JP2009290949A - Power managing system, uninterruptible power supply unit, and method and program for estimating power trend - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a power managing system which accurately estimates the life of a battery that an uninterruptible power unit has, and protects an information processor properly. <P>SOLUTION: An uninterruptible power supply system 1 is provided with a current-voltage source 2, an uninterruptible power supply unit 3, which can supply power, and a basic processor 4, which receives power supply from the uninterruptible power unit 3. The uninterruptible power supply unit 3 is provided with a power load measuring part, which measures a power value and a load value to be supplied, a power value recorder, which records the measured power value, and a trend predictor 25, which predicts the usable grace time of the battery 7, from the recorded power value and the measured load value. The basic processor 4 is provided with a basic processor controller 10, a memory 11, the first extension memory 12, the second extension memory 13, the first magnetic memory 14, the second magnetic memory 15, the third magnetic memory 16, a nonvolatile memory 17, a basic processor monitor 18, a basic processor controller primary battery 19, and a power source 20. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a power management system, an uninterruptible power supply, a power management method, a power trend prediction method, and a power trend prediction program.

  In recent years, progress in technology related to information processing apparatuses has progressed. In many companies, these information processing apparatuses are used to construct a network within the company.

  Therefore, when using such an information processing device, a power management device that prevents failures due to power outages and voltage changes is provided, and an uninterruptible power supply device that uses the information processing device stably and continuously (hereinafter referred to as this). Is also known as UPS (Uninterruptible Power Supply).

  As such an uninterruptible power supply, for example, Patent Document 1 relates to a computer system including a power supply device that supplies a direct current to a node, a current measurement device, and a system control device that controls the system. It is described in.

  Patent Document 2 describes an information processing apparatus that communicates with an uninterruptible power supply apparatus having a plurality of output means, monitors the state of the uninterruptible power supply apparatus, and individually controls the plurality of output means. ing.

JP 2007-233894 A JP 2005-077093 A

  However, the above-mentioned document description has room for improvement in the following points.

  In Patent Document 1 or 2, when a power failure occurs, the power supply to the information processing apparatus is stopped when a certain time has elapsed after issuing a shutdown command to the information processing apparatus.

  Here, the value of the fixed time used when a power failure occurs is a waiting time until completion of the shutdown process set when the information processing apparatus is introduced.

Originally, because the following four values fluctuate due to the increase in the data amount of the information processing device and the aging of the battery of the uninterruptible power supply device, the value of the waiting time until the shutdown processing is completed, Regular review is required.
(1) Increase in data handling volume due to expansion of storage area in information processing device (2) Increase in data handling volume due to expansion of magnetic storage device (3) During shutdown processing, from storage area of information processing device to magnetic storage device Increase in amount of data to be written (4) Battery capacity of uninterruptible power supply due to secular change, decrease in maximum time value that can be voltage compensated until shutdown processing is completed

  However, generally, the value set at the time of introduction of the information processing apparatus is used as it is as the value of the waiting time until the shutdown process is completed, and is hardly reviewed after the introduction.

  Therefore, there is a problem that when the power failure occurs, the uninterruptible power supply turns off during the shutdown process of the information processing device (this is called a dirty shutdown). there were.

  For this reason, it did not play a role as an uninterruptible power supply, and sometimes it fell to the end. In particular, in areas where power outages due to lightning strikes and the like do not occur so much, shutdown processing due to power outages is hardly performed, and thus there is a high possibility that dirty shutdown will occur.

  Moreover, in what was described in patent documents 1 and 2, when a power failure occurs, it detects that a power failure occurred on the information processing device side which is the node side, and functions to complete the shutdown process. There was a problem that load information by shutdown processing could not be acquired.

  And since the information processing device on the node side has a larger circuit scale than the power supply device, it easily breaks down, and when an overvoltage due to a lightning strike etc. occurs, the overvoltage compensation circuit of the power supply device can not prevent it, There is a case where the information processing apparatus stalls, and there is a problem that the information processing apparatus never starts again due to an overvoltage.

  Furthermore, when the data measured by the current measuring device is recorded in the information processing device on the node side, there is a problem that the measured data may be lost.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide power management capable of accurately predicting the life of a battery included in the uninterruptible power supply apparatus and appropriately protecting the information processing apparatus. An object is to provide a system, an uninterruptible power supply, a power management method, a power trend prediction method, and a power trend prediction program.

According to the present invention, a power management system comprising an uninterruptible power supply capable of supplying power by a battery at the time of a power failure, and an information processing device receiving power supply from the uninterruptible power supply by the battery,
The information processing apparatus includes:
Comprising a shutdown means for stopping the processing in operation and terminating the use of the information processing apparatus;
The uninterruptible power supply is
The power value to be supplied to the information processing apparatus and the load on the information processing apparatus until the shutdown process of the information processing apparatus stops the operation of the information processing apparatus and ends the use of the information processing apparatus Power load measuring means for measuring the value,
Power value recording means for recording the power value of the information processing apparatus measured by the power load measuring means;
Trend predicting means for predicting a grace time that the battery can be used from the power value recorded by the power value recording means and the load value measured by the power load measuring means;
A power management system is provided.

