thereto. The cooling unit 28 may be configured by a compressor.

(4) In the above embodiment, the alarm output from the alarm output unit 54 is output by an alarm sound and an alarm display. However, the alarm output from the alarm output unit 54 is not limited to this. The alarm output from the alarm output unit 54 may be output by, for example, a wired or wireless communication message.

(5) In the above embodiment, the signal data A is always generated and output by the detection unit 4, but may be generated by an instruction from the calculation unit 34.

(6) In the above-described embodiment, the reference data E (data used as a reference for determining the deterioration of the cooling unit 28) is signal data related to the sound generated by the cooling unit 28 in a state where there is no deterioration. E is not limited to this. The reference data E may be signal data relating to the sound generated by the cooling unit 28 indicating the state of deterioration over time. The calculation unit 56 compares the reference data E, which is signal data relating to the sound generated by the cooling unit 28, indicating the state of deterioration over time, and the signal data B (signal data relating to the sound generated by the cooling unit 28). The state of deterioration of the cooling unit 28 and / or the remaining life may be estimated.

DESCRIPTION OF SYMBOLS 1 ... Uninterruptible power supply system 2, 2a, 2b ... Uninterruptible power supply 3 ... Control part 4 ... Detection part 5 ... Judgment part 6 ... Temperature measurement part 7 ... Reference | standard Sound generator 8 ... load 9 ... power system 20 ... power source 21 ... AC / DC converter 22 ... storage battery 23 ... DC / AC converter 24 ... bypass circuit,
25 ... input terminal 26 ... auxiliary input terminal 27 ... output terminal 28 ... cooling unit 31 ... input unit 32 ... output unit 33 ... transmitting unit 34 ... calculating unit 35 ... Transmission / reception unit 41 ... First sound detection unit 42 ... Second sound detection unit 51 ... Reception unit 52 ... Storage unit 53 ... Display unit 54 ... Alarm output unit 55 ... Transmission / reception part 56 ... Calculation part 91 ... Power supply line 92 ... Commercial power supply

Claims (33)

