JP2013140474A - Power source management system, power source management device, power source management method, and power source management program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To solve the problem that usage of an integrated power source may cause cost increase, and a trouble in the integrated power source itself may affect a plurality of server devices.SOLUTION: A power management system 100 includes: a server device 1 having power sources 13 and 14 which convert AC power to DC power and output it to an output line 15, and a power control unit 12 which monitors a magnitude of power output from the power sources 13 and 14, and controls operation of the power sources 13 and 14; and a server device 2 having power sources 23 and 24 which convert AC power to DC power and output it to an output line 25, and a power control unit 22 which monitors a magnitude of power output from the power sources 23 and 24, and controls operation of the power sources 23 and 24. The power control unit 22 makes prescribed communication with the power control unit 12, determines operation of the power sources of 13, 14, 23, and 24 according to the magnitude of the output power from the respective power sources of 13, 14, 23, and 24, and transmits the determined operation content to the power control unit 12.

Description

  The present invention relates to a power management system, a power management device, a power management method, and a power management program.

  In recent years, in order to cope with an increase in the amount of information processing, a situation in which a large number of server devices are used at once has been increasing. Under such circumstances, there is a tendency to pay attention to technologies for power saving in order to suppress increasing power. Especially for power supply devices that supply power for IT (Information Technology) equipment, how to reduce AC / DC conversion (AC / DC conversion) loss and build products / implementation means that enable highly efficient power supply Is a challenge.

  An example of a technique for improving power supply efficiency in a power management system including an AC / DC converter is described in Patent Document 1. As an example, the power management system described in Patent Document 1 is configured as a composite computer apparatus including a plurality of CPU modules and a plurality of AC-DC power supply units. In the power management system described in Patent Document 1, conversion is performed by selectively operating the AC-DC power supply unit based on the power-efficiency table of each AC-DC power supply unit according to the required power. Efficiency is improved.

  When considering applying the configuration described in Patent Document 1 to a computer system including a plurality of server devices, for example, a plurality of CPU modules are replaced with a plurality of server devices. In such a configuration, DC power is supplied to a plurality of server devices from a plurality of AC-DC conversion devices provided outside each server device. In other words, in a computer system using a large number of server devices, a configuration in which an integrated power supply is arranged outside and power is distributed from the integrated power supply to each server device is used. Such a configuration in which an integrated power supply is provided outside is generally considered to be able to achieve optimal power control while maintaining space efficiency and power efficiency.

Japanese Patent No. 4600609

  However, in order to arrange an integrated power supply, a large capacity power supply is inevitably required. Therefore, new problems such as higher costs and a failure of the integrated power supply itself affecting a plurality of server devices arise.

  It is an object of the present invention to provide a power management system, a power management apparatus, a power management method, and a power management program that can solve the above-described problems.

  In order to solve the above problems, the present invention converts a first power into a predetermined second power and outputs the first power on a first output line, and power on the first output line as a power source. And a first control unit that monitors the magnitude of the second power output from the first power source and controls the operation of the first power source. A second power source that converts the first power into the predetermined second power and outputs the second power on a second output line connected to the first output line, and the second power A second electrical load that operates using power on the output line as a power source, and controls the operation of the second power source by monitoring the magnitude of the second power output from the second power source. , Performing predetermined communication with the first control means, and the magnitude of the second power output from the first power source, The operation of the first power supply and the operation of the second power supply are determined according to the magnitude of the second power output from the second power supply, and the content of the determined operation is determined as the first power supply. And a second device having a second control means for transmitting to the control means.

  According to the present invention, each power source (that is, the first power source and the second power source) provided in each device (that is, the first device and the second device) can be integratedly managed by the entire power management system. It becomes possible. Therefore, it is not necessary to provide a large-capacity integrated power supply outside the apparatus.

It is a block diagram which shows the structural example of the power management system as one Embodiment of this invention. It is a block diagram which shows the structural example of the power supply control part 12 of FIG. It is a characteristic view which shows an example of power efficiency curves, such as the power supply 13 of FIG. It is a figure which shows the structural example of the power efficiency table 1222 of FIG. 3 is a flowchart for explaining an operation example of the power management system 100 of FIG. 1. FIG. 2 is an explanatory diagram for explaining an operation example of the power management system 100 of FIG. 1. FIG. 6 is an explanatory diagram for explaining another example of the operation of the power management system 100 of FIG. 1. It is a block diagram for demonstrating the basic composition of the power management system as one Embodiment of this invention.

  Hereinafter, an embodiment of a power management system according to the present invention will be described with reference to the drawings. FIG. 1 is a block diagram showing a configuration example of a power management system as an embodiment of the present invention. A power management system 100 in FIG. 1 includes a server device 1, a server device 2, a power cable 3, and a communication cable 4. The server device 1 includes a server processing unit 11, a power supply control unit 12, a power supply 13, a power supply 14, an output line 15, and a communication line 16. The power control unit 12 executes a power management agent 17 that is a program for monitoring the power supplied to the power supply 13 and the power supply 14 and managing the operation in accordance with an instruction from the user, for example.

