JP7206731B2 - Derivation device, derivation method and derivation program - Google Patents

Description

The present invention relates to a method for identifying the phase of power supplied to a device.

When installing a computer device in a rack, generally, a PDU (Power Distribution Unit) is installed in the rack, and the computer device receives power from an outlet of the PDU.

In a PDU with a 3-phase, 4-wire input and a single-phase output, each phase of the three phases is connected to each outlet on the PDU's output side. One of these phases is a set of U-line and N-line among the three-phase power lines U, V and W on the input side and the neutral line N on the input side. The remaining two are the phases consisting of the V-line and N-line pairs and the phases consisting of the W- and N-wire pairs.

In that case, no current flows through the neutral wire N if the computer devices connected to the phases have the same power consumption for the phases. However, if the power consumption of each phase does not match, the current associated with the surplus power of the group with the smaller power consumption flows through the neutral line N as an unbalanced current, wasting power. This means that when the input side is a three-phase four-wire system and the output side is a single phase, if the power consumption difference between the phases is large, the power efficiency will decrease.

To solve this problem, one common practice is to equalize the number of computer devices connected to each phase outlet.

Also, Patent Literature 1 discloses a method for dynamically balancing the power consumption of each phase.

JP 2016-158374 A

However, in order to equalize the number of computer devices connected to each phase outlet, it is necessary for a person to visually confirm the number of computer devices connected to each phase. Especially in the case of a large-scale system, the confirmation is difficult, and there is a possibility that confirmation errors may occur.

Moreover, the method disclosed in Patent Document 1 requires a person to manually set information indicating which phase each computer device is connected to. Especially in the case of a large-scale system, such setting is difficult, and setting errors may occur.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a derivation device or the like that facilitates identification of the phase of power supplied to a device.

The derivation device of the present invention comprises: a transmitting unit that transmits instruction information to a predetermined operating device; and a derivation unit for deriving from the change in power phase information representing the phase in the single-phase power being supplied to each of the operating devices. wherein the level and/or the source of single-phase power for each of the operating devices is changed based on the indication information.

The derivation device or the like of the present invention facilitates identification of the phase of the supply power supplied to the device.

1 is a conceptual diagram showing a configuration example of a system according to a first embodiment; FIG. 2 is a conceptual diagram showing a configuration example of a PDU (Power Distribution Unit) 130; FIG. 1 is a conceptual diagram showing a configuration example of a computer device according to a first embodiment; FIG. 4 is a conceptual diagram showing a first processing flow example of processing performed by a processing unit of the management device of the first embodiment; FIG. FIG. 7 is a conceptual diagram showing a second processing flow example of processing performed by the processing unit of the management device of the first embodiment; FIG. 11 is a conceptual diagram showing a third processing flow example of processing performed by the processing unit of the management device of the first embodiment; It is a conceptual diagram showing the structural example of the system of 2nd embodiment. It is a conceptual diagram showing the structural example of the computer apparatus of 2nd embodiment. FIG. 11 is a conceptual diagram showing an example of a processing flow of processing performed by a processing unit of a management device according to the second embodiment; 1 is a conceptual diagram showing a hardware configuration example of an information processing apparatus capable of realizing a management apparatus and a computer apparatus of each embodiment; FIG. It is a conceptual diagram showing the minimum structure of the derivation|leading-out apparatus of embodiment.

<First embodiment>
In the first embodiment, each computer device changes the power supplied to the configuration of the computer device, so that the management device identifies which of the three-phase wirings the connected wiring is. It is an embodiment relating to
[Configuration and operation]
FIG. 1 is a conceptual diagram showing the configuration of a system 200, which is an example of the system of the first embodiment. It should be noted that wiring indicated by dotted lines in the figure is a signal line.

The system 200 includes a management device 120 , computer devices 110 a to 110 f, a PDU 130 and a distribution board 140 .

The distribution board 140 supplies three-phase power to the PDU 130 via a wiring group 141 that is a three-phase, four-wire power supply line group. Each of the three-phase wirings included in the wiring group 141 is called a U line, a V line, and a W line. Also, the neutral wire included in the wiring group 141 is called the N wire.

PDU 130 comprises terminal pairs CUa and CUb, CVa and CVb, and CWa and CWb. PDU 130 also includes detector 138 .

Each terminal pair provided in the PDU 130 consists of a neutral terminal, which is a neutral terminal, and a single-phase output terminal. Each terminal pair constitutes an outlet.

A neutral terminal included in each of the terminal pairs CUa and CUb is electrically connected to the N line included in the wiring group 141 . Output terminals included in each of the terminal pairs CUa and CUb are electrically connected to the U line included in the wiring group 141 .

A neutral terminal included in each of the terminal pairs CVa and CVb is electrically connected to the N line included in the wiring group 141 . Output terminals included in each of the terminal pairs CVa and CVb are electrically connected to V lines included in the wiring group 141 .

A neutral terminal included in each of the terminal pairs CWa and CWb is electrically connected to the N line included in the wiring group 141 . Output terminals included in each of the terminal pairs CWa and CWb are electrically connected to the W line included in the wiring group 141 .

Terminal pairs CUa, CUb, CVa, CVb, CWa, and CWb supply single-phase power to computer devices 110a to 110f via wire pairs LUa, LUb, LVa, LVb, LWa, and LWb in this order. do.