According to the present invention, an uninterruptible power supply capable of supplying power by a battery at the time of a power failure,
The power value supplied to the information processing device and the load on the information processing device until the information processing device connected to the uninterruptible power supply is stopped and the use of the information processing device is terminated. Power load measuring means for measuring the value,
Power value recording means for recording the power value of the information processing apparatus measured by the power load measuring means;
Trend predicting means for predicting a grace time that the battery can be used from the power value recorded by the power value recording means and the load value measured by the power load measuring means;
An uninterruptible power supply device is provided.

According to the present invention, there is provided a power management method in a power management system including an uninterruptible power supply that can be powered by a battery in the event of a power failure, and an information processing device that receives power from the uninterruptible power supply by the battery. ,
A shutdown step in which the information processing apparatus stops an active process and ends use of the information processing apparatus;
In the shutdown step, the uninterruptible power supply device stops the process during operation of the information processing device and ends the use of the information processing device and the power value supplied to the information processing device and the information processing device A power load measuring step for measuring the load value of
The uninterruptible power supply apparatus records the power value of the information processing apparatus measured in the power load measuring step, and a power value recording step,
A trend prediction step in which the uninterruptible power supply apparatus predicts a grace time that the battery can be used from the power value recorded in the power value recording step and the load value measured in the power load measurement step; ,
A power management method is provided.

According to the present invention, a power supply trend prediction method in an uninterruptible power supply capable of supplying power by a battery at the time of a power failure,
The power value supplied to the information processing device and the load on the information processing device until the information processing device connected to the uninterruptible power supply is stopped and the use of the information processing device is terminated. A power load measuring step for measuring a value;
A power value recording step for recording the power value of the information processing apparatus measured in the power load measuring step;
A trend prediction step of predicting a grace time that the battery can be used from the power value recorded in the power value recording step and the load value measured in the power load measurement step;
A power supply trend prediction method is provided.

According to the present invention, a power trend prediction program in an uninterruptible power supply capable of supplying power by a battery at the time of a power failure,
The power value supplied to the information processing device and the load on the information processing device until the information processing device connected to the uninterruptible power supply is stopped and the use of the information processing device is terminated. Power load measurement procedure to measure the value,
A power value recording procedure for recording the power value of the information processing apparatus measured by the power load measurement procedure;
A trend prediction procedure for predicting a grace time for the battery from the power value recorded by the power value recording procedure and the load value measured by the power load measurement procedure;
Is provided for causing a computer to execute a power supply trend prediction program.

  According to the present invention, a power management system, an uninterruptible power supply, a power management method, and a power trend prediction method that can accurately predict the life of a battery included in the uninterruptible power supply and protect the information processing apparatus appropriately. And a power trend prediction program is provided.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In all the drawings, the same reference numerals are given to the same components, and the description will be omitted as appropriate.

  FIG. 1 shows an uninterruptible power supply system (power management system) 1 according to the present embodiment.

  An uninterruptible power supply system 1 shown in FIG. 1 includes a current / voltage source 2, an uninterruptible power supply 3 that can be supplied with power by a battery 7 in the event of a power failure, and an information processing device that receives power supply from the uninterruptible power supply 3 by a battery 7. (Basic processing device) 4.

  An uninterruptible power supply 3 shown in FIG. 1 includes an uninterruptible power supply control unit 8 that performs overall control, an AC-DC converter 5, a DC-AC inverter 6, a battery 7, a virtual load unit 9, A load measurement mechanism unit 21, a nonvolatile storage unit 24, a trend prediction unit 25, and a timer unit 26 are provided.

  The uninterruptible power supply control unit 8 is a CPU (Central Processing Unit) that performs overall control of the entire uninterruptible power supply 3 and appropriately controls each function by various programs.

  The AC-DC converter 5 is a converter that converts an alternating current acquired from the current / voltage source 2 into a direct current.

  The DC-AC inverter 6 is a power supply circuit that generates an alternating current from a direct current charged in the battery 7.

  The battery 7 is a secondary battery that can be used repeatedly by charging.

  The virtual load unit 9 is a virtual load when trend prediction is executed by the trend prediction unit 25 described later, and has a virtual load that is assumed to be the basic processing device 4. Note that the virtual load unit 9 is not limited to a fixed value, and may be set so as to vary depending on the continuous use time or the continuous use years. The virtual load unit 9 also corresponds to a virtual load life prediction unit 33 described later.

  The load measurement mechanism unit 21 forms an electric energy measurement circuit that performs electric power measurement. The load measurement mechanism unit 21 measures power and electric energy consumed in the shutdown process when a power failure occurs, and performs trend prediction using the virtual load unit 9. It is a measurement circuit that performs measurement during implementation. Further, the load value of the basic processing device 4 is also measured from the power supply unit 20. The load measuring mechanism unit 21 corresponds to a power load measuring unit 31 described later.

  The nonvolatile storage unit 24 is formed of a semiconductor memory that can retain stored contents even when the power is turned off. The nonvolatile storage unit 24 also corresponds to a power value recording unit 32 described later.

  The trend prediction unit 25 has a function of predicting the life of the battery 7 from the power value and the load value measured by the load measurement mechanism unit 21, and functions as a trend prediction described later.

