JP7077868B2 - Power control device and information processing device - Google Patents

Description

The present invention relates to a power supply control device and an information processing device.

In an information processing device such as a server, when an AC power cord of a power supply module such as a PSU (Power Supply Unit) is connected to an AC outlet, a "resident power supply" that is supplied with power to a load is used.

The PSU may have a hiccup function for preventing overcurrent due to the element characteristics of the PSU. The Hickup function stops the output from the PSU and resumes the output after a certain period of time in order to prevent the PSU's IC (Integrated Circuit) and server (load) from failing when the output current exceeds the specified value. This is an example of the overcurrent protection function.

Japanese Unexamined Patent Publication No. 63-157616 Japanese Unexamined Patent Publication No. 2008-217394

By the way, in the device configuration of a large-scale server having a plurality of units such as a system unit and an I / O (Input / Output) unit and a plurality of PSUs, for example, when the server is started, the AC power of the PSU is turned on by an operator. May be performed sequentially. At this time, the peak of the inrush current on the load side with respect to the "resident power supply" may exceed the specified value and the hiccup function may operate depending on the configuration of the mounted unit on the load side, the condition of the quantity, and the like.

In this case, after the output of the PSU is stopped and restarted, the peak of the inrush current on the load side with respect to the "resident power supply" may exceed the specified value again, and the hiccup function may be repeatedly operated. As a result, the power ON / OFF from the PSU is repeated, so that the power ON of the server may not be normally performed.

In one aspect, it is an object of the present invention to easily or at low cost control of power supply in an information processing apparatus.

In one embodiment, the power supply control device may include a switching unit and a switching control unit. The switching unit may switch the state of the power supply path for supplying power from the plurality of power supply devices to the plurality of system modules provided by the information processing device to either a connected state or a disconnected state. The switching control unit calculates the supplyable current value that can be supplied by one or more power supply devices connected to the power supply source based on the power supply signal output when the power supply device is connected to the power supply source. You can do it. Further, when the supplyable current value reaches the total value of the inrush currents of the plurality of system modules, the switching control unit changes the state of the power supply path to the switching unit in the disconnected state. Control to switch to the connection state may be performed.

In one aspect, power supply control in the information processing apparatus can be performed easily or at low cost.

It is a block diagram which shows the structural example of the rack which concerns on the comparative example of one Embodiment. It is a block diagram which shows the structural example of the information processing system which concerns on one Embodiment. It is a block diagram which shows the structural example of the rack which concerns on one Embodiment. It is a block diagram which shows the functional structure example of the control part which concerns on one Embodiment. It is a figure which shows an example of a unit table. It is a figure which shows an example of a PSU table. It is a flowchart which shows the operation example of the power supply control by the server which concerns on one Embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. However, the embodiments described below are merely examples, and there is no intention of excluding various modifications and applications of techniques not specified below. For example, the present embodiment can be variously modified and implemented without departing from the spirit of the present embodiment. In the drawings used in the following embodiments, the parts with the same reference numerals represent the same or similar parts unless otherwise specified.

[1] Embodiment [1-1] Comparative Example FIG. 1 is a block diagram showing a configuration example of a rack 100 according to a comparative example of one embodiment. As shown in FIG. 1, the rack 100 according to the comparative example may be equipped with a plurality of (m units; m is a natural number) servers 110 and a plurality of power strips 120.

The plurality of servers 110 may each have the same configuration as each other, and in the example of FIG. 1, the configuration of the server 110-1 (server # 1) will be described on behalf of the plurality of servers 110. When the servers 110-1 to 110-m are not distinguished, they are simply referred to as the server 110.

As shown in FIG. 1, the server 110 includes a relay board 130, a plurality of (n units; n is a natural number) PSU 140, a plurality of (i units; i is a natural number) system units 150, and a plurality (j units; j). It may be equipped with an I / O unit 160 (natural number).

