JP4277638B2 - Uninterruptible power system - Google Patents

Description

  The present invention relates to an uninterruptible power supply management apparatus and program as a power failure countermeasure for protecting an electronic device during a power failure.

  In general, an uninterrupted power management device (UPS) is connected between an AC power supply and an electronic device (for example, a personal computer). While supplying electric power to the electronic device, the internal battery is charged with electric power from the AC power supply. When the AC power supply is abnormal, the electric power stored in the internal battery is supplied to the electronic device. In this case, when the supply of battery power to the electronic device is stopped as the remaining amount of the internal battery decreases, the operation of the electronic device is stopped prior to that.

By the way, the AC power supply is abnormal in the campus environment where there are many electronic devices in the campus (for example, the entire company, one floor, one room, etc.) and the UPS is associated one-to-one with each electronic device. When the UPS recovers from the normal state, the UPSs start to charge the battery at the same time, and the plurality of electronic devices are put into operation at the same time. As described above, during the initialization process at the time of AC recovery, the power consumption instantaneously becomes extremely high. Therefore, the power consumption may exceed the allowable amount due to the rush current, and the power failure may occur again due to the operation of the breaker.
Therefore, conventionally, for example, as a power failure countermeasure for integrated management of a plurality of electronic devices, a power failure countermeasure system that suppresses the rush current by sequentially delaying the supply of AC power after AC recovery for each electronic device. Is known (see Patent Document 1).
JP-A-4-36135

  However, in this type of power failure countermeasure system, since a plurality of electronic devices are integrated and managed, the number of target devices connected is limited due to hardware restrictions such as the number of switches for power supply switching. However, there remains a problem of lack of flexibility, such as difficulty in dealing with addition and deletion of devices.

It is an object of the present invention to provide a number of new electronic devices to be protected in a premise environment in which each electronic device has a protective measure for preventing a power failure due to a rush current when the commercial power supply recovers normally. Even if it is added, it is possible to prevent the power failure again when the power is restored, including this additional equipment.

The uninterruptible power supply of the present invention is connected between a commercial power source and an electronic device, and when the commercial power source is normal, supplies power from the commercial power source to the electronic device and supplies power from the commercial power source to an internal battery. When the commercial power supply is abnormal, the power stored in the battery is supplied to the electronic device, and when the supply of the battery power is stopped, the uninterruptible power supply stops the operation of the electronic device. A monitoring means for monitoring whether or not the commercial power supply is restored to a normal state when power supply to the electronic device is stopped and its operation is stopped, and other uninterruptible power supply and data When a normal recovery is detected by the determining means for determining the priority order of the start timing of supplying power to the electronic device by performing communication with the other uninterruptible power supply device , It is determined whether or not reached serial start timing, comprising control means for temporarily prohibiting the power supply to the electronic device until the start timing which is set in advance, and said control means, said determination If the priority of the self that is made is higher than the priority of the other uninterruptible power supply, after starting the power supply to the electronic equipment, send a return end notification to the other uninterruptible power supply, If its own priority is lower than the priority of other uninterruptible power supply units, power supply to electronic devices should be temporarily prohibited until a return completion notification is sent from the other uninterruptible power supply units. It is characterized by that.

According to the present invention, it is possible to automatically set the start timing for each uninterruptible power supply and to realize power supply control as set.

(Example 1)
A first embodiment of the present invention will be described below with reference to FIGS.
FIG. 1 is a block diagram showing an overview of the overall configuration of a premises system having an uninterruptible power supply management function in this embodiment.
This premises system has multiple server systems (data processing system with server function: electronic equipment) 1-1, 1-2,... On the premises (for example, the entire company, one floor, one room, etc.) In addition, each electronic device 1-1, 1-2,... Is associated with an uninterruptible power management device (Uninterrupted Power System: UPS) 2-1, 2-2,. The system environment is connected.

A dedicated UPS 2-1 is connected to the electronic device 1-1, and a dedicated UPS 2-2 is connected to the electronic device 1-2. The UPSs 2-1 and 2-2 are independent of each other. The UPS 2-1 acts on the electronic device 1-1, and the UPS 2-2 acts on the electronic device 1-2. In this case, the UPSs 2-1 and 2-2 are connected via the network 3 so as to recognize each other.
The electronic devices 1-1, 1-2,... Are functionally the same, and when there is no need to distinguish them, the electronic devices are collectively referred to as the electronic device 1, Also, the UPSs 2-1, 2-2,... Are functionally identical, and when there is no need to distinguish them, the UPSs are collectively referred to as UPS2.