The detection unit 138 detects each piece of detected power information representing the power supplied to the computer device via each of the U line, the V line, and the W line of the wiring group 141 . Then, the detected power information for each of the U line, V line and W line is transmitted to the management device 120 via the management network 150 . The transmission may be performed sequentially by the detection unit 138 . Alternatively, the transmission may be performed by a transmission instruction from management device 120 . The detection unit 138 includes means for accessing the management device 120, detection means for the power supply value of each line, user interface function, and the like to enable the operation.

The management device 120 is connected via a management network 150 to the detection unit 138 of the PDU 130 as well as to each of the computer devices 110a to 110f.

The management device 120 includes a processing section 121 and a storage section 122 .

The processing unit 121 is configured to include, for example, a central processing unit.

The processing unit 121 sequentially transmits instruction information for stopping or starting power supply to each part of the computer device to each computer device via the management network 150 . It is assumed that each computer device has a function to start or stop power supply to each part of the computer device according to the instruction information.

Then, each time the processing unit 121 transmits the instruction information to any one of the computer devices, the detection power information sent from the detection unit 138 indicates whether through which line of the V line, the U line, and the W line Determine if the power supply has changed. Then, the management device 120 causes the storage unit 122 to store a set of the specified line and the identifier of the computer device that sent the instruction information.

The processing unit 121 performs the above operation for all computer devices.

As a result, the storage unit 122 holds correspondence information specifying the line (phase) to which the computer device is connected for all the computer devices.

The storage unit 122 holds in advance programs and information for the processing unit 121 to perform the above operations. The storage unit 122 reads the instructed information according to the instruction of the processing unit 121 and sends it to the processing unit 121 . The storage unit 122 also stores information instructed by the processing unit 121 .

Although FIG. 1 shows a case where the number of computer devices is six, the number of computer devices included in the system of the embodiment is arbitrary. Also, the number of terminal pairs for each phase is arbitrary. Also, the way in which each computer device is connected to each phase is arbitrary.

FIG. 2 is a conceptual diagram showing a configuration example of the PDU 130 shown in FIG.

A three-phase, four-wire wiring group 141 shown in FIG. 1 is composed of wirings UL, VL, WL, and NL. Wirings UL, VL and WL are power supply lines. The wiring NL is a neutral wire.

The wiring UL is connected to the terminals U1 and U2 via the power sensor SU.

The wiring VL is connected to the terminals V1 and V2 via the power sensor SV.

The wiring WL is connected to the terminals W1 and W2 via the power sensor SW.

The wiring NL is connected to the terminals N1 to N6.

A set of terminal U1 and terminal N1 is terminal pair CUa shown in FIG. A set of terminal U2 and terminal N1 is terminal pair CUb shown in FIG. A set of the terminal V1 and the terminal N3 is the terminal pair CVa shown in FIG. A set of the terminal V2 and the terminal N4 is the terminal pair CVb shown in FIG. A pair of terminals W1 and N5 is a terminal pair CWa shown in FIG. A pair of terminals W2 and N6 is a terminal pair CWb shown in FIG.

Each terminal of the terminal pair CUa is connected to each wiring of the wiring pair LUa shown in FIG. Each terminal of the terminal pair CUb is connected to each wiring of the wiring pair LUb shown in FIG. Each terminal of the terminal pair CVa is connected to each wiring of the wiring pair LVa shown in FIG. Each terminal of the terminal pair CVb is connected to each wiring of the wiring pair LVb shown in FIG. Each terminal of the terminal pair CWa is connected to each wiring of the wiring pair LWa shown in FIG. Each terminal of the terminal pair CWb is connected to each wiring of the wiring pair LWb shown in FIG.

Each of the power sensors SU, SV and SW sends to the processing unit 137 of the detection unit 138 power information representing the power value of the power input from each of the wirings UL, VL and WL.

The detection unit 138 has a storage unit 139 and a processing unit 137 .

The processing unit 137 transmits power information for each of the wirings UL, VL, and WL to the management device 120 according to instruction information from the management device 120 shown in FIG. 1 via the management network 150 . At this time, the processing unit 137 converts the power information sent from each power sensor into transmission information that can be transmitted to the management device 120 via the management network 150 , and then transmits the transmission information to the management device 120 . The processing unit 137 may sequentially perform the transmission. Alternatively, the processing unit 137 may perform the transmission in response to a transmission instruction instruction received from the management device 120 .

The storage unit 139 holds in advance information necessary for the processing unit 137 to perform the above operations. Storage unit 139 also stores information instructed by processing unit 137 . The information includes, for example, the transmission information before the processing unit 137 transmits it to the management device 120 . The storage unit 139 also sends information instructed by the processing unit 137 to the processing unit 137 .

FIG. 3 is a conceptual diagram showing a configuration example of the computer device 110 shown in FIG. Note that the configuration shown in FIG. 3 is a well-known configuration, and detailed description thereof will be omitted here.

Computer device 110 shown in FIG. Here, CPU is an abbreviation for Central Processing Unit. IO is an abbreviation for Input/Output. PCH is an abbreviation for Platform Controller Hub. Also, BMC is an abbreviation for Baseboard Management Controller. Also, PSU is an abbreviation for Power Supply Unit.

The PCH 101 also includes an NM 102 . NM is an abbreviation for Node Manager.

The BMC 100 manages the computer device 110 in cooperation with the NM 102 . BMC 100 and PCH 101 are connected by SMBus 116 . Communication between BMC 100 and NM 102 is via SMBus 116 . Here, SMBus is an abbreviation for System Management Bus.

BMC 100, PCH 101 and PSU 103 are connected by PMBus 111. FIG. PMBus is an abbreviation for Power Management Bus.

Each of BMC 100 and NM 102 accesses PSU 103 via PMBus 111 .