  The server device 2 includes a server processing unit 21, a power supply control unit 22, a power supply 23, a power supply 24, an output line 25, and a communication line 26. In addition, the power control unit 22 executes a power management agent 27 that is a program for monitoring the power supplied to the power source 23 and the power source 24 and managing the operation in accordance with an instruction from the user, for example.

  The number of server devices included in the power management system 100 is not limited to two, and may be three or more. In addition, the power management agent 17 and the power management agent 27 are not configured to be executed in the power control unit 12 or the power control unit 22, but are a predetermined computer (in this case) outside the power control unit 12 or the power control unit 22. For example, a computer (not shown in the server processing unit 11 or the server processing unit 21), and the power control unit 12 and the power control unit 22 operate according to instructions from the power management agent 17 and the power management agent 27. It can also be.

  The power management agent 17 is capable of accepting designation of an arbitrary policy from an operator (operator) in addition to monitoring an operation state such as an output state of power supplied from each power source in the server device 1. It is software that is configured to include. Further, the power management agent 17 is software configured to include a function for instructing each power control unit 12 to perform an operation. Further, the power management agent 17 is represented by any power management agent 17 or 27 as a representative in addition to monitoring the power in its own server device 1, and communication between the agents can be performed for the entire server device (that is, It has a function of calculating required power (over the server device 1 and the server device 2). The power management agent 17 has a function of monitoring whether or not appropriate power is supplied to the operating loads applied to the power supplies 13, 14, 23, and 24 of the server apparatuses 1 and 2.

  Further, the power management agent 27 is configured to include a function capable of accepting designation of an arbitrary policy from an operator in addition to monitoring an operation state such as power supplied from each power source in the server device 2. Software. Furthermore, the power management agent 27 is software configured to include a function for instructing each power control unit 22 to perform an operation. Also. The power management agent 27 is represented by any power management agent 17 or 27 as a representative, in addition to monitoring the power in its own server device 2, and the entire server device (that is, the server device) is communicated between the agents. 1 and the server device 2). Further, the power management agent 27 has a function of monitoring whether or not appropriate power is supplied to the operation load applied to the power supplies 13, 14, 23, and 24 included in the server apparatuses 1 and 2. .

  In FIG. 1, a server device 1 and a server device 2 are computer devices that execute a predetermined server application or the like in response to a request from a client or the like. In the server device 1 and the server device 2, each of the server processing unit 11 and the server processing unit 21 constitutes a computer device such as a CPU (central processing unit), a main storage device, an auxiliary storage device, a communication device, and an input / output device. Contains components. Further, the server processing unit 11 and the server processing unit 21 may include a DC-DC conversion device (or a DC-DC conversion circuit) that converts DC power of a predetermined voltage into one or more types of DC power of a predetermined voltage. Good. The server processing unit 11 operates using power supplied to the output line 15 as a power source. The server processing unit 21 operates using power supplied to the output line 25 as a power source.

  Note that the server device 1 and the server device 2 have some or all of the functions of the power control unit 12, the power control unit 22, the power management agent 17, and the power management agent 27 in the server processing unit 11 and the server processing unit 21. It is also possible to realize this using a predetermined computer device. That is, the server processing unit 11 and the server processing unit 21 and a part or all of the power control unit 12 and the power control unit 22 can be integrally formed.

  The power supply 13 and the power supply 14 are power supply devices that convert AC power, such as commercial power, into DC power of a predetermined voltage and output the output power on the output line 15. The power supply 13 and the power supply 14 may output one system of DC power having a predetermined voltage, or may output a plurality of systems of DC power having different voltages, polarities, and the like. The output line 15 may be configured to include a power cable for one system, or may be configured to include a power cable for a plurality of systems. The power supply 13 and the power supply 14 have a function of measuring (or calculating) the power output to the output line 15 and transmitting the measured (or calculated) result to the power supply control unit 12 via the communication line 16. Have. The power supply 13 and the power supply 14 start (i.e. turn on) or stop (i.e. turn off) power output based on a predetermined instruction signal received from the power supply control unit 12 via the communication line 16. Or the like). Further, the power supply 13 and the power supply 14 have a function of returning data representing the maximum suppliable power based on a predetermined instruction signal received from the power supply control unit 12 via the communication line 16. Further, the power source 13 and the power source 14 may have the same capacity, or may have different capacities.

  Similarly to the power supply 13 and the power supply 14, the power supply 23 and the power supply 24 are power supply devices that convert AC power, such as a commercial power supply, into DC power of a predetermined voltage and output it on the output line 25. The power source 23 and the power source 24 may output one system of DC power having a predetermined voltage, or may output a plurality of systems of DC power having different voltages, polarities, and the like. The output line 25 may be configured to include a power cable for one system or may be configured to include a power cable for a plurality of systems. In addition, the power source 23 and the power source 24 function to measure (or calculate) the power output on the output line 25 and transmit the measured (or calculated) result to the power control unit 22 via the communication line 26. have. Further, the power source 23 and the power source 24 have a function of starting and stopping the output of power based on a predetermined instruction signal received from the power control unit 22 via the communication line 26.

