JP2023176433A - Available discharge time display device for uninterruptible power supply - Google Patents

Abstract

To provide an available discharge time display device for an uninterruptible power supply which can accurately estimate a time of available discharge by the uninterruptible power supply and indicate it to a user.SOLUTION: An available discharge time display device for an uninterruptible power supply according to an embodiment is a display device configured to be capable of displaying an available discharge time with the uninterruptible power supply, and includes: an estimation unit that estimates the available discharge time during operation under a predetermined load, and a display unit that displays the available discharge time during operation under the predetermined load estimated by the estimation unit.SELECTED DRAWING: Figure 9

Description

Embodiments of the present invention relate to a dischargeable time display device for an uninterruptible power supply that is configured to be able to display the dischargeable time by the uninterruptible power supply.

For example, Patent Document 1 describes a computer that detects the usage status of a storage battery in an uninterruptible power supply, sets this as a status flag, and recognizes this using a computer, thereby displaying desired guidance on a display monitor of a workstation. system is disclosed.

Japanese Patent Application Publication No. 7-28567

However, with conventional technology, although it is possible to check the usage status of storage batteries in an uninterruptible power supply, that is, how many storage batteries are being used and at what load, It is not possible to accurately confirm the possible discharge time. Therefore, the user does not know how long the uninterruptible power supply can discharge, and cannot operate the equipment with peace of mind.

Therefore, the present invention provides a display device for displaying the available discharge time of an uninterruptible power supply, which is capable of accurately estimating the available discharge time of the uninterruptible power supply and notifying the user.

The dischargeable time display device of the uninterruptible power supply according to the present embodiment is a display device configured to be able to display the dischargeable time by the uninterruptible power supply, the display device configured to display the dischargeable time when the uninterruptible power supply is operated at a predetermined load. and a display section that displays the possible discharge time during operation under a predetermined load estimated by the estimation section.

A block diagram schematically showing a configuration example of a remote monitoring system according to the present embodiment A diagram schematically showing a configuration example of a status data display screen according to the present embodiment A diagram schematically showing a configuration example of a waveform data display screen according to the present embodiment A diagram schematically showing a configuration example of a daily report data display screen according to the present embodiment A diagram schematically showing a configuration example of a trend data display screen according to the present embodiment A diagram schematically showing a configuration example of a history list display screen according to the present embodiment A front view schematically showing a configuration example of an operation panel included in a storage battery monitoring panel according to the present embodiment A block diagram schematically showing a configuration example of a control board included in the uninterruptible power supply according to the present embodiment A front view of the operation panel schematically showing a display example during normal operation according to the present embodiment A front view of the operation panel schematically showing a display example during operation of the storage battery according to the present embodiment A front view of the operation panel schematically showing a display example during charging according to the present embodiment A front view of the operation panel schematically showing a display example during degenerate operation according to the present embodiment A front view of the operation panel schematically showing a display example when the storage battery according to the present embodiment deteriorates. A front view of the operation panel schematically showing a display example during simulation of the dischargeable time according to the present embodiment

Hereinafter, one embodiment of an "uninterruptible power supply and storage battery remote monitoring system" and "uninterruptible power supply dischargeable time display device" will be described with reference to the drawings. The remote monitoring system 100 illustrated in FIG. 1 includes an uninterruptible power supply 200, a power storage device 300, a base station device 400, and the like.

The uninterruptible power supply 200 includes an AC input section 201 and a DC input section 202. The AC input unit 201 is connected to a commercial power source (not shown) and is configured to be able to input AC power to the uninterruptible power supply 200. On the other hand, the DC input unit 202 is connected to the power storage device 300 and is configured to be able to input DC power to the uninterruptible power supply 200 .

Further, the uninterruptible power supply 200 includes a recording board 203. Various types of information can be recorded on the recording substrate 203. The information recorded on the recording board 203 includes uninterruptible power supply status information indicating various states of the uninterruptible power supply 200.