An AC / DC converter that converts the supplied AC power into an AC / DC converter;
A storage battery that charges the DC power supplied from the AC / DC converter and discharges the DC power;
DC / AC conversion of DC power discharged from the storage battery, and DC / AC conversion unit that outputs AC power;
A cooling unit that cools at least one of the AC to DC conversion unit and the DC to AC conversion unit;
A power supply unit having
A detection unit for detecting an operation sound of the power supply unit;
A control unit for controlling the timing at which the detection unit detects an operation sound, and for extracting the generated sound of the cooling unit;
A determination unit that determines deterioration of the cooling unit based on the generated sound of the cooling unit extracted by the control unit;
An uninterruptible power supply system. The control unit controls the AC / DC conversion unit and the DC / AC conversion unit to operate at a predetermined frequency, and the AC / DC conversion unit and the DC / AC conversion unit operate at a predetermined frequency. Controlling the detection unit to detect an operation sound of the power supply unit;
From the operation sound detected by the detection unit, the sound of the frequency component of the AC / DC conversion unit and the DC / AC conversion unit is removed, and the generated sound of the cooling unit is extracted.
The uninterruptible power supply system according to claim 1. The control unit controls the cooling unit to operate at a predetermined frequency, and controls the detection unit to detect an operation sound of the power supply unit at a timing when the cooling unit operates at a predetermined frequency. And
From the operation sound detected by the detection unit, the sound of the frequency component of the AC / DC conversion unit and the DC / AC conversion unit is removed, and the generated sound of the cooling unit is extracted.
The uninterruptible power supply system according to claim 1 or 2. The controller is
Controlling the detection unit to detect a first operation sound of the power supply unit at a timing when the cooling unit is operating;
When the temperature of the power supply unit becomes a predetermined temperature or less, the cooling unit is controlled to stop the operation, and the second operation sound of the power supply unit is detected at the timing when the cooling unit is stopped. Controlling the detection unit to
Subtracting the second operation sound from the first operation sound detected by the detection unit, to extract the generated sound of the cooling unit,
The uninterruptible power supply system according to claim 1. The controller is
When the cooling unit is operated and the temperature of the power supply unit becomes a predetermined temperature or less, the cooling unit is controlled to stop the operation of the cooling unit, and the cooling unit is stopped at the timing when the cooling unit is stopped. Controlling the detection unit to detect a second operation sound of the power supply unit;
The uninterruptible power supply system according to claim 4. The controller is
The AC / DC converter and the DC / AC converter are controlled to stop the operation, the AC / DC converter and the DC / AC converter are stopped, and the cooling unit is operating at the timing. Controlling the detection unit to detect the operation sound of the power supply unit, and extracting the generated sound of the cooling unit;
The uninterruptible power supply system according to claim 1. The controller is
When performing control to stop the operation of the AC / DC conversion unit and the DC / AC conversion unit, control to operate a second power supply unit provided outside the power supply unit,
The uninterruptible power supply system according to claim 6. A reference sound generator that generates a reference sound at a predetermined volume and frequency, disposed near the AC / DC converter or the DC / AC converter;
The detection unit is disposed in the vicinity of the cooling unit, and is disposed in the vicinity of a first sound detection unit that detects a first operation sound, the AC / DC conversion unit or the DC / AC conversion unit, and a second A second sound detection unit for detecting an operation sound,
The controller is
The volume of the reference sound generated by the reference sound generator included in the second operation sound detected by the second sound detector, and the first sound detected by the first sound detector. Adjusting the volume level of the first operation sound or the second operation sound so that the volume of the reference sound generated by the reference sound generation unit included in one operation sound matches,
Calculating a difference between the second operation sound from the first operation sound and extracting a sound generated by the cooling unit;
The uninterruptible power supply system according to claim 1. The reference sound generated by the reference sound generator has a frequency outside the audible range,
The uninterruptible power supply system according to claim 8. The cooling unit includes at least one of a cooling fan and a compressor.
The uninterruptible power supply system according to any one of claims 1 to 9. The control unit periodically performs an operation of extracting sound generated by the cooling unit.
The uninterruptible power supply system according to any one of claims 1 to 10. The determination unit outputs an alarm by at least one of display, sound, and transmission when the generated sound of the cooling unit is equal to or higher than a predetermined volume.
The uninterruptible power supply system according to any one of claims 1 to 11. An AC / DC converter that converts the supplied AC power into an AC / DC converter;
A storage battery that charges the DC power supplied from the AC / DC converter and discharges the DC power;
DC / AC conversion of DC power discharged from the storage battery, and DC / AC conversion unit that outputs AC power;
A cooling unit that cools at least one of the AC to DC conversion unit and the DC to AC conversion unit;
A power supply unit having
A detection unit for detecting an operation sound of the power supply unit;
A control unit for controlling the timing at which the detection unit detects an operation sound, and for extracting the generated sound of the cooling unit;