  The power source 23 and the power source 24 may have the same capacity, or may have different capacities. Further, the power source 23 and the power source 24 have a function of returning data representing the maximum suppliable power based on a predetermined instruction signal received from the power control unit 22 via the communication line 26. Further, the power source 23 and the power source 24 may have the same capacity as the power source 13 and the power source 14 or may have different capacities. Further, the input power of the power source 13, the power source 14, the power source 23, and the power source 24 may be the same AC power, for example, AC powers of different systems output from different uninterruptible power supply devices or the like. Also good.

  The number of power supplies 13 and 14 and the number of power supplies 23 and 24 are not limited to two, and may be one or a plurality of three or more. Further, the power source 13, the power source 14, the power source 23, and the power source 24 may be configured so that they can be operated in parallel, that is, can receive DC outputs of the same voltage. The parallel operation method is not particularly limited, and various existing methods can be used. By configuring the power supply 13, the power supply 14, the power supply 23, and the power supply 24 so that they can be operated in parallel, power can be transferred between the server apparatuses 1 and 2 via the power cable 3 between the server apparatuses 1 and 2. . The power cable 3 is configured as a power bus (input / output) to an external device, and is connected to the server devices 1 and 2 through, for example, detachable terminals.

  The output line 15 and the output line 25 are connected via the power cable 3. The power cable 3 is composed of one or a plurality of power cables, and one or a plurality of DC outputs of the power supply 13 and the power supply 14 and one or a plurality of DC outputs of the power supply 23 and the power supply 24 for each system. Connecting.

  Next, a configuration example of the power control unit 12 illustrated in FIG. 1 will be described with reference to FIG. The power control unit 22 shown in FIG. 1 can be configured in the same manner. In the example illustrated in FIG. 2, the power control unit 12 includes a CPU 121, a nonvolatile storage device 122, a volatile storage device 123, an input / output device 124, and a communication device 125.

Here, the nonvolatile storage device 122 stores a power management agent program 1221 and a power efficiency table 1222.
The volatile storage device 123 is used as a main storage device when the CPU 121 executes the power management agent program 1221 and the like.
The input / output device 124 is an interface with a predetermined specification, and is connected to the communication line 16 connected to the power supply 13 and the power supply 14.
The communication device 125 is connected to the communication cable 4 connected to the power supply control unit 22, and transmits and receives control signals and data in a predetermined format to and from the power supply control unit 22 under the control of the CPU 121.

  The power control unit 12 executes the power management agent program 1221 by the CPU 121 to monitor the magnitude of the DC power output from the power supply 13 and the power supply 14 to the output line 15. The power control unit 12 controls the operation of the power supply 13 and the power supply 14, that is, the start (that is, on) or stop (that is, off) of the output. At that time, the power management system 100 as a whole does not determine the content of the instruction to start or stop the output of each power source, that is, the content of control, by either the power control unit 12 or the power control unit 22. One is decided on behalf.

  That is, for example, when the power control unit 12 decides on behalf of the contents of control, the power control unit 12 sets the actual supply power and the maximum supplyable power of each power supply 13, power supply 14, power supply 23, and power supply 24. Based on this, the contents of control of each power supply 13, power supply 14, power supply 23, and power supply 24 are determined. Then, the power control unit 12 transmits the details of control of the determined power source 23 and power source 24 to the power control unit 22.

  On the other hand, when the power control unit 22 decides on behalf, the power control unit 22 determines each power supply 13 based on the actual supply power and the maximum suppliable power of each power supply 13, power supply 14, power supply 23, and power supply 24. The contents of control of the power supply 14, the power supply 23, and the power supply 24 are determined. Then, the power control unit 22 transmits the determined control details of the power supply 13 and the power supply 14 to the power control unit 12. Which of the power control units 22 of the power control unit 12 performs representative processing is assigned to, for example, the power control unit 12 and the power control unit 22, and each server device 1 and server device 2 on which they are mounted. This can be determined using information indicating priority, identification numbers, address information, and the like.

  In addition, for example, when the power control unit 12 determines prior to the determination of the content of control, the power control unit 12 includes data representing the actual supply power of the power source 23 and the power source 24 and data representing the maximum suppliable power. Is obtained from the power control unit 22. On the other hand, when the power control unit 22 determines, the power control unit 22 acquires data representing the actual supply power of the power source 13 and the power source 14 and data representing the maximum suppliable power from the power control unit 12. For example, the latest value of the data representing the actual power supply is acquired every fixed period. However, the data representing the maximum power supply can be transmitted at least once to store the value. Good. In the power control unit 12 and the power control unit 22, data representing the contents of the power efficiency table 1222 (or a similar power efficiency table in the power control unit 22) in FIG. 2 is transmitted at least once.

  The configuration illustrated in FIG. 2 is an example. For example, the communication device 125 is omitted, and the power control unit 22 is used by using a communication device included in a predetermined computer device included in the server processing unit 11 in FIG. It is possible to communicate with each other.

  As illustrated in FIG. 4, the power efficiency table 1222 is information that collectively shows, for each power supply (and system), the relationship between the supplied power and the power efficiency as illustrated in FIG. 3, for example. FIG. 3 is a characteristic diagram showing an example of a power efficiency curve of the power source 13 and the like of FIG. In this characteristic diagram, the horizontal axis represents supply power (that is, DC output power), and the vertical axis represents conversion efficiency obtained from input power and output power. FIG. 4 is a diagram illustrating a configuration example of the power efficiency table 1222 of FIG. However, in FIG. 4 and the following operation examples, the power source 13, the power source 14, the power source 23, and the power source 24 output DC power of a predetermined voltage of the same one system, and their maximum suppliable power is the same. Further, description will be made assuming that the power efficiency characteristics are the same.