Further, a peripheral panel 500 is connected to the uninterruptible power supply 200. The peripheral board 500 includes a router device 501 and a hub device 502. The router device 501 and the hub device 502 are configured to be supplied with power from the output side of the uninterruptible power supply 200.

To explain in more detail, the uninterruptible power supply 200 is supplied with power from both the AC input section 201 and the DC input section 202, and is configured to be able to output power at all times. An outlet 504 is connected to the output of the uninterruptible power supply 200 via a transformer 503. Power is supplied to the router device 501 and the hub device 502 by connecting an AC adapter 505 to this outlet 504.

According to such a connection configuration, power is supplied to the router device 501 and the hub device 502 from the uninterruptible power supply 200 even if the power supply is stopped due to a power outage, for example. Therefore, the router device 501 and the hub device 502 can operate by being supplied with power from the uninterruptible power supply 200 even during a power outage, for example.

Further, the peripheral board 500 includes a gateway board 506. The gateway board 506 is also configured to be able to be supplied with power from the uninterruptible power supply 200. That is, the gateway board 506 is configured to be supplied with power via the stabilized power supply 507 connected to the output of the uninterruptible power supply 200. The hub device 502 is configured to be able to collect various types of information recorded on the recording board 203 of the uninterruptible power supply 200 via the gateway board 506.

Further, the uninterruptible power supply 200 includes a control board 204. The control board 204 can control the operations of the router device 501, hub device 502, gateway board 506 of the peripheral board 500, and further the recording board 203 of the uninterruptible power supply 200. Note that the control board 204 may also be able to control the supply of power to the router device 501, hub device 502, and gateway board 506 of the peripheral board 500, and may also be able to control the supply of power to the recording board 203 of the uninterruptible power supply 200. It may also be possible to control the supply of power. Further, the control board 204 may be able to control the overall operation of the uninterruptible power supply 200 and the peripheral panel 500.

The power storage device 300 includes a plurality of storage batteries 301 configured of, for example, lithium ion storage batteries. The storage batteries 301 are each connected to the DC input section 202 of the uninterruptible power supply 200 and are configured to be able to supply DC power to the uninterruptible power supply 200. Further, a monitoring panel 600 is connected to the power storage device 300. The monitoring board 600 includes a recording board 601. Various types of information can be recorded on the recording substrate 601. The information recorded on the recording board 601 includes storage battery status information indicating various states of the storage battery 301 and the like.

The monitoring panel 600 also includes a gateway board 602. The hub device 502 provided in the peripheral board 500 can collect various types of information recorded on the recording board 601 via this gateway board 602.

The monitoring board 600 also includes a control board 603. The control board 603 can control the operations of the recording board 601 and the gateway board 602. Note that the control board 603 may be able to control the supply of power to the recording board 601 and the gateway board 602. Further, control board 603 may be able to control the overall operation of power storage device 300.

As described above, the hub device 502 is configured to be able to collect various types of information recorded on the recording board 203 of the uninterruptible power supply 200 and various types of information recorded on the recording board 601 of the power storage device 300. . That is, the hub device 502 serves as an information aggregation unit that aggregates the uninterruptible power supply status information recorded on the recording board 203 of the uninterruptible power supply 200 and the storage battery status information recorded on the recording board 601 of the power storage device 300. Function. The hub device 502 is configured to be able to transmit the aggregated information to the base station device 400 via the router device 501. Note that in FIG. 1, the information transmission path is indicated by a broken line arrow.

According to the remote monitoring system 100 illustrated above, the hub device 502 is provided not in the power storage device 300 or the monitoring panel 600, but in the peripheral panel 500 provided in the uninterruptible power supply 200. That is, the hub device 502 is provided as a component on the uninterruptible power supply 200 side, not as a component on the power storage device 300 side. Note that the hub device 502 may be provided as a component on the power storage device 300 side, for example.