CPU 105 and storage unit 104 are connected by DDR4-I/F 112 . DDR4 is an abbreviation for Double-Data-Rate4. Also, I/F is an abbreviation for interface. The CPU 105 and the IO card 106 are connected via the PCIe-I/F 113 . PCIe is an abbreviation for PCI Express. PCI is an abbreviation for Peripheral Component Interconnect.

The CPU 105 and PCH 101 are connected via the DMI 114 . DMI is an abbreviation for Desktop Management Interface. Normal access between CPU 105 and PCH 101 is through DMI 114 .

The CPU 105 and PCH 101 are also connected by a PECI (Platform Environment Control Interface) 115 . NM 102 accesses CPU 105 via PECI 115 .

BMC 100 is connected to management network 150 . A power cable is connected to the PSU 103 . The power cable is one of the wire pairs LUa, LUb, LVa, LVb, LWa and LWb shown in FIG. The power cable receives single-phase power from corresponding terminal pairs of PDU 130 .

The BMC 100 supplies or stops power supply to each component of the computer device according to instruction information from the management device 120 .

At that time, instruction information from the management device 120 is first input to the BMC 100 . Upon receiving the instruction information, the BMC 100 instructs the PSU 103 via the PMBus 111 to start or stop power supply from the PSU 103 to each component of the computer device 110 .
[Processing flow example]
FIG. 4 is a conceptual diagram showing a first processing flow example of processing performed by the processing unit 121 of the management device 120 shown in FIG. The processing described below is executed by, for example, a management program held in advance by the storage unit 122 .

For example, the processing unit 121 starts the processing shown in FIG.

Then, as the process of S101, the processing unit 121 generates a list of the device IDs of the target devices, which are the computer devices targeted for the processing shown in FIG. Here, ID is an abbreviation for Identifier. The processing unit 121 performs the generation based on the input information from the outside.

Next, as the processing of S102, the processing unit 121 instructs each of the computer devices having the device IDs included in the list generated by the processing of S101 to stop supplying power to each component of the computer device. Send instruction information. The computer device that has received the instruction information stops supplying power input to the computer device to each component of the computer device.

Then, as the process of S103, the processing unit 121 transmits to the PDU 130 instruction information for instructing transmission of detected power information for each wiring of the U line, the V line, and the W line. Even though the computing device stops supplying power to its components, the power supplied to the computing device may not be completely zero. The reason for this is that power may continue to be supplied, such as to the parts where the computer powers down or powers up its components. The process of S103 assumes the above case and causes the PDU 130 to send detected power information related to the supplied power in the above case.

Then, the processing unit 121 determines whether or not the detected power information has been received from the PDU 130 as the process of S104.

The processing unit 121 performs the processing of S105 when the determination result of the processing of S104 is yes.

On the other hand, when the determination result of the process of S104 is no, the processing unit 121 performs the process of S104 again.

When performing the processing of S105, the processing unit 121 causes the storage unit 122 to store the detected power information determined to have been received by the processing of S104 as the same processing.

Then, the processing unit 121 identifies one device ID for which the process of S107 has not yet been performed from among the device IDs included in the list generated by the process of S101.

Then, as the process of S107, the processing unit 121 transmits, to the computer apparatus having the apparatus ID specified by the process of S106, instruction information for starting supply of the input power to each component of the computer apparatus.

Then, as the process of S108, the processing unit 121 instructs the PDU 130 to transmit detected power information for each wiring of the U line, the V line, and the W line.

Then, the processing unit 121 determines whether or not the detected power information has been received from the PDU 130 as the process of S109.

The processing unit 121 performs the processing of S110 when the determination result of the processing of S109 is yes.

On the other hand, when the determination result of the process of S109 is no, the processing unit 121 performs the process of S109 again.

When performing the processing of S110, the processing unit 121 causes the storage unit 122 to store the detected power information determined to have been received by the processing of S109 as the same processing.

Then, the processing unit 121, as the process of S111, selects the wirings for which the detected power information stored by the process of S110 is greater than the detected power information stored by the process of S105 by a threshold value T1 or more. identify one of them. Here, the threshold T1 is a threshold relating to detected power information predetermined for the processing of S111. The threshold T1 is predetermined for the purpose of determining that power supply to each component of the computer apparatus has started for the changed wiring when the detected power information has changed by the threshold T1 or more. The threshold value T1 is stored in advance in the storage unit 122, for example.

Then, as the process of S112, the processing unit 121 causes the storage unit 122 to store a set of the device ID specified by the most recent process of S106 and the wiring ID of the wiring specified by the most recent process of S111.

Then, as the process of S113, the processing unit 121 transmits, to the computer apparatus having the apparatus ID specified in the process of S106, instruction information for stopping the supply of power to each component of the computer apparatus. The computer device that has received the instruction information stops supplying the input power to each component of the computer device.

Next, as the process of S114, the processing unit 121 determines whether or not the process of S107 has been performed for all device IDs included in the list generated by the process of S101.

The processing unit 121 performs the processing of S115 when the determination result of the processing of S114 is yes.

On the other hand, when the determination result of the process of S114 is no, the processing unit 121 performs the process of S106 again.

When performing the processing of S115, the processing unit 121 outputs all the sets stored in the storage unit 122 by the processing of S112 to a display or the like (not shown) as the same processing.

Then, the processing unit 121 ends the processing shown in FIG.

FIG. 5 is a conceptual diagram showing a second processing flow example of processing performed by the processing unit 121 of the management device 120 shown in FIG. The processing described below is executed by, for example, a management program held in advance by the storage unit 122 .