  The timer unit 26 is a circuit that measures the time until the uninterruptible power supply 3 cuts off the power supply to the basic processing device 4, and cuts off the power supply when the time for turning off the power supply is set as the shutdown setting time. Measure the shutdown setup time until.

  The basic processing device 4 shown in FIG. 1 includes a basic processing device control unit 10 that performs overall control, a storage unit 11, a first extended storage unit 12, a second extended storage unit 13, and a first magnetic unit. Storage unit 14, second magnetic storage unit 15, third magnetic storage unit 16, nonvolatile storage unit 17, basic processing device monitoring unit 18, basic processing device control unit primary battery 19, power supply unit 20 , A clock unit 22 and a display unit 23 are provided.

  The basic processing device control unit 10 is a CPU that performs overall control of the entire basic processing device 4 and appropriately controls each function by various programs.

  The storage unit 11 is a storage unit using a semiconductor element, and is formed by a RAM (Random Access Memory) or the like.

  The first extended storage unit 12 and the second extended storage unit 13 are extended memories and are expanded by the user.

  The first magnetic storage unit 14 is formed by a magnetic storage device such as a hard disk.

  The second magnetic storage unit 15 and the third magnetic storage unit 16 are formed by a magnetic storage device such as a hard disk.

  The nonvolatile storage unit 17 is formed of a semiconductor memory that can retain stored contents even when the power is turned off.

  The basic processing device monitoring unit 18 is a monitoring unit that monitors the processing operation of the basic processing device 4.

  The basic processing device control unit primary battery 19 is a primary battery that discharges DC power to the basic processing device control unit 10.

  The power supply unit 20 is a power circuit that generates required output power from input power, and is formed as a power converter that generates power to be supplied to the basic processing device 4.

  The clock unit 22 has a function of providing time information to the basic processing device control unit 10 when the basic processing device 4 performs a scheduled shutdown.

  The display unit 23 is a liquid crystal display or a monitor that displays perceptible to the user.

  The first extended storage unit 12 and the second extended storage unit 13, and the second magnetic storage unit 15 and the third magnetic storage unit 16 built in the basic processing device 4 are not connected when the system is introduced, and the basic It is assumed that the number of data handled by the processing device 4 is increased by the user as the data amount increases.

  Further, the uninterruptible power supply 3 is configured such that the uninterruptible power supply control unit 8 is operated by hardware and various programs, and the configuration of functions at that time is shown in FIG.

  FIG. 2 is a functional block diagram of the uninterruptible power supply 3.

  The uninterruptible power supply 3 shown in FIG. 2 is processed by the basic processing device controller 10 of the basic processing device 4 until the basic processing device 4 is stopped and the basic processing device 4 is stopped. A power load measuring unit 31 that measures the power value supplied to the device 4 and the load value of the basic processing device 4, and a power value recording unit 32 that records the power value of the basic processing device 4 measured by the power load measuring unit 31. A trend prediction unit 25 that predicts a grace time that the battery 7 can be used from the power value recorded by the power value recording unit 32 and the load value measured by the power load measurement unit 31; And a corresponding virtual load life prediction unit 33.

  In addition, the basic processing device 4 shown in FIG. 1 has a shutdown function in which the basic processing device control unit (shutdown means) 10 stops the running process and ends the use of the basic processing device 4.

  Next, the overall operation of the uninterruptible power supply system 1 according to the present embodiment will be described in detail.

  FIG. 3 is a sequence diagram showing the entire operation of the uninterruptible power supply system 1.

  In the sequence diagram shown in FIG. 3, the uninterruptible power supply 3 that receives power supply from the current / voltage source 2 starts the charging operation for the battery 7 via the AC-DC converter 5 (step S01). Power supply to the power supply control unit 8 is started (step S03).

  When the uninterruptible power supply control unit 8 detects the set time or recovery from the power failure, the uninterruptible power supply control unit 8 starts to supply power to the power supply unit 20 via the DC-AC inverter 6 and the load measurement mechanism unit 21 (step S05).

  The basic processing device control unit 10 that receives power supply to the power supply unit 20 performs initialization operations of the basic processing device control unit 10 and various registers of the basic processing device monitoring unit 18 and the storage unit 11 (step S07). At this time, if the first extended storage unit 12 or the second extended storage unit 13 exists, the initialization operation of the first extended storage unit 12 or the second extended storage unit 13 is also performed. In this embodiment, the initialization operation refers to setting of a register value of the basic processing device control unit 10, power supply confirmation, or preprocessing for causing the basic processing device 4 to function.

  And if the uninterruptible power supply control part 8 detects a power failure (step S09), the battery operation will be started with respect to the power supply part 20 from the battery 7 via the DC-AC inverter 6 and the load measurement mechanism part 21 (step S09). Step S11).

  Further, the uninterruptible power supply control unit 8 notifies the basic processing device control unit 10 of a power failure by serial communication (hereinafter referred to as a power failure notification) (step S13), and then the basic processing device 4 performs a shutdown process. From the start to the completion, the load measurement mechanism unit 21 performs the power load measurement operation (step S17).

  In the present embodiment, the power load measuring operation refers to measuring at least one of a power value or a power amount value and a load value of the basic processing device 4. Further, the load measurement mechanism unit 21 measures the time until the basic processing device 4 is shut down.