The base station device 400 includes an operation input section 401 and a display output section 402. The operation input unit 401 is configured by an operation input device such as a keyboard and a mouse. A user can input various types of information to the base station device 400 via the operation input section 401. The display output unit 402 is configured by a display output device such as a liquid crystal display. The display output unit 402 can display various types of information.

The display output unit 402 provided in the base station device 400 is a system-side display provided in the base station device 400 that is the main body of monitoring operation in the remote monitoring system 100, not in the uninterruptible power supply 200 or the storage battery 301 that are to be monitored. This is an example of a display section or a display section on the monitoring subject side. The display output unit 402 can display the status of the uninterruptible power supply 200 and the status of the storage battery 301 that are to be monitored in correspondence with each other based on various information received from the hub device 502 via the router device 501. It is configured.

That is, the base station device 400 is configured to be able to display the status data display screen G1 illustrated in FIG. 2 on the display output unit 402. According to the state data display screen G1, a state in which a plurality of storage batteries 301 are connected to one uninterruptible power supply 200 via a circuit breaker 301a is schematically shown. Further, according to the status data display screen G1, the operating status of the plurality of storage batteries 301 is indicated by, for example, different display colors.

That is, according to the status data display screen G1, the uninterruptible power supply 200 and the storage battery 301 in the on state are shown in red, for example, and the storage battery 301 in the off state is shown in green, for example. The uninterruptible power supply 200 can discharge from the storage battery 301 that is in the on state, but cannot discharge from the storage battery 301 that is in the off state. According to such a status data display screen G1, the status of the uninterruptible power supply 200 and the status of the plurality of storage batteries 301 can be correlated with each other and displayed simultaneously on the same screen G1 in real time. In addition, in FIG. 2, the storage battery 301 in the off state is shown with hatching.

Furthermore, the base station device 400 can display the dischargeable time by the uninterruptible power supply 200 in the status data display screen G1. That is, the base station device 400 is an example of a display device configured to be able to display the dischargeable time by the uninterruptible power supply 200. Furthermore, the base station device 400 can display the voltage state of the storage battery 301, the current state of the storage battery 301, and the temperature state of the storage battery 301 as the state of the storage battery 301 in the state data display screen G1. Note that the base station device 400 displays at least one of the voltage state of the storage battery 301, the current state of the storage battery 301, and the temperature state of the storage battery 301 as the state of the storage battery 301 in the state data display screen G1. It is good if it can be displayed.

Furthermore, the base station device 400 can display the maximum value and minimum value of the values indicating the state of the storage battery 301 in the state data display screen G1. In this case, the base station device 400 displays the maximum value and minimum value indicating the voltage state of the storage battery 301 in the state data display screen G1. Furthermore, the base station device 400 displays the maximum value and minimum value indicating the temperature state of the storage battery 301 in the state data display screen G1. Furthermore, the base station device 400 displays an average value indicating the temperature state of the storage battery 301 in the state data display screen G1.

Further, the base station device 400 is configured to be able to display a waveform data display screen G2 illustrated in FIG. 3 on the display output unit 402 based on various information received from the hub device 502. According to the waveform data display screen G2, various values indicating the state of the storage battery 301, in this case, the voltage state of the storage battery 301, the current state of the storage battery 301, and the temperature state of the storage battery 301, are displayed as waveform data.

Note that the voltage state of the storage battery 301 can be measured by, for example, a voltage sensor (not shown) provided in the storage battery 301. Further, the current state of the storage battery 301 can be measured by, for example, a current sensor (not shown) provided in the storage battery 301. Further, the temperature state of the storage battery 301 can be measured, for example, by a temperature sensor (not shown) provided in the storage battery 301.