The process depicted in FIG. 5 differs from the description of the process represented in FIG. 4 by the following description. If the description below conflicts with the description of each process in FIG. 4, the description below takes precedence.

The description of S101 to S110 shown in FIG. 5 is the same as the description of S101 to S110 shown in FIG.

After the process of S110, the processing unit 121 performs the following process as the process of S111b. In other words, the processing unit 121 identifies a wire for which the detected power information stored by the most recent processing of S111 is increased by the threshold value T2 or more from the detected power information stored by the previous processing of S110. The processing unit 121 performs the identification from among the U line, the V line, and the W line.

Note that if there is no previous processing of S110, the processing unit 121 stores the detected power information stored by the most recent processing of S110 instead of the detected power information stored by the processing of S105. A wiring that has increased by a threshold value T2 or more is specified.

Here, the threshold T2 is a threshold related to detected power information predetermined for the processing of S111. The threshold value T2 is predetermined to the effect that when the detected power information increases by the threshold value T2 or more, it is determined that power supply to each component of the computer apparatus has started for the changed wiring. The threshold value T2 is stored in advance in the storage unit 122, for example.

Then, as the processing of S112b, the processing unit 121 causes the storage unit 122 to store a set of the device ID identified by the most recent processing of S106 and the wiring ID of the wiring identified by the most recent processing of S111b.

Next, as the process of S114b, the processing unit 121 determines whether or not the process of S107 has been performed for all device IDs included in the list generated by the process of S101.

The processing unit 121 performs the processing of S114-2 when the determination result of the processing of S114b is yes.

On the other hand, when the determination result of the process of S114b is no, the processing unit 121 performs the process of S106 again.

When performing the processing of S114-2, the processing unit 121, as the same processing, for the computer devices of all the device IDs included in the list generated by the processing of S101, supplies power to each component of the computer device. Sends instruction information instructing supply stop.

Then, as the processing of S115b, the processing unit 121 outputs all the sets stored in the storage unit 122 by the processing of S112b to a display or the like (not shown).

FIG. 6 is a conceptual diagram showing a third processing flow example of processing performed by the processing unit 121 of the management device 120 shown in FIG. The processing described below is executed by, for example, a management program held in advance by the storage unit 122 .

The process represented in FIG. 6 differs from the process represented in FIG. 4 by the following description. If the description below conflicts with the description of each process in FIG. 4, the description below takes precedence.

The description of the processing of S101 shown in FIG. 6 is the same as the description of the processing of S101 shown in FIG.

The processing unit 121 performs the process of S102c after the process of S101.

When the processing unit 121 performs the processing of S102, the processing unit 121, as the same processing, supplies the electric power supplied to each computer device of the device ID included in the list generated by the processing of S101 to each component of the computer device. Sends instruction information to instruct The computer device that has received the instruction information supplies the input power to each component of the computer device.

Then, the processing unit 121 performs the processing of S103.

The description of each process of S103 to S106 shown in FIG. 6 is the same as the description of each process of S103 to S106 shown in FIG.

After S106, the processing unit 121, as the process of S107c, transmits to the computer apparatus having the apparatus ID specified by the process of S106, instruction information for stopping the supply of the supplied power to each component of the computer apparatus. .

Then, the processing unit 121 performs the processing of S108.

The description of S108 to S110 shown in FIG. 6 is the same as the description of the processing of S108 to S110 shown in FIG.

After the process of S110, the processing unit 121 performs the following process as the process of S111c. That is, the processing unit 121 identifies, from among the U line, the V line, and the W line, the wiring in which the detected power information stored in the process of S110 is lower than the detected power information stored in the process of S105 by the threshold value T3 or more. . Here, the threshold T3 is a threshold relating to detected power information predetermined for the processing of S111c. The threshold T3 is predetermined for determining that the power supply to each component of the computer apparatus has been stopped for the changed wiring when the detected power information has decreased by the threshold T3 or more. The threshold value T3 is stored in advance in the storage unit 122, for example.

Then, as the processing of S112c, the processing unit 121 causes the storage unit 122 to store a set of the device ID identified by the most recent processing of S106 and the wiring ID of the wiring identified by the most recent processing of S111c.

Then, as the process of S113c, the processing unit 121 transmits, to the computer apparatus having the apparatus ID specified in the process of S106, instruction information for causing the supply of power to each component of the computer apparatus. The computer device that has received the instruction information starts supplying power to each component of the computer device.

Next, as the process of S114c, the processing unit 121 determines whether or not the process of S107 has been performed for all device IDs included in the list generated by the process of S101.

The processing unit 121 performs the processing of S115c when the determination result of the processing of S114c is yes.

On the other hand, when the determination result of the process of S114c is no, the processing unit 121 performs the process of S106 again.

When performing the processing of S115c, the processing unit 121 outputs all the sets stored in the storage unit 122 by the processing of S112c to a display or the like (not shown) as the same processing.

In the above example, the case where the management device causes each computer device to stop or start supplying power to each component of the computer device has been described. However, the management device may, for each computer device, increase or decrease the power supplied to each component of the computer device. The increase or decrease is caused, for example, by the computer device starting or stopping power supply to some components. Said increase or decrease may alternatively occur, for example, by increasing or decreasing the utilization of the computing device. Said increase or decrease may alternatively occur, for example, by changing the operating clock frequency of the central processing unit of the computer system or the number of instructions per unit time.