  And the uninterruptible power supply control part 8 records the electric power value or electric energy value measured by the load measurement mechanism part 21 in the non-volatile memory | storage part 24 (step S19).

  In addition, since the recording information of the non-volatile storage unit 24 is backed up by the battery 7, the recording information is not lost even after the power failure is resolved.

  On the other hand, when receiving the power failure notification in step S13, the basic processing device controller 10 executes a shutdown process for shutting down the basic processing device 4 (step S15).

  In this shutdown process, when the first extended storage unit 12 or the second extended storage unit 13 exists, the data is written to the second magnetic storage unit 15 or the third magnetic storage unit 16 connected thereto, respectively. The data writing process is also performed when the writing process is performed and there is still data that cannot be written.

  When the basic processing device 4 completes the shutdown processing, the basic processing device control unit 10 notifies the uninterruptible power supply 3 that the shutdown processing has been completed (hereinafter referred to as shutdown processing completion notification). This is performed (step S21).

  Thereby, the uninterruptible power supply control part 8 will interrupt | block the power supply by the battery 7, if the notification of a shutdown process completion is received by step S21 (step S23).

  Further, the basic processing device 4 has a process called schedule shutdown, and can start the shutdown process when a certain time or a certain period of time has passed according to the time information of the clock unit 22.

  The operation in this case will be described using a sequence diagram.

  FIG. 4 is a sequence diagram showing a notification that the uninterruptible power supply 3 is to be shut down by the basic processing device 4 based on a schedule shutdown notification (hereinafter referred to as a schedule shutdown notification).

  In FIG. 4, steps that perform the same processing as in FIG. 3 are assigned the same step numbers, and descriptions thereof are omitted.

  The difference between the sequence diagram in FIG. 4 and the sequence diagram in FIG. 3 is that the sequence diagram shown in FIG. 4 has step S31 and step S33.

  The basic processing device 4 includes a schedule shutdown determination step (step S31), and the basic processing device control unit 10 acquires time information from the clock unit 22 at any time, and determines whether the schedule shutdown time has been exceeded. When the operation is performed and the schedule shutdown time is reached, the basic processing device controller 10 sends a schedule shutdown notification to the uninterruptible power supply controller 8 by serial communication (step S33).

  In addition, when the scheduled shutdown time comes, the basic processing device controller 10 performs the shutdown process in step S15 and performs the above-described data write process.

  Also in this case, as described above, in step S19, the power load measuring operation by the load measuring mechanism unit 21 is performed and recorded in the nonvolatile storage unit 24 until the shutdown process is completed. The scheduled shutdown notification can include the shutdown set time, and when the shutdown set time is notified in step S33, the power supply in step S23 can be set to be cut off after the time has elapsed. .

  The overall operation of the uninterruptible power supply system 1 in the present embodiment has been described above, but the independent operation in the uninterruptible power supply 3 will be described below.

  FIG. 5 is a flowchart showing the single operation of uninterruptible power supply 3 of uninterruptible power supply system 1 according to the present embodiment.

  The flowchart of the uninterruptible power supply 3 shown in FIG. 5 represents the same processing as that in FIG. 3 although the display method in step S09 is different. When a power failure is detected, battery operation by the battery 7 is started. ing.

  Next, the single operation in the basic processing device 4 will be described below.

  FIG. 6 is a flowchart showing the single operation of basic processing device 4 of uninterruptible power supply system 1 according to the present embodiment.

  The flowchart of the basic processing device 4 illustrated in FIG. 6 represents the same processing as that in FIG. 3, and indicates that the basic processing device 4 starts the shutdown processing when a power failure notification is received in step S13 ( Step S15).

  Further, the uninterruptible power supply system 1 according to the present embodiment includes a trend prediction unit 25 that performs life prediction of the battery 7 of the uninterruptible power supply 3 in addition to the above-described embodiment.

  Next, the operation of the life prediction of the battery 7 performed by the trend prediction unit 25 will be described below with this life prediction as a trend prediction.

  FIG. 7 is a sequence diagram illustrating processing when the trend prediction unit 25 performs trend prediction.

  First, the uninterruptible power supply control unit 8 determines the necessity of the periodic battery diagnosis when the periodic diagnosis of the battery 7 has not yet been performed or when a predetermined number of days has passed since the previous shutdown process (step S41). ).

  And in this Embodiment, when the basic processing apparatus 4 has not implemented the shutdown process for a fixed period, it is set as the object of the battery periodic diagnosis using the virtual load.

  The fixed period may be a period of 2 months or 3 months, or 1 year or 2 years, and is not limited to this period.

  And the uninterruptible power supply control part 8 performs the following battery regular diagnoses (step S43), when it is necessary to perform the regular diagnosis of a battery.

  First, the uninterruptible power supply control unit 8 energizes the virtual load unit 9, measures current values and voltage drop values, and generates battery life prediction data. Then, the grace time prediction data at the time of power failure is calculated from the load value obtained by the power load measurement by the load measurement mechanism unit 21 acquired at the time of the previous shutdown process and the generated battery life prediction data.

  Then, the uninterruptible power supply control unit 8 records the battery life prediction data and the grace time prediction data at the time of power failure in the nonvolatile storage unit 24 (step S45).