The UPS 2 is connected between the AC power source 4 and the electronic device 1. When the AC power source 4 is normal, the UPS 2 supplies power from the AC power source 4 to the corresponding electronic device 1, and from the AC power source 4. However, if the AC power supply 4 is abnormal (such as a power failure), the power stored in the battery is supplied to the corresponding electronic device 1. In this case, when the remaining amount of the battery is reduced and the power supply is stopped, a shutdown process for forcibly stopping the operation of the electronic device 1 is performed prior to that.
When the UPS 2 detects an abnormality of the AC power source due to a power failure or the like, the UPS 2 notifies the electronic device 1 of an AC_Fail signal indicating that the AC power source is switched to the battery power, and the remaining battery level is reduced ( When, for example, about 10%), the electronic device 1 is notified of a shutdown / LowBattery signal for instructing the operation stop of the electronic device 1. The data communication between the electronic device 1 and the UPS 2 adopts a smart type of a serial transmission method, and the network 3 connecting each UPS 2 is, for example, LAN, 232C, 422, 12C (SMBus), A serial cable such as Dallas 1-wire is used.

FIG. 2 is a block diagram showing basic components of UPS2.
The CPU 21 is a central processing unit that controls the entire operation of the UPS 2 according to the operating system and various application software in the storage device 22. The storage device 22 has a program storage area 22-1 and a data storage area 22-2, and has a drive system in addition to a magnetic / optical memory, a semiconductor memory, and the like. The program storage area 22-1 in the storage device 22 stores an application program for realizing the present embodiment in accordance with an operation procedure shown in FIGS. 11 and 12, which will be described later, and data in the storage device 22 The storage area 22-2 stores data (priority management information) shown in FIG. Note that the recording device 22 may be a detachable storage medium such as a CD-ROM or DVD in addition to a fixed memory such as a hard disk. Programs and data in the storage device 22 are loaded into a RAM (for example, static RAM) 23 as needed, and data in the RAM 23 is saved in the storage device 22. The RAM 23 has a program execution area 23-1 and a work area 23-2.

Further, the CPU 21 is connected to the network interface 24, the serial interface 25, the battery charge / discharge control unit 26, the AC switching control unit 27, the input device 28, and the display device 29, which are input / output peripheral devices, via a bus line. In accordance with the input / output program, the CPU 21 controls the operation of these input / output devices.
The network interface 24 transmits / receives data for obtaining and determining the status / number of UPSs, priority information, and the like to / from other UPSs 2 connected via the network 3. The serial interface 25 transmits the remaining battery amount and the cause information of the AC failure to the electronic device 1 or receives a shutdown process end notification from the electronic device 1.

  The battery charge / discharge control unit 26 detects the voltage of the internal battery or controls the charge / discharge of the internal battery. When a decrease in the remaining battery level is detected, the battery charge / discharge control unit 26 instructs the electronic device 1 to stop operating. Is transmitted to the electronic device 1. The AC switching control unit 27 monitors the AC power supply and detects an abnormality in the AC power supply. When the AC power supply abnormality occurs, the AC power supply is switched from the AC power supply to the battery, and an AC_Fail signal is transmitted to the electronic device 1. Sometimes, switching from the battery to the AC power source is controlled. The input device 28 is an operation unit that constitutes a pointing device such as a keyboard, a touch panel, a mouse, or a touch input pen, and inputs character string data and various commands. In this embodiment, data such as priority order information is input. Enter.

FIG. 3 shows a power system connection diagram centering on the battery charge / discharge control unit 26 and the AC switching control unit 27.
Here, the battery charge / discharge control unit 26 is connected to the internal battery BT, and the AC switching control unit 27 is connected to the AC input side and the AC output side, and the battery charge / discharge control unit 26 is in accordance with an instruction from the CPU 21. The AC switching control unit 27 controls the supply of power among the AC input side, the AC output side, and the battery BT, as shown in FIGS. In this case, immediately after the power failure is recovered, the CPU 21 suppresses supplying power from the AC power source to the electronic device 1 or gives a suppression instruction for suppressing charging of the battery BT to the battery charge / discharge control unit 26. To the AC switching control unit 27. At this time, both AC power supply suppression (AC output suppression) to the electronic device 1 and AC charge suppression (battery charge suppression) to the battery BT can be instructed at the same time, or either one can be instructed.

  FIG. 4 shows the supply state of power during normal operation. The power from the AC power supply is supplied to the electronic device 1, but in this example, the internal battery BT is in a fully charged (FULL) state. Therefore, power supply to the internal battery BT is not performed. FIG. 5 shows a power supply state at the time of a power failure, and the power from the internal battery BT is switched and supplied to the electronic device 1. Thereby, the electronic device 1 is backed up by battery power. FIG. 6 shows a power supply state at the time of power failure recovery (AC output suppression and battery charging suppression: no current suppression). The power from the AC power source is supplied to the electronic device 1 and is in an empty state. (EMPTY) battery BT.

