JP6014986B2 - Power control system, power control method, and power control program - Google Patents

Description

  The present invention relates to a power control system, a power control method, and a power control program, and in particular, it is possible to start a plurality of servers at the earliest possible timing without stopping power supply by a battery during server startup. The present invention relates to a power control system, a power control method, and a power control program.

  In general, it is known that a server has a characteristic that the required power amount at the time of startup becomes maximum and the required power amount decreases when the initialization process or the like is completed. In particular, a server system in which a plurality of servers are mounted requires a large amount of power at startup.

  On the other hand, there is a known measure of adding a power supply unit, but there is a problem that a cost for purchasing the power supply unit is high. Further, surplus power is generated after the initialization process, which is not efficient.

  In addition, a method of providing a time difference in the timing of starting the server is known, but there is a problem that it takes time from system startup to service provision.

  Further, as a related technique, a technique is known in which when a large amount of power is required at the time of starting the system, the battery is temporarily discharged to supplement the power. For example, Patent Document 1 includes a battery that serves as a power supply source such as a controller when the power generation capacity is low before and after the start of the fuel cell, and is charged with the power generated by the fuel cell when the power generation capacity of the fuel cell is sufficient. A system is disclosed.

JP2003-168464A

  However, the time that the battery can be discharged is limited, and if the battery outputable time has passed before the power can be supplied to the server with only the power supply unit, the power supply by the battery stops during the server startup. There is a problem of doing.

  An object of the present invention is to provide a power control system, a power control method, and a power control program capable of starting a plurality of servers at the earliest possible timing without stopping power supply by a battery during server start-up. There is to do.

  The power control system of the present invention controls a power supply unit that supplies power to a load, a battery that supplies insufficient power to the load when power supplied from the power supply unit is insufficient, and the load, power supply unit, and battery And a storage unit that stores power consumption characteristic information that is information indicating the power consumption characteristic of the load, and the control unit controls the power output timing of the battery based on the power consumption characteristic information. And

  The power control method according to the present invention includes a control step for controlling a load, a power supply unit that supplies power to the load, and a battery that supplies insufficient power to the load when power supplied from the power supply unit is insufficient, and power of the load And storing power consumption characteristic information, which is information indicating the consumption characteristic, in a storage unit. In the control step, the power output timing of the battery is controlled based on the power consumption characteristic information.

  The power control program of the present invention controls a computer, a power supply unit that supplies power to the load, and a battery that supplies insufficient power to the load when power supplied from the power supply unit is insufficient, Storing the power consumption characteristic information, which is information indicating the power consumption characteristic of the load, in the storage means, and in the control step, the timing of the power output of the battery is controlled based on the power consumption characteristic information. And

  The present invention has an effect that a plurality of servers can be started at the earliest possible timing without stopping the power supply by the battery in the middle of starting the server.

1 is a block diagram showing a power control system 100 in a first embodiment of the present invention. It is a figure which shows the server state table. 5 is a diagram showing a power information table 300. FIG. It is a figure which shows the power consumption characteristic information. It is the image figure after the synthesis | combination of the line graphs 401-403 which show the power consumption characteristic of the blade servers 107-109. 3 is a flowchart showing the operation of the power control system 100. It is a block diagram which shows the power control system 100 in the 2nd Embodiment of this invention. It is a figure which shows the server state table. It is a figure which shows the power consumption characteristic information 900. FIG. It is an image figure after the synthesis | combination of the line graphs 401-403 which show the power consumption characteristic of the blade servers 107-110.

Next, embodiments of the present invention will be described in detail with reference to the drawings.
(First embodiment)
FIG. 1 is a block diagram showing a power control system 100 according to the first embodiment of the present invention.

  The power control system 100 of the present invention includes power supply units 101 to 103, a battery 104, a control unit 105, a storage unit 106, and servers 107 to 110 as loads. In the present embodiment, an explanation is given using an uninterruptible power supply (UPS) as an example of the battery 104. Further, a description will be given using a blade server as an example of the servers 107 to 110. In this embodiment, a server is used as an example of a load. However, the present invention is not limited to this, and a storage or the like may be used.

  The control means 105 is a processor such as a CPU (Central Processing Unit), but is not limited to this. The CPU executes programs stored in the storage means 106 described later, and realizes various functions of the control means 105.

  The power supply units 101 to 103 supply power to the blade servers 107 to 110.

  The storage unit 106 stores a server state table 200, a power information table 300, power consumption characteristic information 400, and a program (not shown) executed by the control unit. The storage means 106 is a memory such as a flash memory, but is not limited to this.