  In addition, the trend prediction unit 25 performs trend prediction from the battery life prediction data recorded in the nonvolatile storage unit 24 and the grace time prediction data at the time of a power failure at regular intervals (step S47).

  The trend prediction of the battery 7 by the trend prediction unit 25 will be described later in detail using a graph.

  Then, the trend prediction value obtained by the trend prediction is recorded in the nonvolatile storage unit 24 while being updated (step S49). The data recorded here is not limited to the trend prediction value, and trend prediction data including a trend prediction value to be described later is recorded. In addition, when the trend prediction value is corrected, the trend prediction value after correction is also recorded.

  Then, when there is a communication such as an inquiry about a predicted trend value from the basic processing device controller 10, the uninterruptible power supply control unit 8 answers the predicted trend value for the communication. .

  In contrast, in the basic processing device 4, when uninterruptible power supply control software (also referred to as UPS control software), which will be described later, is activated, the basic processing device control unit 10 causes the uninterruptible power supply control unit 8 to predict the trend. A data request is transmitted (step S53).

  When the uninterruptible power supply control unit 8 acquires a trend prediction data request from the basic processing unit control unit 10, the uninterruptible power supply control unit 8 transmits various data including the trend prediction value recorded in the nonvolatile storage unit 24 as trend prediction value data ( In step S55), the basic processing device control unit 10 acquires the various data.

  Thereby, the basic processing device control unit 10 can display a warning popup and a countermeasure on the display unit 23 when the acquired trend prediction value includes NG data, and display a warning or the like to the user. (Step S57).

  The uninterruptible power supply control software (that is, UPS control software) will be described below using a flowchart.

  FIG. 8 is a flowchart when the UPS control software is activated.

  First, the basic processing device controller 10 activates UPS control software (step S71).

  Then, the basic processing device control unit 10 acquires various data including the trend prediction value from the uninterruptible power supply control unit 8 of the uninterruptible power supply 3 (step S73).

  Then, the basic processing device control unit 10 determines whether or not there is NG data in the trend prediction value (step S75), and if there is NG data (YES in step S75), the warning pop-up / handling method or the like is used. NG data is displayed (step S77).

  On the other hand, when there is no NG data in the trend predicted value (NO in step S75), the process proceeds to step S79.

  Next, the basic processing device control unit 10 determines whether or not there is a display request for displaying the trend prediction value (step S79). If there is a trend prediction value display request (YES in step S79). ), The trend prediction value is displayed (step S81).

  On the other hand, when there is no display request for displaying the trend prediction value (NO in step S79), the process proceeds to step S83.

  In addition, when there is a status display request or an operation request for the uninterruptible power supply 3 (YES in Step S83), the basic processing device control unit 10 displays various data including a trend prediction value as a UPS status display, An operation operation is received, and an operation for correcting the trend prediction value is received by the uninterruptible power supply control unit 8 via serial communication (step S85).

  On the other hand, when there is no status display request or operation request for the uninterruptible power supply 3 (NO in step S83), the process proceeds to step S87.

  In step S87, the basic processing device control unit 10 waits for an end operation by the user. When the operation is ended by an operation button or a mouse operation (YES in step S87), the processing ends.

  On the other hand, if not finished yet (NO in step S87), it is determined that the user is willing to operate the basic processing device controller 10, and the process returns to step S73.

  In addition, when a user corrects manually based on trend prediction data in step S85, it records as an update of the prediction information in step S49 shown in FIG.

  Next, the trend prediction in step S47 shown in FIG. 7 will be described in detail using a graph.

  FIG. 9 is a graph when the trend prediction satisfies the various conditions as a result of the trend prediction unit 25 performing the trend prediction. Here, a process of setting a battery life prediction value that satisfies various conditions from the trend prediction value will be described.

  First, the trend prediction unit 25 calculates the life of the battery 7 as the life prediction from the power value measured by the load measurement mechanism unit 21. Then, from the calculated lifetime prediction of the battery 7 and the load value measured by the load measuring mechanism unit 21, battery postponement time prediction data at the time of power failure is calculated.

  In addition, the trend prediction unit 25 generates time measurement data from the time required for the load measurement mechanism unit 21 to shut down the basic processing device 4.

  Then, the approximate lifetime of the battery 7 is predicted as TGOOD1 from the intersection of the decrease prediction line that is the aging behavior of the battery grace time prediction data and the increase prediction line of the aging behavior of the time measurement data required for the shutdown. The shutdown time when the operation time is TGOOD1 is tgood1.

  In this case, if the battery life prediction value is an operation time equal to or less than TGOOD1 and is set so as to satisfy the interval between the time measurement data required for the shutdown time and the battery grace time prediction data, It is determined that there is no problem.

  For example, the current battery life prediction value point B has an operating time shorter than TGOOD 1 and is between point F and point D, so that the battery postponement time prediction data and the time measurement data are satisfied. It is judged that there is no problem.

  Further, in the present embodiment, the battery life prediction value can be corrected as appropriate, and the decrease prediction line of the aging behavior of the battery grace time prediction data and the increase prediction line of the aging behavior of the time measurement data required for the shutdown. Thus, the approximate life time of the battery 7 can be calculated periodically, and the predicted battery life value can be corrected and set.