An uninterruptible power supply. The control unit controls the AC / DC conversion unit and the DC / AC conversion unit to operate at a predetermined frequency, and the AC / DC conversion unit and the DC / AC conversion unit operate at a predetermined frequency. Controlling the detection unit to detect an operation sound of the power supply unit;
From the operation sound detected by the detection unit, the sound of the frequency component of the AC / DC conversion unit and the DC / AC conversion unit is removed, and the generated sound of the cooling unit is extracted.
The uninterruptible power supply according to claim 13. The control unit controls the cooling unit to operate at a predetermined frequency, and controls the detection unit to detect an operation sound of the power supply unit at a timing when the cooling unit operates at a predetermined frequency. And
From the operation sound detected by the detection unit, the sound of the frequency component of the AC / DC conversion unit and the DC / AC conversion unit is removed, and the generated sound of the cooling unit is extracted.
The uninterruptible power supply according to claim 13 or 14. The controller is
Controlling the detection unit to detect a first operation sound of the power supply unit at a timing when the cooling unit is operating;
When the temperature of the power supply unit becomes a predetermined temperature or less, the cooling unit is controlled to stop the operation, and the second operation sound of the power supply unit is detected at the timing when the cooling unit is stopped. Controlling the detection unit to
Subtracting the second operation sound from the first operation sound detected by the detection unit, to extract the generated sound of the cooling unit,
The uninterruptible power supply according to claim 13. The controller is
When the cooling unit is operated and the temperature of the power supply unit becomes a predetermined temperature or less, the cooling unit is controlled to stop the operation of the cooling unit, and the cooling unit is stopped at the timing when the cooling unit is stopped. Controlling the detection unit to detect a second operation sound of the power supply unit;
The uninterruptible power supply according to claim 16. The controller is
The AC / DC converter and the DC / AC converter are controlled to stop the operation, the AC / DC converter and the DC / AC converter are stopped, and the cooling unit is operating at the timing. Controlling the detection unit to detect the operation sound of the power supply unit, and extracting the generated sound of the cooling unit;
The uninterruptible power supply according to claim 13. The controller is
When performing control to stop the operation of the AC / DC converter and the DC / AC converter, a control signal for operating a second power source provided outside the power source is transmitted.
The uninterruptible power supply according to claim 18. A reference sound generator that generates a reference sound at a predetermined volume and frequency, disposed near the AC / DC converter or the DC / AC converter;
The detection unit is disposed in the vicinity of the cooling unit, and is disposed in the vicinity of a first sound detection unit that detects a first operation sound, the AC / DC conversion unit or the DC / AC conversion unit, and a second A second sound detection unit for detecting an operation sound,
The controller is
The volume of the reference sound generated by the reference sound generator included in the second operation sound detected by the second sound detector, and the first sound detected by the first sound detector. Adjusting the volume level of the first operation sound or the second operation sound so that the volume of the reference sound generated by the reference sound generation unit included in one operation sound matches,
Calculating a difference between the second operation sound from the first operation sound and extracting a sound generated by the cooling unit;
The uninterruptible power supply according to claim 13. The reference sound generated by the reference sound generator has a frequency outside the audible range,
The uninterruptible power supply according to claim 20. An AC / DC converter that converts the supplied AC power into an AC / DC converter;
A storage battery that charges the DC power supplied from the AC / DC converter and discharges the DC power;
DC / AC conversion of DC power discharged from the storage battery, and DC / AC conversion unit that outputs AC power;
A cooling unit that cools at least one of the AC to DC conversion unit and the DC to AC conversion unit;
A power supply unit having
An uninterruptible power supply control program for controlling an uninterruptible power supply having a detection unit for detecting operation sound of the power supply unit,
Controlling the AC / DC converter and the DC / AC converter to operate at a predetermined frequency;
Controlling the detection unit to detect an operation sound of the power supply unit at a timing when the AC / DC conversion unit and the DC / AC conversion unit are operating at a predetermined frequency;
Removing the sound of the frequency components of the AC / DC converter and the DC / AC converter from the operation sound detected by the detector, and extracting the generated sound of the cooling unit;
An uninterruptible power supply control program. Controlling the cooling unit to operate at a predetermined frequency at a timing at which the AC / DC conversion unit and the DC / AC conversion unit are operating at a predetermined frequency; and
The program for controlling an uninterruptible power supply according to claim 22. An AC / DC converter that converts the supplied AC power into an AC / DC converter;
A storage battery that charges the DC power supplied from the AC / DC converter and discharges the DC power;
DC / AC conversion of DC power discharged from the storage battery, and DC / AC conversion unit that outputs AC power;
A cooling unit that cools at least one of the AC to DC conversion unit and the DC to AC conversion unit;
A power supply unit having
An uninterruptible power supply control program for controlling an uninterruptible power supply having a detection unit for detecting operation sound of the power supply unit,
Controlling the detection unit to detect a first operating sound of the power supply unit at a timing when the cooling unit is operating;