  FIG. 2 shows the server state table 200. The server status table 200 includes information indicating the power status of each of the blade servers 107 to 110, information indicating power required for startup (startup power), and information indicating the startup time. In this embodiment, the power of the blade servers 107 to 109 is ON, and the power of the blade server 110 is OFF. The activation power of each of the blade servers 107 to 110 is 200 (W). The activation time of each blade server is 13:00. The contents of the server state table 200 are not limited to this embodiment.

  FIG. 3 shows the power information table 300. The power information table 300 includes information indicating the power that can be output from the power supply units 101 to 103 and the UPS 104. In the present embodiment, the output power of each of the power supply units 101 to 103 and the UPS 104 is described as 200 (W), but the present invention is not limited to this. The power information table 300 also includes information on the output possible time of the UPS 104. In the present embodiment, the output possible time of the UPS 104 is 3 minutes, but is not limited to this.

  The control unit 105 accesses the storage unit 106 and acquires information included in the server state table 200 and the power information table 300.

  FIG. 4 shows power consumption characteristic information 400. The power consumption characteristic information 400 is information indicating the power consumption characteristics of the blade servers 107 to 110.

  401 is a line graph showing the power consumption characteristics of the blade server 107. Reference numeral 402 denotes a line graph showing the power consumption characteristics of the blade server 108. Reference numeral 403 is a line graph showing the power consumption characteristics of the blade server 109. Reference numeral 404 is a line graph showing the power consumption characteristics of the blade server 110.

  In the present embodiment, each of the blade servers 107 to 110 sends information indicating the power consumption characteristics of the own blade server to the storage unit 106 when the own blade server is activated. Therefore, in this embodiment, it is assumed that only the line graphs 401 to 403 are described in the power consumption characteristic information 400 stored in the storage unit 106, and the line graph 404 is not described. Note that the timing at which each blade server 107 to 110 sends information indicating the power consumption characteristics of its own blade server to the storage unit 106 is not limited to this.

  The control unit 105 controls the power supply units 101 to 103, the UPS 104, and the blade servers 107 to 110. When the control unit 105 receives information indicating the power that can be output from the power supply units 101 to 103 and the UPS 104 from the power supply units 101 to 103 and the UPS 104, the control unit 105 updates the power state table 200. In addition, when the control unit 105 receives information indicating the power state, the starting power, and the starting time from the blade servers 107 to 110, the control unit 105 updates the server state table 200.

  In the present embodiment, the power information table 300 is described as being stored in the storage unit 106 in advance, but the present invention is not limited to this. Also, in the present embodiment, description will be made on the assumption that information (power status, startup power, startup time information) related to the server status table 200 is transmitted to the control means 105 when the blade servers 107 to 110 are started. It is not limited. For example, when there is a blade server that is turned off or the UPS is turned on, the control unit 105 acquires information about the server status table 200 and information about the power information table 300 from each of the blade servers 107 to 110. Such a configuration may be adopted.

  Based on the power consumption characteristic information 400, the control unit 105 calculates the timing at which the UPS 104 should be turned on. Hereinafter, a case where the blade server 110 is desired to be activated while the blade servers 107 to 119 are activated by the power supply units 101 to 103 will be described. It is assumed that the UPS 104 has electric power (200 (W)) necessary for starting the blade server 110 and is charged so that it can output for 3 minutes.

  First, the control unit 105 synthesizes a line graph indicating the power consumption characteristics of the blade servers 107 to 109 that are already running. FIG. 5 shows an image diagram after combining line graphs 401 to 403 indicating the power consumption characteristics of the blade servers 107 to 109. Reference numeral 500 denotes a line graph after the line graphs 401 to 403 are combined.

  Next, the control unit 105 calculates a time (A) at which it is predicted that power for turning on the blade server 110 that has not been activated can be secured only by the power supply units 101 to 103.

  Specifically, the time when the line graph of FIG. 5 falls to the threshold value is calculated. The threshold value is a value obtained by subtracting the power consumption of the active blade server from the power that can be supplied by all the power supply units.

  In this embodiment, the threshold is 400W. This is because the power supply units 101 to 103 can supply a maximum of 600 W of power, and the power consumption of the blade server 111 that has not yet been activated is 200 W. The fact that the power consumption of the already activated blade servers 107 to 109 has decreased to 400 W means that the power supply units 101 to 103 can further supply 200 W of power.

  In this embodiment, as shown in FIG. 5, the combined line graph reaches the threshold value of 400 W at 13:05. Therefore, time (A) is 13:05.