Furthermore, the base station device 400 is configured to be able to display a daily report data display screen G3 illustrated in FIG. 4 on the display output unit 402 based on various information received from the hub device 502. According to the daily report data display screen G3, various values indicating the state of the uninterruptible power supply 200 and various values indicating the state of the storage battery 301 are displayed in chronological order. Furthermore, according to the daily report data display screen G3, values indicating the status of the uninterruptible power supply 200 and values indicating the status of the storage battery 301 within a predetermined period, in this case, one day or 24 hours are displayed in chronological order. Ru.

Furthermore, the base station device 400 is configured to be able to display a trend data display screen G4 illustrated in FIG. 5 on the display output unit 402 based on various information received from the hub device 502. According to the trend data display screen G4, trends in changes in the values indicating the state of the uninterruptible power supply 200 and the values indicating the state of the storage battery 301 are displayed, for example, as a line graph.

Furthermore, the base station device 400 is configured to be able to display a history list display screen G5 illustrated in FIG. 6 on the display output unit 402 based on various information received from the hub device 502. According to the history list display screen G5, the history of the state of the uninterruptible power supply 200 and the state of the storage battery 301 is displayed in chronological order.

Above, an example of the display mode by the display output unit 402 of the base station device 400, which is an example of the system side display unit or the monitoring subject side display unit, has been described in detail. On the other hand, as illustrated in FIG. 1, the monitoring panel 600 includes an operation panel 700. Next, an example of the display mode on the operation panel 700 of the monitoring panel 600 will be described in detail.

As illustrated in FIG. 7, the operation panel 700 is provided with an operation input section 701 and a display output section 702. The operation input unit 701 includes a start/stop button 701a for starting or stopping operation of the power storage device 300, a record button 701b for checking recorded contents regarding the state of the power storage device 300 and the state of the storage battery 301, and a power storage It includes a measurement button 701c for measuring the state of the device 300 and the state of the storage battery 301, a screen transition button 701d for transitioning the screen displayed on the operation panel 700 to another screen, and the like.

The display output unit 702 is an example of a storage battery side display unit or a monitored target side display unit that is provided not in the uninterruptible power supply 200 or the base station device 400 but in the power storage device 300 side including the storage battery 301. The display output unit 702 is configured with, for example, a liquid crystal display, and is capable of displaying various types of information. Further, the monitoring panel 600 including such a display output unit 702 is an example of a display device configured to be able to display the dischargeable time by the uninterruptible power supply 200. Although not shown, the peripheral panel 500 may also be configured to include an operation panel configured by, for example, a liquid crystal display.

As illustrated in FIG. 8, the control board 204 that can control the overall operation of the uninterruptible power supply 200 virtually implements the estimation processing section 204a using software. Note that the estimation processing unit 204a may be configured by hardware, or may be configured by a combination of software and hardware.

The estimation processing unit 204a is an example of an estimation unit, and is configured to be able to estimate the dischargeable time by the uninterruptible power supply 200 when operating under a predetermined load. Various methods can be applied to estimate the dischargeable time, and for example, it can be calculated by dividing the remaining charge amount of the storage battery 301 by a preset discharge current value or discharge voltage value. The remaining charge of the storage battery 301 can be measured, for example, with an ammeter, a voltmeter, or the like provided in the storage battery 301. In addition, various methods can be applied to the method of estimating the dischargeable time as long as the method can estimate the dischargeable time by the uninterruptible power supply 200.

The control board 204 is configured to be able to display the possible discharge time during operation under a predetermined load estimated by the estimation processing section 204a on the display output section 702 of the operation panel 700. To explain in more detail, the control board 204 transmits information indicating the dischargeable time estimated by the estimation processing unit 204a to the monitoring board 600, for example, by an information transmission module (not shown). Then, the monitoring board 600 receives information indicating the dischargeable time from, for example, an information receiving module (not shown). Then, the monitoring panel 600 displays the available discharge time on the operation panel 700 based on the received information.