When the temperature of the power supply unit becomes a predetermined temperature or less, the cooling unit is controlled to stop the operation, and the second operation sound of the power supply unit is detected at the timing when the cooling unit is stopped. Controlling the detection unit to:
Subtracting the second operation sound from the first operation sound detected by the detection unit, and extracting the generated sound of the cooling unit;
An uninterruptible power supply control program. Controlling the cooling unit to stop the operation when the cooling unit is operated and the temperature of the power supply unit is equal to or lower than a predetermined temperature;
The uninterruptible power supply control program according to claim 24. An AC / DC converter that converts the supplied AC power into an AC / DC converter;
A storage battery that charges the DC power supplied from the AC / DC converter and discharges the DC power;
DC / AC conversion of DC power discharged from the storage battery, and DC / AC conversion unit that outputs AC power;
A cooling unit that cools at least one of the AC to DC conversion unit and the DC to AC conversion unit;
A power supply unit having
An uninterruptible power supply control program for controlling an uninterruptible power supply having a detection unit for detecting operation sound of the power supply unit,
Controlling the AC to DC converter and the DC to AC converter to stop operation;
Controlling the detection unit to detect an operation sound of the power supply unit at a timing when the AC / DC conversion unit and the DC / AC conversion unit are stopped and the cooling unit is operating;
An uninterruptible power supply control program. Before executing the step of controlling the AC / DC converter and the DC / AC converter so as to stop the operation, performing a control of operating a second power source provided outside the power source. Have
The uninterruptible power supply control program according to claim 26. An AC / DC converter that converts the supplied AC power into an AC / DC converter;
A storage battery that charges the DC power supplied from the AC / DC converter and discharges the DC power;
DC / AC conversion of DC power discharged from the storage battery, and DC / AC conversion unit that outputs AC power;
A cooling unit that cools at least one of the AC to DC conversion unit and the DC to AC conversion unit;
A power supply unit having
An uninterruptible power supply control method for controlling an uninterruptible power supply having a detection unit for detecting an operation sound of the power supply unit,
A procedure for controlling the AC / DC converter and the DC / AC converter to operate at a predetermined frequency;
A procedure for controlling the detection unit to detect an operation sound of the power supply unit at a timing at which the AC / DC conversion unit and the DC / AC conversion unit are operating at a predetermined frequency;
From the operation sound detected by the detection unit, removing the sound of the frequency components of the AC / DC conversion unit and the DC / AC conversion unit, and extracting the generated sound of the cooling unit,
An uninterruptible power supply control method. A procedure for controlling the cooling unit to operate at a predetermined frequency at a timing at which the AC / DC conversion unit and the DC / AC conversion unit operate at a predetermined frequency;
The uninterruptible power supply control method according to claim 28. An AC / DC converter that converts the supplied AC power into an AC / DC converter;
A storage battery that charges the DC power supplied from the AC / DC converter and discharges the DC power;
DC / AC conversion of DC power discharged from the storage battery, and DC / AC conversion unit that outputs AC power;
A cooling unit that cools at least one of the AC to DC conversion unit and the DC to AC conversion unit;
A power supply unit having
An uninterruptible power supply control method for controlling an uninterruptible power supply having a detection unit for detecting an operation sound of the power supply unit,
A procedure for controlling the detection unit to detect a first operation sound of the power supply unit at a timing when the cooling unit is operating;
When the temperature of the power supply unit becomes a predetermined temperature or less, the cooling unit is controlled to stop the operation, and the second operation sound of the power supply unit is detected at the timing when the cooling unit is stopped. A procedure for controlling the detection unit to:
Subtracting the second operation sound from the first operation sound detected by the detection unit, and extracting the generated sound of the cooling unit;
An uninterruptible power supply control method. When the cooling unit is operated and the temperature of the power supply unit becomes a predetermined temperature or less, the cooling unit is controlled to stop the operation.
The uninterruptible power supply control method according to claim 30. An AC / DC converter that converts the supplied AC power into an AC / DC converter;
A storage battery that charges the DC power supplied from the AC / DC converter and discharges the DC power;
DC / AC conversion of DC power discharged from the storage battery, and DC / AC conversion unit that outputs AC power;
A cooling unit that cools at least one of the AC to DC conversion unit and the DC to AC conversion unit;
A power supply unit having
An uninterruptible power supply control method for controlling an uninterruptible power supply having a detection unit for detecting an operation sound of the power supply unit,
A procedure for controlling the AC / DC converter and the DC / AC converter so as to stop operation;
A procedure for controlling the detection unit to detect an operation sound of the power supply unit at a timing when the AC / DC conversion unit and the DC / AC conversion unit are stopped and the cooling unit is operating;
An uninterruptible power supply control method. Before executing the procedure for controlling the AC / DC converter and the DC / AC converter so as to stop the operation, a procedure for performing a control to operate the second power supply provided outside the power supply Have
The uninterruptible power supply control method according to claim 32.

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