  FIG. 7 shows a power supply state at the time of power failure recovery (AC output suppression and battery charge suppression: current suppression). Supply of AC power to the electronic device 1 and the battery BT is prohibited. FIG. 8 shows a power supply state at the time of power failure recovery (during AC output suppression). Supply of AC power to the electronic device 1 is prohibited and only supply to the battery BT is performed. FIG. 9 shows a power supply state at the time of power failure recovery (during suppression of battery charging). Supply of AC power to the battery BT is prohibited and only supply to the electronic device 1 is performed.

FIG. 10 is a diagram for explaining the priority management information PM set in each UPS 2.
The priority management information PM includes a start timing for supplying AC power to the electronic device 1 and a start timing for supplying AC power to the battery BT when it is detected that the AC power supply has returned to a normal state. Is the management information of the priority order set for shifting each UPS 2 in terms of time, and has items of “device startup priority”, “battery charge priority”, and “change permission flag” It has a configuration.

  The “device startup priority” is a priority set in order to shift the start timing of supplying AC power to the electronic device 1 after each AC power supply is restored for each UPS 2. “Battery charging priority order” is a priority order set so as to shift the start timing of supplying AC power to the battery BY and starting charging after the AC power supply is restored for each UPS 2. Here, the UPS 2 with the priority “1” functions as the master UPS, and the master UPS 2 stores and manages the priority management information PM assigned to each other UPS 2.

These “device startup priority” and “battery charging priority” may be set in advance by the user in a fixed manner with respect to each UPS 2, and data communication between the UPSs 2 may be performed. Each priority order may be automatically determined by performing, but in this embodiment, both the input setting by the user and the automatic setting by data communication can be executed. Here, when automatic setting is performed by data communication, the priority order assigned to each UPS 2 is determined at random. In addition, the priority order assigned to each UPS 2 is periodically changed by periodically performing automatic priority setting.
The “change permission flag” is provided for prohibiting the above-described automatic priority change for the priority order input and set by the user, and corresponds to the priority order input and set by the user. By setting “impossible” in the “change permission flag”, automatic change of priority is prohibited.

  Next, the operation concept of each UPS 2 in the first embodiment will be described with reference to the flowcharts shown in FIGS. Here, each function described in these flowcharts is stored in the form of a readable program code, and operations according to the program code are sequentially executed. It is also possible to sequentially execute operations according to the program code transmitted via the transmission medium. This also applies to other embodiments described later, and in addition to the recording medium, operations specific to this embodiment can be executed using programs / data supplied externally via a transmission medium.

FIG. 11 is a flowchart showing priority order setting processing executed by each UPS 2.
First, the UPS 2 refers to its own priority management information PM, and at least one of the “device startup priority” and “battery charge priority” is “No. 1”. It is checked whether the UPS functions as a master (step A1). If the UPS 2 does not function as the master, the process proceeds to step A2, where it is checked whether or not the user has instructed to change the priority order. After fetching the input new priority (step A3), the master UPS 2 is requested to change and assign the priority, and the input new priority is transmitted to the master UPS 2 (step S3). Step A4). If there is no instruction to change the priority order (NO in step A2), it is checked whether or not the priority order has already been assigned (step A5), and if it has not been set (NO in step A5). The master UPS is requested to assign a new priority (step A4).

 On the other hand, the master UPS 2 that recognizes that it is the master based on the “priority for device startup” and the “priority for battery charging” (step A1ES) is a new request for priority received from another UPS 2 / Check whether or not a change request has been received (step A8). If a change request is received from another UPS2, the process proceeds to step A9, and the new priority order transmitted from this UPS2 is associated with the UPS2. Are stored and managed, and “non-permitted” is set in the “change permission flag”. Further, referring to the current priority assigned to each UPS 2, it is checked whether the same priority as the newly set priority is set in another UPS 2, and the same priority is set repeatedly. If the priority order is changed, the changed priority order is transmitted to the UPS 2.

 In addition, when the master UPS 2 receives a request for new assignment of priority from another UPS 2 (step A8), the current priority assigned to each UPS 2 is avoided in order to avoid duplicate setting of the same priority. By referring to the order, a new priority order is generated, the new priority order is stored and managed in association with the UPS 2 requested this time, and a process of transmitting to the UPS 2 is performed (step A9).

 If there is no new priority request or change request from another UPS 2 (NO in step A8), the master UPS 2 proceeds to processing for periodically changing the priority (steps A10 and A11). That is, the master UPS 2 determines whether or not a predetermined time has elapsed since the previous change, that is, at the timing of the periodic change, in order to periodically change the current priority set corresponding to each UPS 2. It is checked whether or not it has been reached (step A10). Here, if the periodic change timing has not been reached, the process returns to step A1, but if the periodic change timing has been reached, the process proceeds to step A11. Here, by referring to the current priority assigned to each UPS 2, the UPS 2 in which “permitted” is set in the “change permission flag” is determined as a change target, and then each UPS 2 has its respective priority. A priority is randomly generated and stored and managed, and the newly generated priority is transmitted to the corresponding UPS 2.