  In this case, the process for correcting the battery life prediction value may be automatic or manual, and the battery life prediction value is determined based on the aging behavior of the time measurement data and the aging behavior of the battery grace time prediction data. May be set so as to satisfy the above-described calculated condition predicted from the above.

  Further, the state determined to have no problem is a state in which a point B in which the line segment AB and the line segment CD do not intersect and the line segment AB and the line segment EF do not intersect is set from the graph of FIG. In other words.

  When it is determined that there is no problem by the trend prediction, the following various times are stored in the first magnetic storage unit 14 via the basic processing device control unit 10.

(1) tgood2: Estimated time required for the shutdown process at the time of battery life (that is, the shutdown time at point D)
(2) TGOOD: Operating time at which the battery grace time prediction data at the time of a power failure becomes the current shutdown time setting value (that is, the operating time at point F)
(3) TGOOD1 and tgood1: Time required for shutdown The time required for shutdown and the time required for the shutdown process at the intersection of the rise line of the actual measurement data and the battery delay time prediction data drop prediction line at the time of power failure (the above mentioned approximate lifetime) .)

  Next, the state when the deterioration of the battery 7 has progressed as a result of trend prediction will be described.

  FIG. 10 is a graph illustrating that the deterioration of the battery 7 is progressing as a result of the trend prediction unit 25 performing the trend prediction. Here, a conditional expression for determining the deterioration of the battery 7 is shown in the following expression.

  TNG10 <Battery life prediction value (1)

  FIG. 10 shows that the battery lowering time prediction data at the time of a power failure has a lower right lowering and the shutdown time of the battery 7 is earlier.

  Therefore, as a provisional measure in this case, it is possible to avoid the operation time until the operating time reaches TNG11 by correcting the value of the shutdown time from the current set value to tng11.

  Therefore, it is recommended to deal with the deterioration of the battery 7 by replacing the battery 7 or inspecting the uninterruptible power supply 3 before reaching TNG 11.

  The state in which it is determined that the deterioration of the battery 7 is in progress is based on the graph in FIG. In other words, it is time.

  And when it determines with deterioration of the battery 7 progressing by trend prediction, the following various time is preserve | saved in the 1st magnetic memory | storage part 14 via the basic processing apparatus control part 10. FIG.

(1) TNG10: Operating time at the point where the battery grace time prediction data at the time of power failure becomes the current shutdown time setting value (2) tng12: Predictive time required for the shutdown process at the time of battery life (that is, the shutdown time at point J) is there.)
(3) TNG 11 and tng 11: Time required for shutdown and the time required for shutdown processing at the point where the rise prediction line of the actual measurement data intersects the battery delay time prediction data drop prediction line at the time of power failure (the above-mentioned approximate lifetime) .)

  Next, a case where the shutdown time has rapidly increased as a result of trend prediction will be described.

  FIG. 11 is a graph showing that the shutdown time has increased rapidly as a result of the trend prediction unit 25 performing the trend prediction. Here, a conditional expression for determining a rapid increase in the shutdown time is shown in the following expression.

  tng22> current set value (2)

  This indicates that the upper right corner of the time measurement data required for the shutdown becomes stronger and the shutdown time of the basic processing device 4 is longer than usual.

  Therefore, as a provisional correspondence in this case, it is possible to avoid the operation time until the operating time reaches TNG21 by performing a correction for changing the shutdown time from the current set value to tng21.

  Therefore, it is recommended to stop unnecessary services and distribute the load to other processing information devices before becoming TNG 21.

  Further, from the graph of FIG. 11, the state where the shutdown time is determined to be abruptly increased is that the operating time (TNG21) at the point where the line segment MN and the line segment PQ intersect is shorter than the predicted battery life. In other words, it can be said.

  Then, when it is determined that the shutdown time has increased rapidly by trend prediction, the following various times are stored in the first magnetic storage unit 14 via the basic processing device control unit 10.

(1) TNG20: Operating time at which the actual measurement data required for shutdown becomes the current shutdown time setting value (2) tng22: Estimated time required for shutdown processing at the time of battery life (that is, the shutdown time at point Q) .)
(3) TNG21 and tng21: the time required for the shutdown process and the time required for the shutdown process at the point where the estimated increase line of the actual measurement data intersects with the battery delay time prediction data decrease prediction line at the time of power failure (the above mentioned approximate lifetime) .)

  9, 10, and 11, the model that performs trend prediction using linear prediction is described, but this embodiment is not limited to this, and a sudden change in data amount or temperature rise is described. In consideration of the case where the battery deterioration is accelerated at the same time, nonlinear trend prediction may be applied.

  In that case, it is obvious that the gist of the present invention is not impaired even when each actually measured value rises or falls uniformly (that is, when the trend prediction is a monotone function).

  As described above, according to the present embodiment, the uninterruptible power supply system 1 predicts the life of the battery 7 included in the uninterruptible power supply device 3 with high accuracy by measuring the load with the load measurement mechanism unit 21. The basic processing device 4 can be appropriately protected.

  In addition, according to the present embodiment, not only can the load be measured during the shutdown process of the basic processing device 4, but also the life expectancy of the battery 7 can be predicted using a virtual load after a certain period of time has elapsed. Prediction accuracy is improved.