  The power source 13, the power source 14, the power source 23, and the power source 24 illustrated in FIG. 1 have output characteristics represented by, for example, a power efficiency curve illustrated in FIG. That is, the power source 13, the power source 14, the power source 23, and the power source 24 have a power efficiency that rises relatively rapidly as the supply power per unit time gradually increases from 0, and then gradually rises and falls. It has characteristics. On the other hand, the power efficiency table 1222a shown in FIG. 4A as an example of the power efficiency table 1222 divides the supply power on the horizontal axis of the graph of FIG. This is data in which the characteristic that the value is the efficiency value for each range is stored for each power supply identification code that is information for identifying the power supply. In the example shown in FIG. 4A, the efficiency value “x11%” in the range A corresponding to the power supply identification code representing the power supply 13 in the power efficiency table 1222a (where A and x11 are arbitrary characters or character strings). In the following, the data of the efficiency value “x12%” in the range B, the efficiency value “x13%” in the range C, and so on are set. Further, the power efficiency table 1222a includes an efficiency value “x21%” in the range A corresponding to the power supply identification code representing the power supply 14, an efficiency value “x22%” in the range B, an efficiency value “x23%” in the range C,. Each data is set. In addition, as a representative value of the efficiency of each range, the median value, average value, minimum value, and maximum value of the efficiency within the range can be used.

  Further, the power efficiency table 1222 may be configured like the power efficiency table 1222b illustrated in FIG. That is, the power efficiency table 1222 includes two power sources 13 and 14 connected to the power control unit 12 via the communication line 16 and two items connected to the power control unit 22 via the communication line 26. The power efficiency characteristics of the power source 23 and the power source 24 can be stored. The power efficiency characteristics of the power source 23 and the power source 24 are acquired and stored from the power control unit 22 by the power control unit 12 performing predetermined communication with the power control unit 22 via the communication line 4, for example. With this method, the power efficiency table 1222 such as the power efficiency table 1222b can be configured.

  In the power efficiency table 1222, data representing the maximum power that can be supplied from each power supply 13, power supply 14, power supply 23, and power supply 24 can also be stored.

Next, the operation of the power management system 100 shown in FIG. 1 will be described with reference to FIG.
The process shown in FIG. 5 is a process that is repeatedly called at predetermined time intervals, for example. First, in each server apparatus 1 and 2, the power management agents 17 and 27 mounted on each server apparatus monitor the power status of their own server apparatuses 1 and 2 (step S1). That is, the power management agent 17 transmits a predetermined instruction signal to each power supply 13 and power supply 14. Then, the power management agent 17 represents the magnitude of the supply power (ie, actual power consumption) per unit time from the power supply 13 and the power supply 14 via the communication line 16 in the actual power supply 13 and the power supply 14. Data and data representing the maximum power that can be supplied are acquired. In addition, the power management agent 27 transmits a predetermined instruction signal to each power source 23 and power source 24. Then, the power management agent 27 acquires data representing the magnitude of the actual power supply at each power supply 23 and power supply 24 and data representing the maximum suppliable power from each power supply 23 and power supply 24 via the communication line 26. To do. However, since the data representing the maximum suppliable power is a predetermined value, it is possible to omit the second and subsequent acquisition processes by acquiring at least once and storing it in a predetermined storage device. It is.

  Subsequently, the total of the actual supply power (corresponding to the sum of the power consumption) that is represented by an arbitrary power management agent and is supplied to the entire other server devices including the system itself is calculated. Then, the representative power management agent calculates the sum of the actual supply power (total power consumption) of all the server devices and calculates the sum of the maximum suppliable power of all the server devices (step S2). Here, one of the power management agents 17 and 27 representatively receives data representing the magnitude of the supplied power and data representing the maximum suppliable power from the other power management agent. The representative power management agent includes the sum of the actual supply power of each power source 13, power source 14, power source 23, and power source 24 (total power consumption) and the maximum of each power source 13, power source 14, power source 23, and power source 24. Calculate the total available power. However, similarly to the above, the data representing the sum of the maximum suppliable power can be acquired at least once and stored in a predetermined storage device, so that the second and subsequent acquisition processes can be omitted. is there.

  Next, among the power management agents 17 or 27, the power management agent calculated on behalf of the sum of the actual supply power and the sum of the maximum suppliable power in step S2 Comparison is made with a comparison criterion (assumed to be 95% or more in FIG. 5) arbitrarily set with respect to the sum of the maximum suppliable power (step S3). The comparison standard used in this step S3 is a reference value set to avoid the possibility of power shortage due to the maximum supply capacity of each power source. If this comparison standard is exceeded, power shortage It is assumed that predetermined control for avoiding occurrence of the above is attempted.