  Next, the control means 105 calculates the time (B) at which the UPS 104 should be turned on. Time (B) is the time obtained by subtracting the UPS 104 possible output time from time (A). In the present embodiment, it is determined that time (B) is 13:02 after subtracting 3 minutes, which is a possible output time. The control unit 105 determines that power can be continuously supplied to the blade server 110 if power supply to the blade server 110 by the UPS 104 is started at 13:02. This is because the UPS 104 can supply power to the blade server 110 from 13:02 to 13:05, and the power supply units 101 to 103 can supply power to the blade server 110 after 13:05.

  In the present embodiment, the power supply by the power supply units 101 to 103 is started at the same time when the power supply to the blade server 110 by the UPS 104 is stopped, but the power supply time by the UPS 104 and the power supply units 101 to 103 are started. The power supply time may be slightly overlapped. That is, the UPS 104 may start supplying power between time (B) and time (A).

  FIG. 6 is a flowchart showing the operation of the power control system 100 in the present embodiment.

  The control unit 105 acquires state information from the power supply units 101 to 103, the UPS 104, and the blade servers 107 to 110 (step S601). The state information includes a server state table 200, a power information table 300, and power consumption characteristic information 400.

Next, when acquiring the state information, the control unit 105 determines whether or not all the blade servers 107 to 110 are powered on (step S602). When all the blade servers 107 to 110 are powered on, the control unit 105 determines whether the UPS 104 is powered on (step S603). When the UPS 104 is turned on, the control unit 105 determines whether or not the power supply units 101 to 103 can supply power even when the UPS 104 is turned off (step S604). If it is determined that the power can be supplied only by the power supply units 101 to 103 even if the UPS 104 is turned off, the control unit 105 turns off the UPS 104 (step S605).

  If it is determined in S602 that all blade servers are not powered on, the control unit 105 determines whether power can be supplied only by the power supply units 101 to 103 in order to power on the blade servers that are powered off. Is determined (step S606). If it is determined in S606 that power can be supplied, the control unit 105 turns on the blade server that is turned off using the power supply units 101 to 103, and records the time in the server state table 200 (step S607). ). Then, the control unit 105 determines whether the power of the UPS 104 is on and the power is sufficient even when the power of the UPS 104 is turned off (step S608). If it is determined in S608 that the power is sufficient, the control unit 106 turns off the UPS 104 (step S609).

  If it is determined in S606 that the power supply unit 101-103 alone does not have enough power to turn on the blade server that is turned off, the control unit 105 determines whether the UPS 104 is turned off ( Step S610). When the UPS 104 is powered off, the control unit 106 calculates a time (A) at which it is predicted that the power necessary for powering on the blade server can be secured only by the power supply units 101 to 103 (step S611). Specifically, as described above, time (A) is a time at which a line graph indicating the power consumption characteristics of a blade server that is already running is combined and the combined line graph becomes a threshold value. The threshold value is a value obtained by subtracting the power consumption of the active blade server from the power that can be supplied by all the power supply units.

  Next, the control unit 105 determines that the time (B) at which the power supply of the UPS 104 should be started is the time obtained by subtracting the output available time of the UPS 104 from the time (A) (step S612). At time (B), the control means 105 turns on the UPS 104 (steps S613 and S614). The blade server that has been turned off is turned on, and the control unit 105 records the activation time of the blade server that is turned on in the server state table 200 (step S615).

  Note that the calculation method of the time (A) and the time (B) is not limited to the method described above.

  Next, the operation of the power control system 100 when the power control system 100 is in the state of the server state table 200 (FIG. 2) and the power information table 300 (FIG. 3) will be described.

  The control unit 105 acquires state information from the power supply units 101 to 103, the UPS 104, and the blade servers 107 to 110 (step S601).

  When acquiring the status information, the control unit 105 determines whether all the blade servers 107 to 110 are powered on (step S602). Since the blade servers 107 to 109 are powered on but the blade server 110 is powered off, the process advances to step S606. The control unit 105 determines whether power can be supplied only by the power supply units 101 to 103 in order to turn on the blade server 110 that is turned off (step S606). Since the power units 101 to 103 supply the power (600 (W)) necessary for starting the blade servers 107 to 109, the power units 101 to 103 have power for turning on the blade server 110. Is not left. Therefore, the process proceeds to step S610, and the control unit 105 determines whether or not the UPS 104 is turned on (step S610). Since the UPS 104 is powered off, the process proceeds to step S611. Based on the line graph in FIG. 5 (image of a composite graph of the power consumption characteristics of the blade servers 107 to 109), the control means 105 is necessary for starting the blade server 110 with only the power supply units 101 to 103. It is determined that the time (A) at which sufficient power (200 (W)) can be secured is 13:05 (step S612).