  As mentioned above, although embodiment of this invention was described with reference to drawings, these are the illustrations of this invention, Various structures other than the above are also employable.

  For example, since the uninterruptible power supply system 1 is configured to include the timer unit 26 in the uninterruptible power supply device 3, a shutdown time may be set by the timer unit 26 and the shutdown time may be automatically increased or decreased. .

  In this case, it can be realized by notifying the set shutdown time in step S13 in FIG. 3, and when the uninterruptible power supply controller 8 has set the shutdown set time, the power to the basic processing device 4 is supplied. The supply should be cut off.

  Thereby, the uninterruptible power supply 3 can set the shutdown set time without depending on the processing load of the basic processing device 4.

  Further, when the uninterruptible power supply control unit 8 cuts off the power supply to the basic processing device 4, it determines whether or not the power value exceeds a certain value (standby power value of the basic processing device) and records it. May be provided.

  And by adding a process to determine whether or not the shutdown process was in progress, even if the server could not be started due to OS (Operating System) program destruction, refer to the log of the uninterruptible power supply later By doing so, it becomes possible to investigate the cause.

It is the block diagram which showed the structure of the uninterruptible power supply system which concerns on this Embodiment. It is a functional block diagram of the uninterruptible power supply concerning this embodiment. It is the sequence diagram which showed the whole operation | movement of the uninterruptible power supply system which concerns on this Embodiment. It is the sequence diagram which showed the operation | movement of the schedule shutdown of the uninterruptible power supply system which concerns on this Embodiment. It is the flowchart which showed the independent operation | movement of the uninterruptible power supply which concerns on this Embodiment. It is the flowchart which showed the single operation | movement of the basic processing apparatus which concerns on this Embodiment. It is the sequence diagram which showed the operation | movement of the trend prediction which the trend prediction part which concerns on this Embodiment performs. It is a flowchart when starting up the UPS control software according to the present embodiment. It is the figure which showed the graph at the time of performing the trend prediction which the trend prediction part which concerns on this Embodiment performs. It is the figure which showed the graph of the operation | movement in which the trend prediction part which concerns on this Embodiment performed trend prediction, and battery deterioration advanced. It is the figure which showed the graph when the trend prediction part which concerns on this Embodiment performs trend prediction, and the shutdown time is increasing rapidly.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Uninterruptible power supply system 2 Current / voltage source 3 Uninterruptible power supply 4 Basic processing unit 5 AC-DC converter 6 DC-AC inverter 7 Battery 8 Uninterruptible power supply control unit 9 Virtual load unit 10 Basic processing unit control unit 11 Memory Unit 12 first extended storage unit 13 second extended storage unit 14 first magnetic storage unit 15 second magnetic storage unit 16 third magnetic storage unit 17 nonvolatile storage unit 18 basic processing device monitoring unit 19 basic processing device control unit primary battery DESCRIPTION OF SYMBOLS 20 Power supply part 21 Load measurement mechanism part 22 Timing part 23 Display part 24 Nonvolatile memory | storage part 25 Trend prediction part 26 Timer part 31 Power load measurement part 32 Power value recording part 33 Virtual load lifetime prediction part

Claims (19)