  That is, as a result of comparison in step S3, if it exceeds (in the case of “Yes” in step S3), the representative power management agent is the server server 1 or 2 that is managed by the power management system 100. It is confirmed whether or not there is a power supply in a supply stop state that can be used for replenishment of power supply (step S4). The representative power management agent instructs the start of power supply when there is a power supply in a supply stop state that can be used for replenishment (from “Yes” in step S4 to step S5). In other words, the representative power management agent or the power management agent that has received an instruction from the representative power management agent performs control for starting the supply of power from the stopped power source managed by the representative power management agent. On the other hand, when there is no power supply in a supply stop state that can be used for replenishment (in the case of “No” in step S4), the representative power management agent ends the process while maintaining the operating state. Then, the control is returned to the initial confirmation, that is, the standby state of the process of step S1.

  On the other hand, as a result of the comparison in step S3, when the total of the actual supply power is less than 95% of the total of the maximum supplyable power (in the case of “No” in step S3), the representative power management agent is Based on the actual supply power, a power efficiency value is obtained with reference to a power efficiency table (for example, the power efficiency table 1222 shown in FIG. 2). Then, the representative power management agent compares the acquired power efficiency value with the arbitrarily set power efficiency standard (step S6). Here, the arbitrarily set power efficiency standard is an arbitrarily set value that serves as a criterion for determining low-efficiency operation and high-efficiency operation, for example, as shown in FIG. As a result of the comparison in step S6, when the power efficiency value based on the actual supply power is equal to or exceeds the arbitrarily set power efficiency standard (in the case of “Yes” in step S7), the process is terminated and the initial The control is returned to the confirmation, that is, the standby state of the process of step S1.

  As a result of the comparison in step S6, when the power efficiency value based on the actual supply power is below the arbitrarily set power efficiency standard (in the case of “No” in step S7), the representative power management agent is stopped. It is confirmed whether there is a possible power source (step S8). When there is a power supply that can be stopped (“Yes” in step S8), the representative power management agent stops the supply of power from the selected power supply in an arbitrarily set order (step S8). S9). Here, when there is a power supply that can be stopped, even if the supply of power from one or a plurality of power supplies among the plurality of currently operating power supplies is stopped, the remaining power supply that has not stopped (that is, continuously) When the sum of the maximum power that can be supplied exceeds the actual power supply, and the power efficiency of the remaining power supplies that did not stop exceeds the power efficiency standard (the power efficiency is at least higher than when the power supply does not stop). I mean. In step S9, the representative power management agent or the power management agent that has received an instruction from the representative power management agent receives power from the power source selected in the order arbitrarily set by the representative power management agent. Stop supplying power.

  According to the processing of steps S3 to S9, it is determined by the representative power management agent whether power is being supplied in a state of low efficiency, and it is determined that the supply is being performed in a state of low efficiency. In such a case, an instruction to stop the surplus power supply is issued.

  In the above configuration, each power supply has a function of measuring or calculating actual supply power and outputting the measurement or calculation result to the outside in addition to a function as a normal power supply. It is only necessary to provide a function for turning the output on or off according to the control signal, and an existing power source can be used as long as it has such a function. At that time, the measured value of the actual supply power is, for example, a voltage value and a current value are measured in the power supply, and the power supply data calculated from the measurement result is transmitted from the power supply to the power management agent 17 or 27. To. Alternatively, only the data representing the current value may be transmitted, and the power management agent 17 or 27 may perform calculation processing using the rated output voltage value to obtain the power value of the supplied power. Alternatively, the power value of the supplied power may be obtained by transmitting data calculated from the input / output voltage and the switching control continuity in the power source from the power source. Information representing power may be transmitted as an analog signal instead of digital data.

  That is, according to the present embodiment, a special function is not mounted on the power source, and the capacity is not increased in realizing it. Further, in this embodiment, since the power management agents 17 and 27 are used to grasp and manage the power of the entire server, it is not necessary to request a special action for each power source. In addition, since availability is maintained only by the number of redundant power supplies inside the server device, it is not necessary to prepare a large-capacity power supply conscious of a plurality of servers, which can contribute to cost reduction. In addition, the power management agents 17 and 27 individually grasp the power situation inside a single server and notify the situation between a plurality of server devices, so that even if a temporary power shortage due to a failure occurs. There is no worry of affecting all server devices.

  In the above operation example, one system of DC power is connected in parallel by the power cable 3, but when a plurality of systems are connected in parallel by the power cable 3, the operation content of each power source is determined. For example, it can be performed as follows. That is, the sum of the actual supply power and the sum of the maximum supplyable power are performed for each system, and the maximum supplyable power and the actual supply power are compared for each system. Do processing. In addition, the power efficiency characteristics may be a combination of all systems, or a plurality of characteristics may be prepared for each system, and the total or average efficiency of each system may be compared with a reference value for each power source. The control content can be determined.

  Next, with reference to FIG. 6, as an example, an operation when the business of the server apparatus 1 is in a low load state and the required power is reduced will be described. In the example shown in FIG. 6, as shown in the upper side of FIG. 6 as the power management system 100a, each power source 13, power source 14, power source 23, and power source 24 are in operation, and each is shown by a broken line in the power efficiency characteristic diagram. Assume that the power shown is output. That is, the maximum suppliable power of the power supply 13 is M1, and the actual supplied power is A1 which is about one-fourth of M1. Similarly, the maximum suppliable power of the power source 14 is M2, and the actual supplied power is A2 which is about a quarter of M2. In addition, it is assumed that the maximum suppliable power of the power source 23 is M3 and the actual supplied power is A3, which is about a quarter of M3. The maximum suppliable power of the power supply 24 is M4, and the actual supplied power is A4, which is about a quarter of M4.