 On the other hand, in each UPS 2 other than the master, when its own priority is already assigned (step A5), when priority is transmitted from the master UPS 2 (step A6), this priority The order is acquired and the priority order is rewritten (step A7). Although not shown in the figure, when the new priority order generated by the master UPS 2 is transmitted, the UPS 2 that has requested the new assignment of the priority order receives the priority order and receives the new priority order. Set up.

FIG. 12 is a flowchart showing the overall processing related to power control executed in each UPS 2.
First, each UPS 2 checks whether power is being supplied to the AC output side in a state where its own priority is set (step B1). Normally, since AC power is being supplied, the AC voltage is detected to check whether or not an abnormality has occurred (step B2). Here, when an abnormality occurs in the AC voltage due to a power failure or the like, switching from the AC power source to the battery BT is started to start supplying battery power (step B3), and an AC_Fail signal is output (step B4). .

Here, the AC voltage is detected again to check whether or not the abnormal state has been recovered (step B5). If the abnormal state remains, the battery capacity is below a predetermined value (for example, 10% or less). It is checked whether or not it has decreased (step B7). At first, since the remaining battery level is sufficient, the process returns to step B1, but since the battery power is being supplied on the AC output side, the battery power is supplied while monitoring the battery capacity until the AC power returns to normal. Keep doing.
On the other hand, when the AC power supply is restored to the normal state (YES in step B5), the battery power supply is terminated and switched to the AC power supply (step B6).

 Here, when the battery capacity decreases to a predetermined value or less without returning the AC power supply to the normal state (YES in Step B7), the shutdown process is performed from the electronic device 1 after outputting the shutdown / LowBattery signal (Step B8). Wait until the end notification is returned (step B9). Here, when an end notification of the shutdown process is received, after waiting for a predetermined time required for the electronic device 1 to stop (step B10), the power supply from the battery BT is ended (step B11), and AC The power supply to the output side is cut off (step B12). Thereafter, the process returns to the first step B1, but in this case, since the AC output side is in the cut-off state, the process proceeds to step B13, where the AC voltage is detected to check whether or not the recovery from the abnormal state. Here, if the AC power supply remains in an abnormal state, the process returns to step B1 and is in a standby state until it returns to normal.

 If the AC power supply returns to normal (YES in step B13), it is checked whether there is an unprocessed return process (step B14). That is, when the AC power supply returns to normal, power is supplied to the electronic device 1 and the battery BT in accordance with the “priority of device startup” and “priority of battery charging” set in its own priority management information PM. Each of the return processes for supplying is executed, and it is checked whether any unprocessed return processes remain among the respective return processes. Here, immediately after the AC power supply is restored, all the restoration processes are in an unprocessed state, so that the process proceeds to step B15 and it is checked whether the priority of “No. 1” is self.

Here, if the self priority is No. 1 (master UPS2), the process proceeds to step B18, and whether the priority is “priority for starting up the device” or “priority for battery charging”. Check. If the “device startup priority” is “No. 1”, the power supply to the AC output side is started (step B20), and the AC power that has returned to normal is supplied to the electronic device 1. If the “priority of battery charging” is “No. 1”, charging of the battery BT is started (step B19). Then, after waiting for a predetermined time (step B21), it notifies all the other UPSs 2 that the return processing has been completed, and transmits the priority order to all the other UPSs 2 (step B22).
Thereafter, the process returns to step B14 to check whether there is another unprocessed return process. Now, when the return process related to the device start-up is completed and the return process related to the battery charge remains, or the return related to the battery charge. If the process is completed and there is a return process related to device startup, the loop from step B14 is repeated until the unprocessed return process is completed.

 On the other hand, each UPS 2 whose self priority is not “No. 1” (NO in step B15) is in a standby state until a return completion notification is received from another UPS 2 (step B16). When the return end notification transmitted from is received, the priority added to the end notification is compared with its own priority, and it is checked whether the next priority is self (step B17). Here, for example, if the priority added to the end notification is “1” and the self priority is “3”, the next priority is recognized as not self, and the process returns to step B16. If the priority added to the end notification is “1” and its own priority is “2”, the next priority is recognized as self.

Here, if the next priority is self, it is checked whether the priority is “priority for starting up the device” or “priority for battery charging” (step B18). If it is “priority for device startup”, power supply to the AC output side is started (step B20), but if it is “priority for battery charging”, charging to battery BT is started (step B20). B19). Then, after waiting for a predetermined time (step B21), it notifies all the other UPSs 2 that the return processing has been completed, and transmits the priority order to all the other UPSs 2 (step B22).
In this way, when the return process related to the device startup and the return process related to the battery charging are completed (NO in step B14), the process returns to the first step B1.