A power management system comprising an uninterruptible power supply capable of supplying power by a battery at the time of a power failure, and an information processing device receiving power supply from the uninterruptible power supply by the battery,
The information processing apparatus includes:
Comprising a shutdown means for stopping the processing in operation and terminating the use of the information processing apparatus;
The uninterruptible power supply is
The power value to be supplied to the information processing apparatus and the load on the information processing apparatus until the shutdown process of the information processing apparatus stops the operation of the information processing apparatus and ends the use of the information processing apparatus Power load measuring means for measuring the value,
Power value recording means for recording the power value of the information processing apparatus measured by the power load measuring means;
Trend predicting means for predicting a grace time that the battery can be used from the power value recorded by the power value recording means and the load value measured by the power load measuring means;
A power management system comprising: The trend prediction means includes
From the power value recorded by the power value recording means, the life of the battery is calculated as a life prediction, and from the battery life prediction and the load value measured by the power load measuring means, a battery grace time prediction is calculated. The power management system according to claim 1, wherein the power management system calculates data and predicts a grace period in which the battery can be used. The trend prediction means includes
The time until the use of the information processing device is terminated is measured by the power load measuring means, and time actual measurement data is generated from the time obtained by the measurement,
3. The power management system according to claim 2, wherein an approximate life time of the battery is predicted based on an aging behavior predicted from the battery grace time prediction data and an aging behavior of the generated time measurement data. . The trend prediction means includes
Predicting the intersection point of the operation time, which is derived from the aging behavior predicted from the battery grace time prediction data and the aging behavior predicted from the generated time actual measurement data, as the approximate life time of the battery. The power management system according to claim 3. The trend prediction means includes
The power management system according to claim 4, wherein a predicted life value of the battery is determined from the predicted approximate life time of the battery. The trend prediction means includes
The estimated battery life value is
It is a time that exceeds the shutdown time of the time measurement data predicted by the aging behavior, and is less than or equal to the grace time of the battery grace time prediction data predicted by the aging behavior, and from the estimated approximate lifetime The power management system according to claim 5, wherein the power management system is determined to be correctable from a short operating time. The shutdown means includes
The operation of the information processing apparatus is stopped and the use of the information processing apparatus is terminated at the time of a power failure notification from the uninterruptible power supply or a schedule shutdown by the information processing apparatus. The power management system described in the section. The uninterruptible power supply is
A virtual load life diagnosis means for diagnosing the estimated life of the battery by a virtual load when the power value and the load value are not measured by the power load measurement means for a predetermined period;
The trend prediction means includes
Use of the battery from the power value recorded by the power value recording means, the load value measured by the power load measuring means, and the estimated life of the battery diagnosed by the virtual load life diagnosis means The power management system according to any one of claims 1 to 7, wherein a possible grace period is predicted. An uninterruptible power supply that can be powered by a battery in the event of a power failure,
The power value supplied to the information processing device and the load on the information processing device until the information processing device connected to the uninterruptible power supply is stopped and the use of the information processing device is terminated. Power load measuring means for measuring the value,
Power value recording means for recording the power value of the information processing apparatus measured by the power load measuring means;
Trend predicting means for predicting a grace time that the battery can be used from the power value recorded by the power value recording means and the load value measured by the power load measuring means;
An uninterruptible power supply characterized by comprising: A power management method in a power management system comprising an uninterruptible power supply capable of supplying power by a battery at the time of a power failure, and an information processing device receiving power supply from the uninterruptible power supply by the battery,
A shutdown step in which the information processing apparatus stops an active process and ends use of the information processing apparatus;
In the shutdown step, the uninterruptible power supply device stops the process during operation of the information processing device and ends the use of the information processing device and the power value supplied to the information processing device and the information processing device A power load measuring step for measuring the load value of
The uninterruptible power supply apparatus records the power value of the information processing apparatus measured in the power load measuring step, and a power value recording step,
A trend prediction step in which the uninterruptible power supply apparatus predicts a grace time that the battery can be used from the power value recorded in the power value recording step and the load value measured in the power load measurement step; ,
A power management method comprising the steps of: The trend prediction step includes:
From the power value recorded in the power value recording step, the life of the battery is calculated as a life prediction, and from the life prediction of the battery and the load value measured in the power load measurement step, a battery grace time prediction is calculated. The power management method according to claim 10, wherein data is calculated to predict a grace period in which the battery can be used. The trend prediction step includes:
The time until the use of the information processing device is terminated is measured in the power load measuring step, and from the time obtained by the measurement, time actual measurement data is generated,
12. The power management method according to claim 11, wherein the approximate life time of the battery is predicted based on the aging behavior predicted from the battery grace time prediction data and the aging behavior of the generated time measurement data. . The trend prediction step includes:
Predicting the intersection point of the operation time, which is derived from the aging behavior predicted from the battery grace time prediction data and the aging behavior predicted from the generated time actual measurement data, as the approximate life time of the battery. The power management method according to claim 12. The trend prediction step includes:
The power management method according to claim 13, wherein a predicted life value of the battery is determined from the predicted approximate life time of the battery. The trend prediction step includes:
The estimated battery life value is
It is a time that exceeds the shutdown time of the time measurement data predicted by the aging behavior, and is less than or equal to the grace time of the battery grace time prediction data predicted by the aging behavior, and from the estimated approximate lifetime The power management method according to claim 14, wherein correction is determined from a short operating time. The shutdown step includes
16. The system according to claim 10, wherein when the power failure is notified from the uninterruptible power supply device or when the information processing device is scheduled to shut down, the operation is stopped and the use of the information processing device is terminated. The power management method described in the section. The uninterruptible power supply is
A virtual load life diagnosis step of diagnosing the estimated life of the battery by a virtual load when the power value and the load value are not measured in the power load measurement step for a predetermined period;
The trend prediction step includes:
Using the battery from the power value recorded in the power value recording step, the load value measured in the power load measurement step, and the estimated life of the battery diagnosed in the virtual load life diagnosis step The power management method according to any one of claims 10 to 16, wherein a possible grace period is predicted. A power supply trend prediction method in an uninterruptible power supply capable of supplying power from a battery in the event of a power failure,
The power value supplied to the information processing device and the load on the information processing device until the information processing device connected to the uninterruptible power supply is stopped and the use of the information processing device is terminated. A power load measuring step for measuring a value;
A power value recording step for recording the power value of the information processing apparatus measured in the power load measuring step;
A trend prediction step of predicting a grace time that the battery can be used from the power value recorded in the power value recording step and the load value measured in the power load measurement step;
The power supply trend prediction method characterized by including this. A power supply trend prediction program for an uninterruptible power supply that can supply power from a battery during a power failure,
The power value supplied to the information processing device and the load on the information processing device until the information processing device connected to the uninterruptible power supply is stopped and the use of the information processing device is terminated. Power load measurement procedure to measure the value,
A power value recording procedure for recording the power value of the information processing apparatus measured by the power load measurement procedure;
A trend prediction procedure for predicting a grace time for the battery from the power value recorded by the power value recording procedure and the load value measured by the power load measurement procedure;
A power trend prediction program characterized by causing a computer to execute.

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