Also, in the above description, the case where the system includes one PDU has been described. However, a plurality of PDUs may be included in the system of the embodiment. In that case, the management device causes each computing device to vary the power it provides to each configuration of that computing device such that the wiring that supplies power to that computing device is one of the three-phase wirings that supply power to any PDU. Identify which one. In that case, power may be supplied to each PDU from a different power supply source (such as a switchboard).
[effect]
In the system of the first embodiment, the management device causes each of the computer devices to vary the power supplied to each configuration within the computer device in sequence. According to the change in the detected power information of the three-phase wiring input to the PDU, the management device determines which of the three-phase wiring the wiring connected to each computer device is connected to. identify if there is The identification is not based on human visual observation. In addition, there is no need for a person to manually set information indicating to which phase wiring each computer device is connected for the identification. As such, the system facilitates identification of the phase of power supplied to the computer device.

The system of the present embodiment may comprise multiple PDUs, each powered by a different power source. In that case, the system facilitates identification of the phase and source pairs of power supply supplied to the computer device.
<Second embodiment>
In the second embodiment, each computer device specifies which of the three-phase wires the connected wiring is by switching the PDU that supplies power to the configuration of that computer device. 1 is an embodiment of a system;
[Configuration and operation]
FIG. 7 is a conceptual diagram showing the configuration of a system 200b, which is an example of the system of the second embodiment. Wiring indicated by a dotted line in the figure is a signal line.

The system 200b includes a management device 120, computer devices 110a to 110f, PDUs 130a and 130b, and distribution boards 140a and 140b.

Each of the distribution boards 140a and 140b supplies three-phase power to each of the PDUs 130a and 130b via wiring groups 141a and 141b, which are three-phase four-wire power supply line groups. Each of the three-phase wirings included in each of the wiring groups 141a and 141b is a U line, a V line, and a W line. Also, the neutral wires included in each of the wiring groups 141a and 141b are N wires.

The PDU 130a comprises terminal pairs CUa1, CUa2, CVa1, CVa2, CWa1 and CWa2. PDU 130a also includes detector 138a.

Each terminal pair of the PDU 130a includes a neutral terminal and a single-phase output terminal. Each terminal pair constitutes an outlet.

A neutral terminal included in each of the terminal pairs CUa1 and CUa2 is electrically connected to the N line included in the wiring group 141a. The output terminal included in each of the terminal pairs CUa1 and CUa2 is electrically connected to the U line included in the wiring group 141a.

A neutral terminal included in each of the terminal pairs CVa1 and CVa2 is electrically connected to the N line included in the wiring group 141a. The output terminals included in each of the terminal pairs CVa1 and CVa2 are electrically connected to the V line included in the wiring group 141a.

Neutral terminals included in the terminal pairs CWa1 and CWa2 are electrically connected to the N lines included in the wiring group 141a. The output terminals included in each of the terminal pairs CWa1 and CWa2 are electrically connected to the W line included in the wiring group 141a.

Each of terminal pairs CUa1, CUa2, CVa1, CVa2, CWa1 and CWa2 can supply single-phase power to each of computer devices 110a, 110b, 110c, 110d, 110e and 110f. The supply is performed via each of the wiring pairs LUa1, LUa2, LVa1, LVa2, LWa1 and LWa2.

The detection unit 138a detects each piece of detected power information representing the power supplied to the computer device via each of the U line, the V line, and the W line of the wiring group 141a. Then, the detected power information for each of the U line, V line and W line is transmitted to the management device 120 via the management network 150 . The transmission may be performed sequentially by the detection unit 138a. Alternatively, the transmission may be performed by a transmission instruction from management device 120 . The detection unit 138a includes access means to the management device 120, detection means for the power supply value of each line, user interface function, and the like to enable the operation.

The description of the PDU 130b is obtained by replacing the a at the end of the reference numerals representing each of the PDU, the detection unit, the distribution board, the wiring group, the terminal pair, and the wiring pair in the above description of the PDU 130a.

The management device 120 is connected via a management network 150 to the detector 138a of the PDU 130a, the detector 138b of the PDU 130b, and each of the computer devices 110a to 110f.

The management device 120 includes a processing section 121 and a storage section 122 .

The processing unit 121 is configured to include, for example, a central processing unit.

The processing unit 121 sends instruction information to each computer device to switch the power supplied to each part of the computer device between the power from the PDU 130a and the power from the PDU 130b via the management network 150. Send to in order. It is assumed that each computer device has a function of switching the power supplied to each part of the computer device between the power from the PDU 130a and the power from the PDU 130b according to the instruction information.

Then, each time the processing unit 121 transmits the instruction information to any computer device, the detection power information received from the detection unit 138 specifies through which line the power supply has changed. The processing unit 121 performs the identification from among the V line, U line, and W line included in either the wiring group 141a or 141b.

Then, the management device 120 causes the storage unit 122 to store a set of the line ID representing the specified line and the identifier of the computer device to which the instruction information is to be transmitted. There are six line IDs representing each of the three-phase wirings for each PDU.

The processing unit 121 performs the above operation for all computer devices.

As a result, the storage unit 122 holds the set for each computer device.

The storage unit 122 holds in advance programs and information for the processing unit 121 to perform the above operations. The storage unit 122 reads the instructed information according to the instruction of the processing unit 121 and sends it to the processing unit 121 . The storage unit 122 also stores information instructed by the processing unit 121 .

FIG. 8 is a conceptual diagram showing a configuration example of the computer device 110 shown in FIG.

The description of FIG. 8 is the same as the description of FIG. 3, except for the following discussion. If the description below conflicts with the description of FIG. 3, the description below takes precedence.