 As described above, the UPS 2 in the first embodiment has a “device startup priority” for itself so that there is a time difference from the “device startup priority” set in the other UPS 2. In a set state, when the power supply to the electronic device 1 is stopped and its operation is in a stopped state, when the AC power supply is restored to a normal state, it is determined whether or not its own priority is reached, Since the power supply to the electronic device 1 is temporarily prohibited until it reaches its own priority, the timing at which the plurality of UPSs 2 supply power to the electronic device 1 can be shifted in time, and the AC power supply It is possible to prevent re-power failure due to rush current when recovering normally, and even if several new electronic devices 1 are added, re-power failure is prevented when power is restored, including this additional device. Kill. In this case, the existing UPS structure itself provided for each electronic device 1 is not changed, and it can be easily realized simply by incorporating simple software into the existing UPS, which is advantageous in terms of cost. It becomes.

  In this case, the master UPS 2 determines priority with the other UPS 2 by performing data communication with the other UPS 2, and the determined priority of the master UPS 2 is higher than the priority of the other UPS 2 Transmits a notice of completion of the restoration process to the other UPS 2 after starting the power supply to the electronic device 1, and when the priority of the self is lower than the priority of the other UPS 2, Since the power supply to the electronic device 1 is temporarily prohibited until the end notification of the restoration process is transmitted from the UPS 2, the priority order can be automatically set for each UPS 2 and the setting is performed as set. It becomes possible to realize power supply control.

Since the master UPS 2 determines the priority for starting the power supply to the electronic device 1 and the start priority for starting the charging of the battery BT, the power supply to the electronic device 1 and the charging to the battery BT are determined. Can be shifted in time, which is more effective as a measure for preventing a power failure due to a rush current.
Since the master UPS 2 automatically changes the priority order periodically, it is possible to prevent the priority order from being fixed, and it is possible to ensure equality with respect to a measure for preventing a power failure due to a rush current. In this case, for the priority order input and set by the user, automatic change of the priority order can be prohibited.

  When each UPS 2 detects that the AC power supply has been restored to a normal state, it determines whether or not the priority order for starting charging the battery BT has been reached, and the battery BT is set until its own priority order is reached. Therefore, the power supply to the electronic device 1 and the charge to the battery BT can be shifted in time, which is more effective as a measure for preventing a power failure due to a rush current.

In the first embodiment described above, the case where the electronic device 1 and the UPS 2 are associated one-to-one is illustrated, but this is a case where a plurality of electronic devices as protection targets are connected to the UPS 2. However, the same applies.
In addition, the priority order may be set by the user for each UPS 2, and further, for example, a time interval may be set every 10 seconds as the power supply start timing for each UPS 2. Good. In this case, for example, “0 second” for the first UPS 2, “10 seconds” for the second UPS 2, “20 seconds” for the third UPS 2,... “10 seconds × (N−1) seconds” may be set.

  In the first embodiment described above, automatic change of the priority order is prohibited for the priority order input and set by the user, but for the UPS 2 arbitrarily designated by the user. The automatic change of the priority order may be prohibited. Accordingly, it is possible to give the highest priority to the power supply by arbitrarily specifying a specific electronic device (for example, an electronic device in charge of important processing).

On the other hand, a recording medium (for example, a CD-ROM, a floppy disk, a RAM card, etc.) on which a program code for executing each of the above-described units is recorded may be provided to the computer. That is, a computer-readable recording medium having a program code, and when the commercial power source is normal, the power from the commercial power source is supplied to the electronic device and the internal battery is charged with the power from the commercial power source, When the commercial power source is abnormal, the power stored in the battery is supplied to the electronic device, and when the supply of the battery power is stopped, the function of stopping the operation of the electronic device and the electronic device The function that monitors whether the commercial power supply has returned to the normal state when the power supply is stopped and the operation is stopped, and when the normal recovery of the commercial power supply is detected, A function to determine whether or not the start timing for supplying power has been reached, and temporarily prohibit power supply to the electronic equipment until the preset start timing is reached, and other uninterruptible power It is also possible to provide a computer-readable recording medium on which a program for realizing a function for setting a start timing for itself so as to cause a time difference from the start timing set in the source device is recorded. Good.
(Example 2)

A second embodiment of the present invention will be described below with reference to FIGS.
In the second embodiment, in a campus environment where a plurality of UPSs 2 exist, power is interchanged between the UPSs 2 to realize an effective power backup of the entire campus. is there. That is, a UPS with sufficient battery capacity when the AC power supply is abnormal supplies battery power to another UPS with insufficient battery capacity, or a UPS with sufficient battery capacity when AC power is restored is insufficient with battery capacity Battery power is supplied to another UPS.
Here, the same or the same names in both embodiments are denoted by the same reference numerals, the description thereof will be omitted, and the following description will focus on the features of the second embodiment. .