The relay board 130 is a board (for example, an electronic device) for interconnecting a plurality of PSUs 140, a plurality of system units 150 such as a fan (not shown), a plurality of I / O units 160, and the like.

The power strip 120 is a device that draws power into the rack 100 from the original AC power outlet (outlet). The power strip 120 may be provided with a plurality of outlets. Examples of the power strip 120 include an outlet box.

The AC power supply may be a resident power supply that supplies power to the unit inside the server 110 connected to the power strip 120 immediately after the connection to the power strip 120. The AC power supply is provided under the floor of the space (for example, indoors) where the rack 100 is installed or on the back surface inside the rack 100. When the cable (plug) of the power strip 120 is connected to the outlet (energized state) of the original AC power supply, the AC power supply and the power strip 120 become resident power supplies.

As illustrated in FIG. 1, each PSU 140 may be connected to the power strip 120-1 via each cable 140a. Further, each system unit 150 may be connected to the power tap 120-2 via each cable 150a, and each I / O unit 160 may be connected to the power tap 120-3 via each cable 160a. good.

In this case, the PSU 140 connected to the power strip 120-1 is a resident power supply (standby power supply) used when the power of each unit is turned off with respect to the system unit 150 and the I / O unit 160 via the relay board 130. Power may be supplied (powered). In the example of FIG. 1, a resident power source (for example, 12V) is indicated by reference numeral 170.

When the power of the server 2 is turned on, the PSU 140 informs the system unit 150 and the I / O unit 160 via the relay board 130 as a non-resident power source for the operation when the power of each unit is turned on. The power of the normal power supply) may be supplied (powered). In the example of FIG. 1, the non-resident power supply (for example, 12V) is indicated by reference numeral 180. Although the resident power supply 170 and the non-resident power supply 180 are shown in FIG. 1, these power supplies may be supplied via a common power supply path.

The power strip 120-2 may supply (power) the power of the resident power supply (standby power supply) used when the power of the system unit 150 is turned off to each system unit 150. Further, the power strip 120-3 may supply (power) the power of the resident power supply (standby power supply) used when the power of the I / O unit 160 is turned off to each I / O unit 160.

Next, assuming that the relay board 130, the PSU 140, the system unit 150, the I / O unit 160, the power strips 120-2 and 120-3 are connected, an example of the procedure for starting the server 110-1 by the operator. To explain.

(1) The operator inserts one end of each cable 140a into the power strip 120-1.

(2) The operator connects the other end of each cable 140a to the PSU 140.

(3) The operator turns on the power switch of the server 110.

The power supply of the server 110 is turned on by the procedure (3) above (the server 110 is started), but the power itself is supplied from the PSU 140 connected to the power strip 120-1 in the procedure (2) above. Will be supplied sequentially.

Here, in the procedure (2) above, the resident power supply (standby power supply) is supplied to the system unit 150 and the I / O unit 160 even before the cable 140a is connected. Therefore, when the other end of the cable 140a is connected to the PSU 140 by the procedure (2) above, the standby power supply already supplied to the load side and the standby power supply supplied by the PSU 41 (single unit) immediately after the connection are obtained. Depending on the difference, the Hiccup function may work.

In this case, after the output of the PSU 140 is stopped and restarted, the peak of the inrush current on the load side with respect to the resident power supply may exceed the specified value again, and the hiccup function may be repeatedly operated. As a result, the power ON / OFF from the PSU 140 is repeated, so that the power ON / OFF of the server 110 may not be normally performed.

As illustrated in FIG. 1, the power input circuit unit of each unit, for example, the intrusion prevention circuit (denoted as “CR” in FIG. 1) 152 of each system unit 150, and the intrusion prevention of each I / O unit 160. It is conceivable to set different time constants for the circuit 162.