For example, FIG. 9 illustrates the display state of the display output unit 702 during normal operation when the uninterruptible power supply 200 is not discharging the storage battery 301. According to FIG. 9, "dischargeable time" is displayed on the display output section 702. In this case, the estimation processing unit 204a estimates the dischargeable time during operation at a rated load, that is, during operation under a load condition in which all the storage batteries 301 of the power storage device 300 are discharged. The display output unit 702 displays the dischargeable time T1 during operation at the rated load estimated by the estimation processing unit 204a.

Further, FIG. 10 illustrates a display state of the display output unit 702 during a storage battery operation in which the uninterruptible power supply 200 is discharging the storage battery 301. According to FIG. 10, the display output unit 702 displays the dischargeable time T1 during operation at the rated load estimated by the estimation processing unit 204a. The display output unit 702 further displays the elapsed time T2 since the uninterruptible power supply 200 started discharging the storage battery 301. Note that the elapsed time T2 after the uninterruptible power supply 200 starts discharging from the storage battery 301 is measured by, for example, a timer circuit (not shown) included in the uninterruptible power supply 200, the peripheral panel 500, or the monitoring panel 600. be able to.

Further, FIG. 11 illustrates a display state of the display output unit 702 during charging when the uninterruptible power supply 200 is charging the storage battery 301. According to FIG. 11, the display output unit 702 displays character information indicating that charging of the storage battery 301 is incomplete until charging of the storage battery 301 is completed, in this case, character information of "charging incomplete". Displaying L1.

In addition, the uninterruptible power supply 200 performs a rated operation in which all the storage batteries 301 connected to the uninterruptible power supply 200 are discharged, and one out of all the storage batteries 301 connected to the uninterruptible power supply 200. The degenerate operation in which discharge is performed only from the storage battery 301 of the section is configured to be possible. That is, if a malfunction such as failure or deterioration occurs in any of the plurality of storage batteries 301 connected to the uninterruptible power supply 200, the uninterruptible power supply 200 stops discharging from the storage battery 301. Instead, it is configured to be able to execute a degenerate operation in which discharge is performed only from the remaining good storage batteries 301 or dischargeable storage batteries 301.

Then, when the uninterruptible power supply 200 is performing a degenerate operation, the display output unit 702 displays a state in which the amount of discharge by the uninterruptible power supply 200 is less than the rated discharge amount, as illustrated in FIG. Text information indicating that the number of vehicles in operation is insufficient, in this case, text information L2 indicating "insufficient number of operating vehicles" is displayed. Note that the number of operating units indicates the number of storage batteries 301 that are discharging among the plurality of storage batteries 301.

Further, as illustrated in FIG. 13, the display output unit 702 is configured to be able to display information L3 indicating that the storage battery 301 has deteriorated. According to FIG. 13, if the storage battery 301 has deteriorated, a check mark is shown in the item "Battery Deterioration". Note that whether or not the storage battery 301 has deteriorated is determined by, for example, a predetermined dischargeable time estimated by the estimation processing unit 204a, that is, a significantly longer dischargeable time than would be expected if the storage battery 301 is in good condition. Based on the fact that the number is low, it can be determined that the storage battery 301 has deteriorated. Furthermore, it can also be determined that the storage battery 301 has deteriorated based on the usage period of the storage battery 301 exceeding a preset recommended usage period or update time. Further, the process of determining whether or not the storage battery 301 has deteriorated can be performed as a software process by the estimation processing unit 204a, for example, or a dedicated processing unit that determines whether or not the storage battery 301 has deteriorated. It is good also as a structure provided with.

Further, according to FIG. 14, the user is configured to be able to input the load factor and the number of operating storage batteries 301 to the display output section 702. That is, the user inputs an arbitrary load factor into the load factor column N1, inputs an arbitrary number of operating machines into the operating number column N2, and operates setting button B to set the load factor and the number of operating machines. I can do it. The estimation processing unit 204a is configured to be able to estimate the dischargeable time according to the load factor set in the display output unit 702 and the number of operating storage batteries 301 set in the display output unit 702. Then, the display output unit 702 displays on the display output unit 702 the possible discharge time estimated by the estimation processing unit 204a, that is, the possible discharge time T3 according to the set load factor and the set number of operating storage batteries 301. configured to be possible.