A power cable including one of wiring pairs LUa1, LUa2, LVa1, LVa2, LWa1 and LWa2 shown in FIG. 7 is connected to the PSU 103a. The power cable receives single-phase power from corresponding terminal pairs of PDU 130a.

A power cable including one of wiring pairs LUb1, LUb2, LVb1, LVb2, LWb1 and LWb2 shown in FIG. 7 is connected to the PSU 103b. The power cable receives single-phase power from corresponding terminal pairs of PDU 130b.

The BMC 100 switches between the PSU 103a and the PSU 103b for supplying power to each component of the computer device according to the instruction information from the management device 120. FIG.

At that time, instruction information from the management device 120 is first input to the BMC 100 . Upon receiving the instruction information, the BMC 100 instructs the PSU 103 and PSU 103b via the PMBus 111 to start or stop power supply from the PSU 103 and PSU 103b to each component of the computer device 110 .

The BMC 100 instructs one of the PSU 103 a and the PSU 103 b to supply power to each component of the computer device 110 and instructs the other to stop supplying power to each component of the computer device 110 .

When the BMC 100 instructs the PSU 103a to supply power to each component of the computer device 110 and instructs the PSU 103b to stop supplying power to each component, power is supplied to each component from the PDU 130a via the PSU 103a. is done. In that case, the single phase power input to computing device 110 is from PDU 130a.

When the BMC 100 instructs the PSU 103b to supply power to each component of the computer device 110 and instructs the PSU 103a to stop supplying power to each component, power is supplied to each component from the PDU 130b via the PSU 103b. is done. In that case, the single phase power input to computing device 110 is from PDU 130b.
[Processing flow example]
FIG. 9 is a conceptual diagram showing a processing flow example of processing performed by the processing unit 121 of the management device 120 shown in FIG. The processing described below is executed by, for example, a management program held in advance by the storage unit 122 .

The processing depicted in FIG. 9 differs from the processing depicted in FIG. 6 in the following description. If the description below conflicts with the description of each process in FIG. 6, the description below takes precedence.

The description of the processing of S101 shown in FIG. 9 is the same as the description of the processing of S101 shown in FIG.

The processing unit 121 performs the process of S102d after the process of S101.

When the processing unit 121 performs the processing of S102d, the processing unit 121, as the same processing, supplies the electric power supplied to each computer device of the device ID included in the list generated by the processing of S101 to each component of the computer device. Sends instruction information to instruct The computer device that has received the instruction information supplies the supplied power to each component of the computer device.

Then, the processing unit 121 performs the processing of S103.

The description of each process of S103 to S106 shown in FIG. 9 is the same as the description of each process of S103 to S106 shown in FIG.

Then, as the process of S108d', the processing unit 121 instructs each of the PDUs 130a and 130b to transmit detected power information for each wiring of the U line, the V line, and the W line.

Then, the processing unit 121 performs the processing of S109'.

The description of S109' and S110' shown in FIG. 9 is the same as the description of the processing of S109 and S110 shown in FIG. However, in the same description, S109 should be read as S109', and S110 should be read as S110'.

After the process of S110', the processing unit 121 performs the following process as the process of S111d'. That is, the processing unit 121 specifies, from among the U line, the V line, and the W line, the wiring in which the detected power information stored in the process of S110′ is increased by the threshold value T4 or more from the detected power information stored in the process of S105. do. Here, the threshold T4 is a threshold relating to detected power information predetermined for the processing of S111d. The threshold T4 is predetermined to the effect that, when the detected power information decreases by the threshold T4 or more, it is determined that the power supply to each component of the computer apparatus has been stopped for the changed wiring. The threshold value T4 is stored in advance in the storage unit 122, for example.

Then, as the process of S112d', the processing unit 121 generates a set of the device ID specified by the most recent process of S106, the PSUID of the PSU currently in use, and the wiring ID of the line specified by the most recent process of S111d. , is stored in the storage unit 122 .

Then, after S112d', the processing unit 121 transmits instruction information for switching the PSU to which power is supplied to the computer device having the device ID identified by the processing of S106 as the processing of S107d after S112d'. Then, the processing unit 121 performs the processing of 108d.

The description of S108d to S112d shown in FIG. 9 is the same as the description of the above S108d' to S112d'. However, in the same explanation, "'" at the end of each code representing processing starting with the alphabetic letter S shall be deleted. In addition, if the replacement of terms causes a contradiction, the description shall not be read.

After the process of S112d, the processing unit 121, as the process of S114d, determines whether or not the process of S107d has been performed for all device IDs included in the list generated by the process of S101.

The processing unit 121 performs the processing of S115d when the determination result of the processing of S114d is yes.

On the other hand, when the determination result of the process of S114d is no, the processing unit 121 performs the process of S106 again.

When performing the processing of S115d, the processing unit 121 outputs all the sets stored in the storage unit 122 by the processing of S112d to a display or the like (not shown) as the same processing.

Note that the computer may switch PDUs and change the level of power supplied to each component within the computer according to an instruction from the management device. Also in this case, the management device identifies the phase to which the computer device is connected from the change in power information for each phase received from the PDU.
[effect]
The system of this embodiment has the same effect as the system of the first embodiment.

In the above explanation, the case where the input of the PDU is a three-phase four-wire system has been explained. However, it does not matter if the input of the PDU is a three-phase three-wire system.

FIG. 10 is a conceptual diagram showing a hardware configuration example of an information processing device capable of realizing the management device and computer device of each embodiment.