  Since the UPS 104 can output 3 minutes, the control unit 105 determines that the time when the UPS 104 should be turned on is 13:02.

  At 13:02, the control means 105 turns on the UPS 104 and the blade server 110 is turned on. Then, the control unit 105 records the activation time of the blade server 110 in the server state table 200 (step S615).

  As described above, in the present embodiment, based on the power consumption characteristic information, the control unit 105 is predicted to be able to secure the power necessary for powering on the blade server only by the power supply units 101 to 103 (A ). Then, the control unit 105 calculates the time (B) when the power output by the UPS 104 should be started based on the time (A) and the output possible time of the UPS 104. Therefore, in the present embodiment, the power supply units 101 to 103 and the UPS 104 can supply power to the server 111 continuously and at an earlier timing.

  As described above, in this embodiment, since the battery power output control is performed based on the power consumption characteristic information, a plurality of servers are connected at the earliest possible timing without stopping the power supply by the battery during the start-up of the server. It has a remarkable effect that it can be activated.

  (Supplementary Note 1) A control step for controlling a load, a power supply unit that supplies power to the load, and a battery that supplies insufficient power to the load when power supplied from the power supply unit is insufficient, and shows power consumption characteristics of the load Storing the power consumption characteristic information as information in a storage means, and in the control step, the power output timing of the battery is controlled based on the power consumption characteristic information.

  (Additional remark 2) It has the step which stores the output possible time information which is the information which shows the output possible time of a battery in a memory | storage means, The load has the power consumption characteristic that required electric power reduces after progress for a predetermined time, In the control step, based on the power consumption characteristic information and the output possible time information, the battery power output is set so that the power supply unit can supply the insufficient power when the battery output possible time has elapsed. The power control method according to appendix 1, wherein the timing is controlled.

  (Supplementary note 3) The supplementary note 2 is characterized in that, in the control step, the power output timing of the battery is controlled so that the shortage of power can be supplied by the power supply unit simultaneously with the elapse of the battery output possible time. Power control method.

  (Supplementary note 4) The load is composed of a plurality of servers, and the power consumption characteristic information is information indicating characteristics of power consumption of the entire activated server among the plurality of servers. The power output timing of the battery is controlled so that the power supply unit can supply power to the server that has not been activated when the power supply by the battery to the server that has not been activated has stopped. The power control method according to supplementary note 2 or 3, wherein

  (Supplementary Note 5) In the control step, the first time is calculated as the time when the power consumption characteristic information exceeds the threshold, the second time is calculated as the time obtained by subtracting the battery output possible time from the first time, The power control according to appendix 4, wherein the battery starts to supply power after time 2 and the threshold value is a value obtained by subtracting the power consumption of the server that has not been activated from the power that can be output from the entire power supply unit. Method.

  (Supplementary Note 6) In the control step, when the first server and the second server among the plurality of servers are not activated, the power output timing by the battery for the first server is controlled, and the first server The power control method according to appendix 5, wherein the power output timing by the battery to the second server is controlled after the power supply is started.

  (Supplementary note 7) The power supply control method according to any one of supplementary notes 1 and 6, wherein the battery is an uninterruptible power supply for supplying power during a power failure.

  (Supplementary Note 8) A control step for controlling a power supply unit that supplies power to the computer, a power supply unit that supplies power to the load, and a battery that supplies insufficient power to the load when power supplied from the power supply unit is insufficient Storing power consumption characteristic information, which is information indicating characteristics, in a storage unit, and controlling the power output timing of the battery based on the power consumption characteristic information in the control step program.

  (Supplementary Note 9) A computer is caused to execute a step of storing outputable time information, which is information indicating a battery outputable time, in a storage unit, and the load has a power consumption characteristic that a required power decreases after a predetermined time has elapsed. In the control step, based on the power consumption characteristic information and the output possible time information, the battery is set so that the power supply unit can supply insufficient power when the battery output possible time has elapsed. The power control program according to appendix 8, wherein the power output timing is controlled.

  (Supplementary Note 10) In the control step, the power output timing of the battery is controlled so that the power supply unit can supply insufficient power at the same time as the battery output possible time elapses. 9. The power control program according to 9.

  (Supplementary Note 11) The load is composed of a plurality of servers, and the power consumption characteristic information is information indicating characteristics of the power consumption of the entire activated server among the plurality of servers. In the control step, the battery output possible time is The power output timing of the battery is controlled so that the power supply unit can supply power to the server that has not been activated when the power supply by the battery to the server that has not been activated has stopped. The power control program according to appendix 9 or 10, characterized by the above.