As described above, in the remote monitoring system 100, the display mode by the display output unit 402, which is an example of the system side display unit or the monitoring subject side display unit, and the display output unit, which is an example of the storage battery side display unit or the monitored target side display unit, are different from each other. The display mode according to 702 is different. Note that various types of information necessary for display on the display output unit 402 are transmitted and received between the devices via, for example, a communication module (not shown). Further, various types of information necessary for display on the display output unit 702 are transmitted and received between the devices via, for example, a communication module (not shown).

According to the embodiment illustrated above, the remote monitoring system 100 remotely monitors the uninterruptible power supply 200 and the storage battery 301 connected to the uninterruptible power supply 200 by the base station device 400. The storage battery 200 and the storage battery 301 are provided with a display output unit 402 that displays the status of the battery 200 and the status of the storage battery 301 in association with each other. According to this configuration example, the uninterruptible power supply 200 and the storage battery 301 can be associated with each other and remotely monitored. Thereby, the states of the uninterruptible power supply 200 and the plurality of storage batteries 301 can be efficiently monitored in groups. Further, the states of the uninterruptible power supply 200 and the plurality of storage batteries 301 can be checked simultaneously in real time on the same screen G1.

Further, according to the present embodiment, the remote monitoring system 100 includes a hub device 502 that aggregates uninterruptible power supply status information indicating the status of the uninterruptible power supply 200 and storage battery status information indicating the status of the storage battery 301. . According to this configuration example, the uninterruptible power supply state information and the storage battery state information can be aggregated by the hub device 502 and sent to the base station device 400 all at once, and the uninterruptible power supply state information and the storage battery state information, which are different pieces of information, respectively Storage battery status information can be sent together and efficiently at the same time. Moreover, compared to a configuration in which the uninterruptible power supply status information and the storage battery status information are transmitted by different means, the number of necessary information transmitting means can be suppressed, and the configuration can be simplified.

Further, according to the present embodiment, the hub device 502 is provided not in the power storage device 300 or the monitoring panel 600 but in the peripheral panel 500 provided in the uninterruptible power supply 200. Here, in the uninterruptible power supply 200, the connected power storage device 300 and the monitoring panel 600 may be replaced. However, assuming a configuration in which the hub device 502 is included in the power storage device 300 and the monitoring panel 600, it is necessary to attach and detach the hub device 502 when replacing the power storage device 300 and the monitoring panel 600, which increases the burden of replacement work. increases. According to this embodiment, since the hub device 502 is provided as a component on the uninterruptible power supply 200 side, even if the power storage device 300 or the monitoring panel 600 is replaced, the hub device 502 cannot be attached or removed. There is no need to perform this process, and it is possible to suppress an increase in the burden of replacement work.

Further, according to the present embodiment, the display output unit 402 can display the dischargeable time by the uninterruptible power supply 200. According to this configuration example, the user can be informed of the discharge possible time by the uninterruptible power supply 200, and the user can continue to operate the equipment with peace of mind. It can be carried out.

Further, according to the present embodiment, the display output unit 402 can display the maximum value and minimum value of the values indicating the state of the storage battery 301. According to this configuration example, it is possible to easily confirm in which state range the storage battery 301 is being operated.

Further, according to the present embodiment, the display output unit 402 displays at least one of the voltage state of the storage battery 301, the current state of the storage battery 301, and the temperature state of the storage battery 301 as the state of the storage battery 301. Can be displayed. According to this configuration example, it is possible to quantitatively confirm in which state the storage battery 301 is being operated based on the displayed state of the voltage, current, or temperature of the storage battery 301.

Further, according to the present embodiment, the display output unit 402 can display the state of the uninterruptible power supply 200 and the state of the storage battery 301 in chronological order. According to this configuration example, it is possible to easily check how the state of the uninterruptible power supply 200 and the state of the storage battery 301 are changing.