The information processing device 90 includes a communication interface 91 , an input/output interface 92 , an arithmetic device 93 , a storage device 94 , a nonvolatile storage device 95 and a drive device 96 .

The communication interface 91 is communication means for the communication device of each embodiment to communicate with an external device by wire and/or wirelessly. When the communication device is implemented using at least two information processing devices, these devices may be connected via the communication interface 91 so as to be able to communicate with each other.

The input/output interface 92 is a man-machine interface such as a keyboard as an example of an input device and a display as an output device.

The arithmetic unit 93 is an arithmetic processing unit such as a general-purpose CPU (Central Processing Unit) or a microprocessor. The computing device 93 can, for example, read various programs stored in the nonvolatile storage device 95 to the storage device 94 and execute processing according to the read programs.

The storage device 94 is a memory device such as a RAM (Random Access Memory) that can be referred to by the arithmetic device 93, and stores programs, various data, and the like. Storage device 94 may be a volatile memory device.

The non-volatile storage device 95 is a non-volatile storage device such as ROM (Read Only Memory), flash memory, etc., and is capable of storing various programs and data.

The drive device 96 is, for example, a device that processes data reading and writing with respect to a recording medium 97, which will be described later.

The recording medium 97 is, for example, an optical disk, a magneto-optical disk, a semiconductor flash memory, or any other recording medium capable of recording data.

In each embodiment of the present invention, for example, the information processing device 90 illustrated in FIG. It may be realized by

In this case, the embodiment can be realized by having the arithmetic device 93 execute the program supplied to the communication device. It is also possible to configure the information processing device 90 to perform not all but some of the functions of the communication device.

Further, the program may be recorded in the recording medium 97 and stored in the non-volatile storage device 95 as appropriate at the stage of shipment or operation of the communication apparatus. In this case, as the method of supplying the program, a method of installing the program in the communication device using an appropriate jig at the manufacturing stage before shipment or at the operation stage may be adopted. Moreover, as a method of supplying the program, a general procedure such as a method of downloading from the outside via a communication line such as the Internet may be adopted.

The embodiments described above are preferred embodiments of the present invention, and various modifications can be made without departing from the gist of the present invention.

FIG. 11 is a conceptual diagram showing the configuration of a derivation device 120x, which is the minimum configuration of the derivation device of the embodiment.

The derivation device 120x includes a transmission unit 121ax, a reception unit 121bx, and a derivation unit 121cx.

The transmission unit 121ax transmits instruction information to a predetermined operating device.

The receiving unit 121bx receives power information representing the power supplied to each of the operating devices among each of single-phase power constituting multi-phase power, which is power of multiple phases from a predetermined supply source.

The deriving unit 121cx derives phase information representing a phase in the single-phase power being supplied to each of the operating devices from the change in power. is changed based on the instruction information.

Derivation device 120x causes each of the operating devices to change the level and/or source of the single-phase power. Then, the derivation device 120x specifies from which of the plurality of phases the single-phase power is derived, based on the change in the power information of each of the plurality of phases input to the supply device. The identification is not based on human visual observation. In addition, there is no need for a person to manually set information indicating to which phase wiring each operating device is connected for the identification. As such, the system facilitates identification of the phase of power supplied to the computer device.

Therefore, the derivation device 120x has the effects described in the section [Effects of the Invention] due to the above configuration.

The derivation device 120x shown in FIG. 11 is, for example, the management device 120 shown in FIG. 1 or FIG. Further, the transmission unit 121ax is, for example, the part that performs the transmission, which is included in the processing unit 121 shown in FIG. 1 or 7 . Also, the receiving unit 121bx is a part that performs the above-described reception, which is included in the processing unit 121 shown in FIG. 1 or 7, for example. Also, the derivation unit 121xc is a part that performs the derivation, which is included in the processing unit 121 shown in FIG. 1 or 7, for example. Also, the instruction information is the above-described instruction information sent by the management device 120 shown in FIG. 1 or 7 to each computer device. Also, the operating device may be, for example, each of the computing devices 110a-110f depicted in FIG. 1 or FIG. Also, the plurality of phases are, for example, three phases. Further, the supply source is, for example, the distribution board 140 shown in FIG. 1, the distribution board 140a or the distribution board 140b shown in FIG. Also, the power information is, for example, the aforementioned detected power information.

Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and further modifications, replacements, and adjustments can be made without departing from the basic technical idea of the present invention. can be added. For example, the configuration of elements shown in each drawing is an example for helping understanding of the present invention, and the configuration is not limited to the configuration shown in these drawings.