FIG. 13 is a block diagram showing an overview of the overall configuration of the local system in the second embodiment.
In this premises system, a plurality of personal computers (PCs) 11-1, 11-2,... 11-n exist in the premises (for example, the entire company, one floor, one room, etc.), and each PC 11- 1, 11-2,... Is a system environment in which UPS 12-1, 12-2,.
The PCs 11-11, 11-2,... Are functionally the same, and when there is no need to distinguish them, the PCs are collectively referred to as the server system 11, and The UPSs 12-1, 12-2,... Are functionally the same, and when there is no need to distinguish them, the UPSs are collectively referred to as UPS12.

Each UPS 12 is connected to an external commercial power supply AC line. Further, the UPS 12 and the PC 11 are connected by a UPS-PC power supply line and also by a UPS-PC control signal line. Here, as described above, each UPS 12 supplies power from the AC power supply to the corresponding PC 11 and charges the internal battery with the power from the AC power supply when the AC power supply is normal. In the case of a power failure or the like, the power stored in the battery is supplied to the corresponding PC 11. The UPSs 12 are connected to each other by an inter-UPS power supply line and are connected by an inter-UPS control signal line.
Note that the UPS power supply line performs power transmission using an AC signal in order to reduce the power loss due to the resistance component when the distance is long, for example, depending on the number of locally connected devices and the maximum distance. Alternatively, when the distance is short, power transmission by a DC signal may be performed in order to simplify the circuit.

FIG. 14 is a block diagram showing basic components of each UPS 12.
The UPS 12 has basically the same configuration as the UPS of the first embodiment described above, and includes a CPU, storage device, RAM, network interface, serial interface, input device, display device, battery BT, and battery charge / discharge control unit 26. In addition to the AC switching control unit 27, the power transmission control unit 123 is provided. As shown in FIG. 15, the power transmission control unit 121 controls power supply for accommodating battery power among the plurality of UPSs 12 according to instructions from the CPU.

FIG. 15 is a diagram showing a power system connection diagram among a plurality of UPSs 12.
This example shows a case in which the battery power is supplied from the UPS 12-1 having sufficient battery capacity to another UPS 12-3 having insufficient battery capacity. In this case, the power transmission control unit 121 of the UPS 12-1 supplies its battery power to the inter-UPS power supply line. At this time, among the other UPSs 12, the power transmission control unit 121 on the UPS 12-3 side is set to a state in which power on the inter-UPS power supply line can be taken in, and the other UPSs 12-2 are connected between UPSs. The power on the power supply line is set so as not to be captured. In this state, the battery power from the UPS 12-1 is supplied only to the UPS 12-3.

FIG. 16 is a diagram for explaining the power control condition management information PC set in each UPS 12.
The power control condition management information PC includes a condition for the UPS 12 having a sufficient battery capacity to supply battery power to another UPS 12 having insufficient battery capacity when the AC power is abnormal or when the AC power is restored, and the battery capacity is insufficient. The UPS 12 is condition management information for managing conditions for requesting the UPS 12 having sufficient battery capacity to supply battery power. In other words, this power control condition management information PC stores and manages various conditions corresponding to the time of AC abnormality and the time of AC normality (at the time of recovery). "Remaining battery condition", "Battery remaining condition requiring power transmission from other UPS", and "Battery remaining condition permitting power transmission to other UPS".

The “remaining battery condition for starting the shutdown process” indicates the remaining battery capacity that is a condition for starting the shutdown process in which the PC 11 is stopped as the battery power decreases. In the illustrated example, the UPS 12-1 Is set to “5% or less”, and UPS 12-2 is set to “10% or less”.
The “remaining battery condition for requesting power transmission from other UPS” indicates the remaining battery capacity as a condition when the UPS 12 having insufficient battery capacity requests the UPS 12 having sufficient battery capacity to supply battery power. In the illustrated example, “20% or less” is set in the UPS 12-1, and “15% or less” is set in the UPS 12-2.
“Battery remaining amount condition permitting power transmission to another UPS” indicates a remaining battery amount that is a condition when the UPS 12 having a sufficient battery capacity supplies battery power to the other UPS 12 having insufficient battery capacity, In the illustrated example, “80% or more” is set in the UPS 12-1, “30% or more”,... Is set in the UPS 12-2.

In addition, the conditions corresponding to normal AC (recovery) are as follows: “remaining battery condition for starting restart process”, “remaining battery condition for requesting power transmission from other UPS”, “to other UPS Each item of “remaining battery condition permitting power transmission” is included.
The “remaining battery condition for starting the restart process” indicates the remaining battery capacity that is a condition when the PC 11 starts restarting at the time of AC recovery. In the illustrated example, the UPS 12-1 indicates “0% or more”. “30% or more”,... Are set in the UPS 12-2.