Further, according to the present embodiment, the display output unit 402 can display the state of the uninterruptible power supply 200 and the state of the storage battery 301 within a predetermined period. According to this configuration example, changes in the state of uninterruptible power supply 200 and the state of storage battery 301 within a certain specific period can be easily confirmed.

Further, according to the present embodiment, the display mode by the display output unit 402 provided as a component on the side of the base station device 400 that is the monitoring subject, and the display mode provided as a component on the side of the storage battery 301 that is the monitoring target. The display mode by the display output unit 702 is different. According to this configuration example, the display output unit 402 can display the status of the uninterruptible power supply 200 and the storage battery 301 in a manner that is easy for the user operating the base station device 400 to monitor. At 702, the status of the uninterruptible power supply 200 and the storage battery 301 can be displayed in a manner that is easy for the user who operates the uninterruptible power supply 200 and the power storage device 300 to monitor. Thereby, monitoring via each of the devices 200, 300, and 400 can be performed more easily.

Further, according to the present embodiment, the peripheral panel 500 and the monitoring panel 600, which are configured to be able to display the discharge time allowed by the uninterruptible power supply 200, allow the uninterruptible power supply 200 to discharge during operation at a predetermined load. It includes an estimation processing section 204a that estimates time, and a display output section 702 that displays the possible discharge time during operation under a predetermined load estimated by the estimation processing section 204a. According to this configuration example, the possible discharge time of the uninterruptible power supply 200 can be accurately estimated and notified to the user, and the user can continue to operate the equipment with peace of mind. You can take appropriate action with plenty of time.

Further, according to the present embodiment, the states of the uninterruptible power supply 200 and the storage battery 301 can be checked based on the magnitude or change of a simple parameter called "time". Therefore, compared to a monitoring method that shows the states of the uninterruptible power supply 200 and the storage battery 301 in detail, it is possible to reduce the burden of monitoring and the burden of checking the state.

Further, according to the present embodiment, the estimation processing section 204a can estimate the possible discharge time by the uninterruptible power supply 200 during operation at the rated load, and the display output section 702 can estimate the discharge time estimated by the estimation processing section 204a. It is possible to display the possible discharge time when operating at a rated load. According to this configuration example, it is possible to accurately estimate and notify the user of the dischargeable time during rated operation in which all storage batteries 301 connected to the uninterruptible power supply 200 are discharged, and the user can: It is possible to continue operating the equipment with more peace of mind, and it is also possible to take measures against a power outage with more leeway, for example.

Further, according to the present embodiment, the display output unit 702 can further display the elapsed time since the uninterruptible power supply 200 starts discharging. According to this configuration example, it is possible to easily check the progress indicating how far the discharge by the uninterruptible power supply 200 has progressed with respect to the estimated dischargeable time, and the discharge by the uninterruptible power supply 200 remains. This makes it easy to check how much time is available. Thereby, the user can continue operating the equipment with greater peace of mind, and can also take measures against a power outage with more leeway, for example.

Further, according to the present embodiment, the display output unit 702 can display that the charging of the storage battery 301 is incomplete until the charging of the storage battery 301 is completed. According to this configuration example, it is possible to easily confirm that the amount of power stored in the storage battery 301, in other words, the amount of power that can be discharged by the uninterruptible power supply 200 is insufficient.

Further, according to the present embodiment, when the uninterruptible power supply 200 is performing degenerate operation, the display output unit 702 indicates that the amount of discharge by the uninterruptible power supply 200 is less than the rated discharge amount. Can be displayed. According to this configuration example, it is possible to easily confirm that the amount of electric power is insufficient due to discharge by the uninterruptible power supply 200 alone, and it is possible to notify the user that some other measure is required.