  (Supplementary Note 12) In the control step, the first time is calculated as the time when the power consumption characteristic information exceeds the threshold, the second time is calculated as the time obtained by subtracting the battery output possible time from the first time, The power control according to appendix 11, wherein the battery starts power supply after time 2 and the threshold value is a value obtained by subtracting the power consumption of the server that has not been activated from the power that can be output from the entire power supply unit. program.

  (Supplementary Note 13) In the control step, when the first server and the second server among the plurality of servers are not activated, the power output timing by the battery with respect to the first server is controlled, and The power control program according to appendix 12, wherein the power output timing by the battery to the second server is controlled after the power supply is started.

  (Supplementary note 14) The power supply control program according to any one of supplementary notes 8 and 13, wherein the battery is an uninterruptible power supply for supplying power during a power failure.

  The present invention relates to a power control system, a power control method, and a power control program, and in particular, a plurality of loads at the earliest possible timing without stopping power supply by an auxiliary power source such as a battery in the middle of starting a load such as a server. TECHNICAL FIELD The present invention relates to a power control system, a power control method, and a power control program that can start a computer.

100 Power Control System 101-103 Power Supply Unit 104 UPS
DESCRIPTION OF SYMBOLS 105 Control means 106 Storage means 107-111 Blade server 200 Server state table 300 Power information table 400 Power consumption characteristic information 401 Line graph which shows the power consumption characteristic of the blade server 107 402 Line graph which shows the power consumption characteristic of the blade server 108 403 Blade Line graph showing power consumption characteristics of server 109 404 Line graph showing power consumption characteristics of blade server 110 500 Composite diagram of line graphs 401 to 403 700 Power control system 800 Server state table 901 Line showing power consumption characteristics of blade server 110 Graph 1000 Composite diagram of line graph 401-403 and line graph 901

Claims (7)

A power supply unit capable of supplying electric power to the first server and one activated non second server running,
A battery for supplying power to the second server ;
Control means for controlling the power supply unit and the battery;
Storage means for storing power consumption characteristic information which is information indicating the power consumption characteristic of the first server and output possible time information which is information indicating the output possible time of the battery;
When the one second server is started up, the control means passes the battery output possible time based on the power consumption characteristic information and the output possible time information to the second server . when power supply by the battery is stopped, the so power supply is turned power to possible supply state to said first server and said second server, the battery power output start timing A power control system characterized by controlling the power. At the same time that elapses possible output time of the battery, the power of claim 1, wherein said power supply unit is characterized by comprising a possible supply state power to the first server and the second server Control system.   The control means calculates a time when the power consumption characteristic information falls below a threshold as a first time, calculates a time obtained by subtracting a battery output possible time from the first time as a second time,
  The control means starts power supply by the battery after the second time,
  The power control system according to claim 2, wherein the threshold value is a value obtained by subtracting power consumption of the second server from output possible power of the entire power supply unit.   The power supply control system according to any one of claims 1 and 3, wherein the battery is an uninterruptible power supply for supplying power during a power failure.   A power supply unit for supplying power to a first server being started and one second server not being started;
  Power storage means for supplying power to the second server;
  Control means for controlling the power supply unit and the power storage means,
  When the one second server is activated, the control unit is configured to output the time that the power storage unit can output based on the power consumption characteristic information of the first server and the output time information of the power storage unit. When the power supply by the power storage means to the second server stops after a lapse of time, the power supply unit is in a state capable of supplying power to the first server and the second server. Thus, the power control system for controlling the power output start timing of the power storage means.   A control step of controlling a power supply unit that supplies power to the first server that is being activated and one second server that is not activated, and a battery that supplies power to the second server;
  Storing power consumption characteristic information, which is information indicating power consumption characteristics of the first server, and outputable time information, which is information indicating output possible time of the battery, in a storage unit;
  In the control step, when one of the second servers is started up, the output possible time of the battery has passed to the second server based on the power consumption characteristic information and the output possible time information. When the power supply by the battery stops, the power output start timing of the battery is such that the power supply unit can supply power to the first server and the second server. Is controlled, a power control method.   On the computer,
A control step for controlling a power supply unit that supplies power to a first server that is being activated and one second server that is not activated, and a battery that is to supply power to the second server;
  Storing power consumption characteristic information, which is information indicating the power consumption characteristic of the first server, and outputable time information, which is information indicating the output possible time of the battery, in a storage unit;
  In the control step, when one of the second servers is started up, the output possible time of the battery has passed to the second server based on the power consumption characteristic information and the output possible time information. When the power supply by the battery stops, the power output start timing of the battery is such that the power supply unit can supply power to the first server and the second server. Is a power control program.

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