  The “remaining battery condition for requesting power transmission from other UPS” and the “remaining battery condition for permitting power transmission to another UPS” indicate the remaining battery capacity as in the above case. In the illustrated example, “15% or less”,... Is set in the UPSs 12-1 and 12-2 as the “remaining battery condition for requesting power transmission from other UPS”. As the “remaining battery condition for permitting power transmission”, “70% or more” is set in the UPS 12-1, “60% or more”, etc. in the UPS 12-2.

  Here, in the illustrated setting example, the UPS 12-1 is a UPS for protecting the PC 11 that is required to operate at all times, and is a condition that can operate to the limit even when the remaining battery level is low. Is set. The UPS 12-2 is a UPS for protecting the PC 11 for which high reliability is demanded. While the battery remaining amount is low, in order to prevent troubles when power failures occur continuously. This is a case where a condition that does not start is set.

FIG. 17 is a flowchart showing the overall operation of each UPS 12.
Each UPS 12 constantly monitors the presence or absence of an AC voltage abnormality. When an abnormality in the AC voltage is detected due to a power failure or the like (step C1), the UPS 12 performs control according to the AC abnormality.
First, the UPS 12 detects the remaining amount of the battery BT, accesses the power control condition management information PC, and compares the current battery remaining amount with the “battery remaining amount condition that requires power transmission” to thereby calculate the power. It is checked whether or not a requirement condition related to transmission is satisfied (step C2). If the remaining battery level is insufficient and the establishment of the required condition is detected, the power on the inter-UPS power supply line is set to a state where it can be taken in, and the inter-UPS power supply is set. After the electric power on the line is supplied to its own battery BT and charging is started (step C3), the process returns to the first step C1. Thus, for example, when the remaining battery level on the UPS 12-1 side becomes 20% or less, the UPS 12-1 continues to charge the power on the inter-UPS power supply line until the remaining battery level exceeds 20%.

  On the other hand, the UPS 12 compares the current battery remaining amount with the “battery remaining amount condition permitting power transmission to other UPS” to check whether the permission condition regarding power transmission is satisfied (step C4). Here, when the remaining battery capacity is sufficient and the establishment of the permission condition permitting power transmission to another UPS 12 is detected, the battery power is supplied on the inter-UPS power supply line. Later (step C5), the process returns to the first step C1. Thus, for example, when the battery capacity on the UPS 12-1 side is 80% or more, the UPS 12-1 continues to supply power on the inter-UPS power supply line until the remaining battery capacity becomes less than 80%. .

  The UPS 12 checks whether the battery power is being supplied to the AC output side (PC11 side) when the AC voltage is abnormal (step C6). If the battery power is not being supplied, the UPS 12 returns to step C1, If the battery power is being supplied, the current battery remaining amount is compared with the “battery remaining amount condition for starting the shutdown process” to check whether the start condition for the shutdown process is satisfied (step C7). Here, when the establishment of the start condition is detected (for example, when the remaining battery level on the UPS 12-1 side becomes 5% or less), the shutdown process similar to that in the first embodiment described above is performed ( Step C8).

On the other hand, when the AC voltage is recovered from the normal state, this is detected in step C1, and control is performed according to the normal AC state (at the time of return).
First, the UPS 12 detects the remaining amount of the battery BT, accesses the power control condition management information PC, and compares the current battery remaining amount with the “battery remaining amount condition that requires power transmission” to thereby calculate the power. It is checked whether or not a requirement condition related to transmission is satisfied (step C9). If the remaining battery level is insufficient and the establishment of the required condition is detected, the power on the inter-UPS power supply line is set to a state where it can be taken in, and then this inter-UPS power supply is set. The power on the line is supplied to its own battery BT to start charging (step C3).

  Further, at the time of AC recovery, the UPS 12 compares the current battery remaining amount with “battery remaining amount condition permitting power transmission to other UPS” to check whether or not a permission condition related to power transmission is satisfied ( Step C10). Here, when there is a surplus in its own battery remaining amount and power transmission to another UPS 12 is permitted, the power from the battery BT is supplied to the inter-UPS power supply line (step C5). Further, at the time of AC recovery, the UPS 12 checks whether or not power is being supplied to the AC output side (PC11 side) (step C11). If it is in the middle, the present battery remaining amount is compared with the “battery remaining amount condition for starting the restart process” to check whether or not the start condition for the restart process is satisfied (step C12). Here, when the start condition for the restart process is satisfied, the restart process for starting the power supply to the PC 11 is performed (step C13), but the remaining battery level is insufficient and the start condition is not satisfied. In step C1, the power supply to the PC 11 is temporarily prohibited until the start condition is satisfied.

  As described above, in the second embodiment, each UPS 12 is connected via the inter-UPS power supply line, and requests power supply to other UPSs 12 or supplies power to other UPSs 12. In the state where the conditions to be permitted are set, when the establishment of the condition is detected, power transmission is started with other UPS 12, so that the remaining battery capacity of each UPS 12 is different, Even if the reliability required for each PC 11 is different, by automatically transferring power between each UPS 12, it is possible to always provide the necessary backup time for the necessary equipment. The secured state can be maintained.