Further, according to the present embodiment, the display output unit 702 can display that the storage battery 301 has deteriorated. According to this configuration example, it is possible to notify the user that the storage battery 301 needs to be replaced, and it is possible to avoid operating the uninterruptible power supply 200 without resolving the insufficient amount of discharge. can do.

Further, according to the present embodiment, the estimation processing unit 204a can estimate the dischargeable time according to the set load factor and the set number of operating storage batteries 301. That is, according to the present embodiment, it is possible to simulate the dischargeable time by the uninterruptible power supply 200 based on the load factor set by the user and the number of operating storage batteries 301.

Note that this embodiment is not limited to the one embodiment described above, and can be modified and expanded as appropriate without departing from the gist thereof. For example, the number of storage batteries 301 connected to the uninterruptible power supply 200 can be changed as appropriate. Furthermore, the storage battery 301 is not limited to a lithium ion storage battery, and may be any other storage battery. Further, the contents and layouts of various screens can be changed and implemented as appropriate. Further, the information displayed on various screens may be outputted as audio using, for example, a speaker.

Furthermore, when the storage battery 301 is deteriorated, the estimation processing unit 204a is configured to be able to estimate the dischargeable time in the deteriorated state, and the display output unit 702 is configured to be able to estimate the dischargeable time and the storage battery 301 before deterioration. It may also be configured such that the dischargeable time of the storage battery 301 after deterioration can also be displayed. According to this configuration example, the degree of deterioration of the storage battery 301 can be confirmed by comparing the displayed dischargeable time after deterioration with the dischargeable time before deterioration. Therefore, the user can judge, for example, whether the storage battery 301 needs to be replaced immediately or whether the storage battery 301 can be used for a while.

Although one embodiment of the present invention has been described above, this embodiment is presented merely as an example, and is not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, substitutions, changes, etc. can be made without departing from the gist of the invention. This embodiment and its modifications are included within the scope and gist of the invention, as well as within the scope of the invention described in the claims and its equivalents.

In the drawing, 100 is an uninterruptible power supply and storage battery remote monitoring system, 200 is an uninterruptible power supply, 204a is an estimation processing unit (estimation unit), 301 is a storage battery, 400 is a base station device (display device), and 402 is a display Output section (display section, system side display section, monitoring main side display section), 502 is a hub device (information aggregation section), 600 is a monitoring panel (display device, dischargeable time display device for uninterruptible power supply), 702 is The display output section (display section, storage battery side display section, monitoring target side display section) is shown.

Claims (7)

A display device configured to be able to display a dischargeable time by an uninterruptible power supply,
an estimation unit that estimates the possible discharge time when operating under a predetermined load;
a display unit that displays the possible discharge time during operation at a predetermined load estimated by the estimation unit;
A dischargeable time display device for an uninterruptible power supply equipped with. The estimating unit estimates the possible discharge time during operation at rated load,
2. The available discharge time display device for an uninterruptible power supply according to claim 1, wherein the display section displays the available discharge time during operation at the rated load estimated by the estimation section. The dischargeable time display device for an uninterruptible power supply according to claim 1, wherein the display further displays an elapsed time since the uninterruptible power supply starts discharging. The dischargeable time display device for an uninterruptible power supply according to claim 1, wherein the display unit displays that charging of the storage battery is incomplete until charging of the storage battery is completed. The uninterruptible power supply device is capable of performing a rated operation in which all connected storage batteries are discharged, and a degenerate operation in which some of all connected storage batteries are discharged,
The display unit according to claim 1, wherein the display unit displays that the amount of discharge by the uninterruptible power supply is less than a rated discharge amount when the uninterruptible power supply is performing the degenerate operation. Discharge available time display device for power supply during power outage. The dischargeable time display device for an uninterruptible power supply according to claim 1, wherein the display unit displays that the storage battery has deteriorated. The dischargeable time display device for an uninterruptible power supply according to claim 1, wherein the estimator is capable of estimating the dischargeable time according to a set load factor and a set number of operating storage batteries.

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