  In this case, the total power supply (A1 + A2 + A3 + A4) corresponding to the total power consumption of the server apparatus 1 and the server apparatus 2 is about one-fourth of the maximum total power supply (M1 + M2 + M3 + M4) of each power source. Therefore, the representative power management agent determines that there is a surplus in the power supplied from all the server devices, based on the communication between the agents and the total calculation. Then, the representative power management agent stops the supply of the power supply 13 through, for example, the power supply control unit (1) 12 in order to make it equal to or greater than a threshold (that is, a power efficiency standard) arbitrarily determined by referring to the power efficiency table. . By concentrating the load on the remaining power sources (the power source 14, the power source 23, and the power source 24), control is performed so that the operation is performed while maintaining high efficiency. In this example, as shown in the lower side of FIG. 6 as the power management system 100b, the power source 13 stops operating (that is, the supplied power B1 = 0), and the other power source 14, the power source 23, and the power source 24 are respectively maximum. Electric power B2 to B4 that is about one third of the suppliable electric power M2 to M4 is output.

  In this case, as the order of the power to be stopped, control is performed to preferentially turn off the power of the server apparatus having a reduced load. Even if the power supply between server devices is cut off due to human error (such as disconnecting a cable), each server device can supply power as much as possible with the mounted power supply in the disconnected server device. This is because it is necessary to maintain the power supply state. If the power of a server device whose load does not drop from a certain predetermined time is turned off, the power necessary for the server device cannot be supplied by the power in the server device. Therefore, control is performed to preferentially turn off the power of the server apparatus that has been loaded.

  Next, with reference to FIG. 7, as an example, an operation when both the server apparatus 1 and the server apparatus 2 are in a low-load operation and the required power is reduced will be described. In the example shown in FIG. 7, as shown in the upper side of FIG. 7 as the power management system 100c, each power source 13, power source 14, power source 23, and power source 24 are in operation, and the power efficiency characteristic diagram is indicated by a broken line. Assume that the power shown is output. That is, the maximum suppliable power of the power supply 13 is M1, and the actual supplied power is C1 that is about one-fourth of M1. Similarly, it is assumed that the maximum suppliable power of the power supply 14 is M2, and the actual supplied power is C2 that is about one-fourth of M2. In addition, it is assumed that the maximum suppliable power of the power source 23 is M3 and the actual supplied power is C3, which is about one-fourth of M3. The maximum suppliable power of the power supply 24 is M4, and the actual supplied power is C4, which is about a quarter of M4. In this case, the sum (C1 + C2 + C3 + C4) of the supplied power corresponding to the sum of the power consumption in the server device 1 and the server device 2 is about one-fourth of the sum of the maximum suppliable power (M1 + M2 + M3 + M4).

  In this case, the representative power management agent confirms the necessary power required for all the server apparatuses from the communication between the agents and the total calculation thereof, and then controls the supply stop of the surplus power supplies (power supply 13 and power supply 24). Are executed from each agent through the power supply control unit 12 and the power supply control unit 22. In this case, as in the previous example, assuming that the power cable 3 serving as the power supply bus between the server apparatuses 1 and 2 is disconnected from the power supply between the server apparatuses 1 and 2 due to an arbitrary human error, The server apparatus 1 and 2 must always have a policy operation in which the power supply operation is automatically determined and the power supply is stopped, thereby eliminating the risk of the power supply of each server apparatus being insufficient. . In this example, as shown in the lower side of FIG. 7 as the power management system 100d, the power supply 13 and the power supply 24 stop operating (that is, the supplied power D1 = 0 and D4 = 0), and the other power supplies 14 and 23 are , Respectively, output electric powers D2 and D3 that are about a half of the maximum suppliable electric powers M2 and M3.

  As described above, according to the embodiment of the present invention, for a system user who uses a plurality of server devices at the same time, while ensuring availability in terms of power supply without increasing costs, for example, an existing low capacity There is an effect that high-efficiency operation can be realized by a combination of power sources.

  FIG. 8 shows an aspect in which the embodiment of the power management system according to the present invention described with reference to FIG. 1 and the like is configured using basic components. That is, the power management system of the present invention includes the first device 8 and the second device 9 as basic components. Here, the first device 8 includes a first power supply 81, a first output line 82, a first electric load 83, and a first control means 84. The second device 9 includes a second power source 91, a second output line 92, a second electric load 93, and a second control means 94.

  Then, the first power supply 81 converts the first power into a predetermined second power and outputs the first power on the first output line 82. The first electrical load 83 operates using the power on the first output line 82 as a power source. The first control means 84 monitors the magnitude of the second power output from the first power supply 81 and controls the operation of the first power supply 81. The second power source 91 converts the first power into predetermined second power and outputs the second power on the second output line 92 connected to the first output line 82. The second electrical load 93 operates using the power on the second output line 92 as a power source. The second control means 94 monitors the magnitude of the second power output from the second power supply 91 and controls the operation of the second power supply 91. In accordance with the magnitude of the second power output from the first power supply 81 and the magnitude of the second power output from the second power supply 91. The operation with the power supply 91 is determined, and the content of the determined operation is transmitted to the first control means 84.