Also, part or all of the above embodiments may be described as the following additional remarks, but are not limited to the following.
(Appendix 1)
a transmission unit that transmits instruction information to a predetermined operating device;
a receiving unit that receives power information representing power supplied to each of the operating devices, out of each of single-phase power that constitutes multi-phase power, which is power of a plurality of phases from a predetermined supply source;
a deriving unit that derives phase information representing a phase in the single-phase power being supplied to each of the operating devices from the change in power;
A derivation device wherein the level and/or the source of the single phase power for each of the operating devices is changed based on the indication information.
(Appendix 2)
2. The derivation device of claim 1, wherein the power information is sent from a supply device that converts the multi-phase power into the plurality of single-phase power.
(Appendix 3)
3. The derivation device according to statement 1 or statement 2, wherein the change of the source of supply is due to switching of the source of supply.
(Appendix 4)
4. The derivation apparatus of clause 3, further comprising a second plurality of feeders each receiving an input of said multi-phase power from a different said feeder, said changing being effected by switching said feeders.
(Appendix 5)
5. The delivery device of clause 4, wherein the operating device switches the feeding device.
(Appendix 6)
6. The derivation device according to any one of appendices 1 to 5, wherein the phase information represents the phase and represents the source of the power associated with the phase.
(Appendix 7)
3. The derivation device according to appendix 1 or appendix 2, wherein the change in the level is an increase in the level, and the derivation unit performs the derivation by an increase amount related to the increase.
(Appendix 8)
8. The derivation device of clause 7, wherein said increase is caused by initiating power to a predetermined configuration of said operating device.
(Appendix 9)
3. The derivation device according to appendix 1 or appendix 2, wherein the change in the level is a decrease in the level, and the derivation unit performs the derivation by a decrease amount related to the decrease.
(Appendix 10)
10. The derivation device of clause 9, wherein said reduction is caused by de-energizing a predetermined configuration of said operating device.
(Appendix 11)
11. The derivation device according to any one of appendices 1 to 10, wherein the input of the multi-phase power is performed by a wiring group including the plurality of power supply lines.
(Appendix 12)
12. The derivation device of clause 11, wherein the wire group includes a neutral wire.
(Appendix 13)
13. A derivation device according to any one of clauses 1 to 12, wherein said transmission and said reception occur over a network.
(Appendix 14)
14. The derivation device of clause 13, wherein said network is a private network.
(Appendix 15)
15. The derivation device of any one of clauses 1-14, wherein the operating device is a computing device.
(Appendix 16)
16. A derivation device according to any one of appendices 1 to 15, which is a management device.
(Appendix 17)
A derivation system comprising a derivation device according to any one of appendices 1 to 16 and the operating device.
(Appendix 18)
sending instruction information to a predetermined operating device;
receiving power information representing power to be supplied to each of the operating devices from each of single-phase power constituting multi-layer power, which is power of a plurality of phases from a predetermined supply source;
deriving from the change in power phase information representing a phase in the single-phase power being supplied to each of the operating devices;
The level of single phase power and/or the source of each of the operating devices is modified based on the indication information.
(Appendix 19)
a process of transmitting instruction information to a predetermined operating device;
a process of receiving power information representing power supplied to each of the operating devices among each of single-phase power that constitutes multi-layer power, which is power of multiple phases from a predetermined supply source;
causing a computer to perform a process of deriving phase information representing a phase in the single-phase power supplied to each of the operating devices from the change in power;
A derivation program wherein the level and/or the source of the single phase power for each of the operating devices is modified based on the indication information.

90 information processing device 91 communication interface 92 input/output interface 93 arithmetic device 94 storage device 95 nonvolatile storage device 96 drive device 97 recording medium 100 BMC
101PCH
102 NM
103, 103a, 103b PSUs
104, 122, 139 storage unit 105 CPU
106 IO card 110, 110a, 110b, 110c, 110d, 110e, 110f Computer device 111 PMBus
113 PCIe-I/F
114 DMI
115 PECI
116 SMBus
120 management device 121 processing unit 130 PDU
138 detection unit 140 distribution board 141 wiring group 150 management network 200, 200b System CUa, CUa1, CUa2, CUb, CUb1, CUb2, CVa, CVa1, CVa2, CVb, CVb1, CVb2, CWa, CWa1, CWa2, CWb, CWb1 , CWb2 Terminal pair LUa, LUa1, LUa2, LUb, LUb1, LUb2, LVa, LVa1, LVa2, LVb, LVb1, LVb2, LWa, LWa1, LWa2, LWb, LWb1, LWb2 Wire pair SU, SV, SW Power sensor U1, U2, V1, V2, W1, W2 Terminals UL, VL, WL, NL Wiring

Claims (7)

a transmission unit configured to transmit instruction information to a plurality of operating devices that operate with power supplied from any one of a plurality of supply sources ;
a receiving unit that receives power information representing power supplied to each of the plurality of operating devices, out of each of single-phase power that constitutes multi-phase power, which is power of a plurality of phases from the supply source;
a derivation unit that derives phase information representing a phase in the single-phase power supplied to each of the plurality of operating devices from a change in the power caused by switching of the supply source . 2. The derivation apparatus of claim 1, wherein the power information is sent from a feeder that converts the multi-phase power into the plurality of single-phase power. 3. The apparatus according to claim 1 , further comprising a second plurality of supply devices each receiving an input of said multi-phase power from a different supply source, wherein said supply sources are changed by switching said supply devices. Derivation device as described. 4. A delivery device as claimed in claim 3 , wherein the operating device switches the feeding device. 5. A derivation as claimed in any preceding claim, wherein the phase information is representative of the phase and the source of the plurality of sources of the power associated with the phase. Device. transmitting instruction information to a plurality of operating devices that operate with power supplied from any of a plurality of supply sources ;
receiving power information representing power to be supplied to each of the plurality of operating devices from each of single-phase power constituting multi-layer power, which is power of a plurality of phases from the supply source;
a derivation method for deriving phase information representing a phase in the single-phase power supplied to each of the plurality of operating devices from changes in the power caused by switching the supply source . a process of transmitting instruction information to a plurality of operating devices that operate with power supplied from any of a plurality of supply sources ;
a process of receiving power information representing power supplied to each of the plurality of operating devices among each of single-phase power that constitutes multi-layered power, which is power of a plurality of phases from the supply source;
A derivation program causing a computer to execute a process of deriving phase information representing a phase of the single-phase power supplied to each of the plurality of operating devices from the change in the power caused by switching of the supply source .

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