In this case, in a campus environment where a plurality of UPSs 12 exist, battery power can be interchanged between the UPSs 12 while the PC 11 is being backed up due to an abnormality in the AC power supply. It is possible to realize an effective backup.
In addition, since the condition for starting the power supply to the PC 11 after the AC power supply is restored to the normal state is designated by the value of the remaining battery level, when the remaining battery level is extremely low, In preparation for a power failure, power supply to the PC 11 can be temporarily suppressed until the remaining battery level reaches a predetermined value.

  In the second embodiment described above, the setting of the power control condition management information PC has not been mentioned. However, in addition to the case where the user arbitrarily inputs and sets, for example, it is predetermined for each PC 11. The power control condition management information PC may be automatically set by referring to importance and reliability. Furthermore, the user may arbitrarily change the contents of the power control condition management information PC set as default.

  On the other hand, you may make it provide the recording medium which each recorded the program code for making a computer perform each means mentioned above. That is, a computer-readable recording medium having a program code, and when the commercial power source is normal, the power from the commercial power source is supplied to the electronic device and the internal battery is charged with the power from the commercial power source, When the commercial power supply is abnormal, the power stored in the battery is supplied to the electronic device, and the power supply is requested to another uninterruptible power supply, or the other uninterruptible power supply A computer that records a program for realizing a function for setting a condition for permitting power supply and a function for starting power transmission with another uninterruptible power supply when the condition is satisfied is readable by a computer A simple recording medium may be provided.

The block diagram which showed the outline | summary of the whole structure of the premise system provided with the uninterruptible power supply management function. The block diagram which showed the basic component of UPS2. The electric power system connection diagram centering on the battery charging / discharging control part 26 and the AC switching control part 27. The figure which showed the supply state of the electric power at the time of normal driving | operation. The figure which showed the supply state of the electric power at the time of a power failure. The figure which showed the supply state of the electric power at the time of a power failure recovery | restoration (AC output suppression and battery charge suppression: no current suppression). The figure which showed the supply state of the electric power at the time of a power failure recovery | restoration (AC output suppression and battery charge suppression: Current suppression). The figure which showed the supply state of the electric power at the time of a power failure recovery | restoration (during AC output suppression). The figure which showed the supply state of the electric power at the time of a power failure recovery (during battery charge suppression). The figure for demonstrating the priority management information PM set to each UPS2. The flowchart which showed the priority order setting process which each UPS2 performs. The flowchart which showed the whole process regarding the power control performed in each UPS2. The block diagram which showed the outline | summary of the whole structure of the premise system in 2nd Example. The block diagram which showed the basic component of each UPS12. The figure which showed the electric power system connection diagram between several UPS12. The figure for demonstrating the power control condition management information PC set to each UPS12. The flowchart which showed the whole operation | movement of each UPS12.

Explanation of symbols

1 Electronic equipment (server system)
2, 12 UPS
3 Network 4 AC power 11 PC
21 CPU
22 storage device 24 network interface 25 serial interface 26 battery charge / discharge control unit 27 AC switching control unit 121 power transmission control unit BT battery PM priority management information
PC power control condition management information

Claims (4)

Connected between the commercial power source and the electronic device, and when the commercial power source is normal, the power from the commercial power source is supplied to the electronic device and the power from the commercial power source is charged to the internal battery. In this case, the electric power stored in the battery is supplied to the electronic device, and when the supply of the battery power is stopped, the uninterruptible power supply device that stops the operation of the electronic device,
Monitoring means for monitoring whether or not the commercial power supply is restored to a normal state when power supply to the electronic device is stopped and its operation is stopped;
A determination means for determining a priority order of a start timing for supplying power to the electronic device with the other uninterruptible power supply by performing data communication with the other uninterruptible power supply;
When it is detected successfully recovered by said monitoring means, to determine whether it has reached the start timing, temporarily prohibiting control unit power supply to the electronic device until the start timing which is set in advance When,
And when the priority of the determined self is higher than the priority of the other uninterruptible power supply device, the control means starts the power supply to the electronic device and then starts the other uninterruptible power supply. If a return completion notification is sent to the device and its own priority is lower than that of the other uninterruptible power supply, the electronic An uninterruptible power supply characterized by temporarily prohibiting power supply to equipment. The determining means determines a priority order of start timing for starting power supply to the electronic device and a priority order of start timing for starting charging of the internal battery.
The uninterruptible power supply according to claim 1, which is configured as described above. Provided with a changing means for periodically changing the priority of the start timing determined by the determining means;
The uninterruptible power supply according to claim 1 . Providing a designation means for designating whether or not to permit periodic change of priority by the changing means;
Prohibit change of priority that is designated as non-changeable by this specification means.
The uninterruptible power supply according to claim 3, which is configured as described above.

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