  In the above configuration, the first control unit 84 transmits the second power output from the first power source to the second control unit 94, and the second control unit 94 transmits the first power. The contents of the operation of the first power supply 81 determined by the second control means 94 are transmitted to the control means 84. Further, the operation of the first power supply 81 is controlled according to the content of the operation of the first power supply 81 determined by the first control means 84. The correspondence with the configuration shown in FIG. 1 is as follows. That is, the first device 8 corresponds to the server device 1. The second device 9 corresponds to the server device 2. The first power supply 81 corresponds to a combination of the power supply 13 and the power supply 14 or one of them. The first output line 82 corresponds to the output line 15. The first electrical load 83 corresponds to the configuration of the server processing unit 11 (the configuration of the power supply control unit 12 with further addition). The first control unit 84 corresponds to the power supply control unit 12. The second power supply 91 corresponds to a combination of the power supply 23 and the power supply 24 or one of them. The second output line 92 corresponds to the output line 25. The second electrical load 93 corresponds to the server processing unit 21 (the configuration of the power control unit 22 with further addition). The second control means 94 corresponds to the power supply control unit 22.

  The server device 1 and the server device 2 described above have a computer system inside. Each process described above is stored in a computer-readable recording medium in the form of a program, and the above process is performed by the computer reading and executing the program. Here, the computer-readable recording medium means a magnetic disk, a magneto-optical disk, a CD-ROM, a DVD-ROM, a semiconductor memory, or the like. Alternatively, the computer program may be distributed to the computer via a communication line, and the computer that has received the distribution may execute the program.

  The program may be for realizing a part of the functions described above. Furthermore, what can implement | achieve the function mentioned above in combination with the program already recorded on the computer system, what is called a difference file (difference program) may be sufficient.

  A part or all of the above embodiment is described as in the following supplementary notes, but is not limited thereto.

(Appendix 1)
A first power source that converts the first power into predetermined second power and outputs the first power on the first output line;
A first electrical load that operates using power on the first output line as a power source;
A first device comprising: first control means for monitoring the magnitude of the second power output by the first power source and controlling the operation of the first power source;
A second power source that converts the first power into the predetermined second power and outputs the second power on a second output line connected to the first output line;
A second electrical load that operates using power on the second output line as a power source;
Monitoring the magnitude of the second power output from the second power source, and controlling the operation of the second power source; performing predetermined communication with the first control means; The operation of the first power supply and the second power supply according to the magnitude of the second power output from the first power supply and the magnitude of the second power output from the second power supply. A power management system comprising: a second device having a second control unit that determines an operation and transmits the content of the determined operation to the first control unit.

(Appendix 2) The first power is AC power,
The power management system according to appendix 1, wherein the second power is DC power.

(Appendix 3)
The second control means includes: the second power output from the first power supply; the second power output from the second power supply; the first power supply; The operation for turning on or off the first power supply and the operation for turning on or off the second power supply are determined in accordance with each maximum supplyable power and each power efficiency characteristic of the second power supply. The power management system according to appendix 1 or 2, wherein

(Appendix 4)
The power supply according to any one of appendices 1 to 3, wherein at least one of the first power supply and the second power supply includes a plurality of power supply devices that input AC power and output predetermined DC power. Management system.

(Appendix 5)
A second power source that converts the first power into predetermined second power and outputs the second power on the second output line;
A second electrical load that operates using power on the second output line as a power source;
Monitoring the magnitude of the second power output from the second power source and controlling the operation of the second power source;
A first power source that converts the first power into the predetermined second power and outputs the first power on the first output line connected to the second output line, and the power on the first output line And a first control means for monitoring the magnitude of the second power output from the first power source and controlling the operation of the first power source. Perform predetermined communication with the first control means in the first device,
The operation of the first power supply and the second power supply according to the magnitude of the second power output from the first power supply and the magnitude of the second power output from the second power supply. And a second control unit for determining the operation of the first control unit and transmitting the content of the determined operation to the first control unit.

(Appendix 6)
A first power source that converts the first power into predetermined second power and outputs the first power on the first output line;
A first electrical load that operates using power on the first output line as a power source;
A first device comprising: first control means for monitoring the magnitude of the second power output by the first power source and controlling the operation of the first power source;
A second power source that converts the first power into the predetermined second power and outputs the second power on a second output line connected to the first output line;
A second electrical load that operates using power on the second output line as a power source;
Monitoring the magnitude of the second power output from the second power source, and controlling the operation of the second power source; performing predetermined communication with the first control means; The operation of the first power supply and the second power supply according to the magnitude of the second power output from the first power supply and the magnitude of the second power output from the second power supply. A second device having a second control means for determining an action and transmitting the content of the determined action to the first control means,
Transmitting the determined operation of the first power source from the second control means to the first control means;
And a step of controlling the operation of the first power supply in accordance with the content of the operation of the first power supply determined by the first control means.

(Appendix 7)
A first power source that converts the first power into predetermined second power and outputs the first power on the first output line;
A first electrical load that operates using power on the first output line as a power source;
A first device comprising: first control means for monitoring the magnitude of the second power output by the first power source and controlling the operation of the first power source;
A second power source that converts the first power into the predetermined second power and outputs the second power on a second output line connected to the first output line;
A second electrical load that operates using power on the second output line as a power source;
Monitoring the magnitude of the second power output from the second power source, and controlling the operation of the second power source; performing predetermined communication with the first control means; The operation of the first power supply and the second power supply according to the magnitude of the second power output from the first power supply and the magnitude of the second power output from the second power supply. A second device having a second control means for determining an action and transmitting the content of the determined action to the first control means,
Transmitting the determined operation of the first power source from the second control means to the first control means;
A power management program for executing, using a computer, a process of controlling the operation of the first power supply according to the content of the operation of the first power supply determined by the first control means.

100, 100a to 100d Power management system 1, 2 Server device 3 Power cable 4 Communication cable 11 Server processing unit 12 Power control unit 13 Power source 14 Power source 15 Output line 16 Communication line 17 Power management agent 21 Server processing unit 22 Power control unit 23 Power supply 24 Power supply 25 Output line 26 Communication line 27 Power management agent 1221 Power management agent program 1222 Power efficiency table

Claims (7)

A first power source that converts the first power into predetermined second power and outputs the first power on the first output line;
A first electrical load that operates using power on the first output line as a power source;
A first device comprising: first control means for monitoring the magnitude of the second power output by the first power source and controlling the operation of the first power source;
A second power source that converts the first power into the predetermined second power and outputs the second power on a second output line connected to the first output line;
A second electrical load that operates using power on the second output line as a power source;
Monitoring the magnitude of the second power output from the second power source, and controlling the operation of the second power source; performing predetermined communication with the first control means; The operation of the first power supply and the second power supply according to the magnitude of the second power output from the first power supply and the magnitude of the second power output from the second power supply. A power management system comprising: a second device having a second control unit that determines an operation and transmits the content of the determined operation to the first control unit. The first power is AC power;
The power management system according to claim 1, wherein the second power is DC power. The second control means includes: the second power output from the first power supply; the second power output from the second power supply; the first power supply; The operation for turning on or off the first power supply and the operation for turning on or off the second power supply are determined in accordance with each maximum supplyable power and each power efficiency characteristic of the second power supply. The power management system according to claim 1 or 2. 4. The power supply device according to claim 1, wherein at least one of the first power supply and the second power supply includes a plurality of power supply devices that input AC power and output predetermined DC power. 5. The described power management system. A second power source that converts the first power into predetermined second power and outputs the second power on the second output line;
A second electrical load that operates using power on the second output line as a power source;
Monitoring the magnitude of the second power output from the second power source and controlling the operation of the second power source;
A first power source that converts the first power into the predetermined second power and outputs the first power on the first output line connected to the second output line, and the power on the first output line And a first control means for monitoring the magnitude of the second power output from the first power source and controlling the operation of the first power source. Perform predetermined communication with the first control means in the first device,
The operation of the first power supply and the second power supply according to the magnitude of the second power output from the first power supply and the magnitude of the second power output from the second power supply. And a second control unit for determining the operation of the first control unit and transmitting the content of the determined operation to the first control unit. A first power source that converts the first power into predetermined second power and outputs the first power on the first output line;
A first electrical load that operates using power on the first output line as a power source;
A first device comprising: first control means for monitoring the magnitude of the second power output by the first power source and controlling the operation of the first power source;
A second power source that converts the first power into the predetermined second power and outputs the second power on a second output line connected to the first output line;
A second electrical load that operates using power on the second output line as a power source;
Monitoring the magnitude of the second power output from the second power source, and controlling the operation of the second power source; performing predetermined communication with the first control means; The operation of the first power supply and the second power supply according to the magnitude of the second power output from the first power supply and the magnitude of the second power output from the second power supply. A second device having a second control means for determining an action and transmitting the content of the determined action to the first control means,
Transmitting the determined operation of the first power source from the second control means to the first control means;
And a step of controlling the operation of the first power supply in accordance with the content of the operation of the first power supply determined by the first control means. A first power source that converts the first power into predetermined second power and outputs the first power on the first output line;
A first electrical load that operates using power on the first output line as a power source;
A first device comprising: first control means for monitoring the magnitude of the second power output by the first power source and controlling the operation of the first power source;
A second power source that converts the first power into the predetermined second power and outputs the second power on a second output line connected to the first output line;
A second electrical load that operates using power on the second output line as a power source;
Monitoring the magnitude of the second power output from the second power source, and controlling the operation of the second power source; performing predetermined communication with the first control means; The operation of the first power supply and the second power supply according to the magnitude of the second power output from the first power supply and the magnitude of the second power output from the second power supply. A second device having a second control means for determining an action and transmitting the content of the determined action to the first control means,
Transmitting the determined operation of the first power source from the second control means to the first control means;
A power management program for executing, using a computer, a process of controlling the operation of the first power supply according to the content of the operation of the first power supply determined by the first control means.

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