For example, a different time constant is provided for the control signal of the power ON / OFF switch for each unit or each type of unit. As a result, the ON time of the power switch can be shifted, and even when the power is turned on to each unit at the same time, the peak current consumption of the entire server 110 can be suppressed (within the specified value). Therefore, since the inrush currents on the load side do not overlap, it is possible to prevent the output (DC) of the PSU 140 from shutting down due to the inrush currents on the load side when the PSU 140 is connected to the power strip 120-1.

However, in the method illustrated in FIG. 1, units having the same function or the like are managed as different units (separate products) in units having different time constants, so that the number of products for each unit or the like increases. Management becomes complicated, and the cost associated with management increases.

For example, it is conceivable to provide an outlet box or the like having a power switch so that the power of a plurality of PSU 140s can be turned on at once. When such an outlet box is provided, a mounting space is secured in the housing of the rack 100. However, the use of the rack space for the user by the provider of the rack 100 or the server 110 may not be permitted.

Further, in the installation environment of the server 110, the installation of such a power switch may be restricted between the AC power outlet and the PSU 140 from the viewpoint of operability and safety. When it is restricted, for example, when it is difficult for the user to insert and remove the plug from the AC power supply due to the installation conditions of the AC power supply, such as under the floor, or because of safety problems, the AC power supply is limited to the user side. There are cases where it is difficult to request switching between ON and OFF.

Further, for example, it is conceivable to adopt a high-performance PSU having a sufficient power supply capacity as the PSU 140. However, a high-performance (or dedicated) PSU is more expensive than a general-purpose PSU, and the introduction cost increases.

The rack 100 or a system including a plurality of servers 110 may be provided with a management device for managing the servers 110. In this case, the power switch on each unit may be connected to the management device, and the power ON / OFF timing may be controlled for each unit by a signal from the management device.

The management device can shift the power ON timing for each unit such as the system unit 150 and the I / O unit 160, so that the peak current consumption of the entire server 110 can be reduced even when the power is turned on to the server 110. It can be suppressed. However, when the management device is used, the cost increases due to the introduction and maintenance of the management device.

Therefore, in one embodiment, a method for easily or at low cost to control the power supply in the information processing apparatus will be described.

[1-2] Configuration Example of Information Processing System According to One Embodiment FIG. 2 is a block diagram showing a configuration example of the information processing system 1 according to one embodiment, and FIG. 3 is a rack 10 according to one embodiment. It is a block diagram which shows the configuration example of.

As illustrated in FIG. 2, the information processing system 1 may optionally include an AC power supply 11, a plurality of power strips 12, and a plurality of servers (m units; m is a natural number, see FIG. 3). ..

The AC power supply 11 may be a resident power supply that supplies power to the unit inside the server 2 connected to the power strip 12 immediately after the connection to the power strip 12. The AC power supply 11 is provided under the floor of the space (for example, indoors) where the rack 10 is installed or on the back surface inside the rack 10. When the cable (plug) of the power strip 12 is connected to the outlet (energized state) of the original AC power supply 11, the AC power supply 11 and the power strip 12 become resident power supplies.

As described above, the AC power supply 11 and the power strip 12 connected to the AC power supply 11 are an example of a power supply source that is a source of power supplied by the PSU 41 to the server 2 (load unit).

The power strip 12 is a device that is connected to the outlet of the original AC power source 11 and draws power into the rack 10. The power strip 12 may be provided with a plurality of outlets. Examples of the power strip 12 include an outlet box.

The server 2 is an example of an information processing device. As illustrated in FIG. 2, the server 2 includes a relay board 3, a plurality of (n units; n is a natural number) power supply device 4, a plurality of (i units; i is a natural number) system units 5, and a plurality (j units). ; J may be provided with an I / O unit 6 (which is a natural number). In addition to the system unit 5 and the I / O unit 6, the server 2 may be provided with another load unit that serves as a load on the power supply device 4.

Hereinafter, the units provided in the server 2, including the system unit 5 and the I / O unit 6, may be collectively referred to as a “load unit”. Since the load unit is a module that can be inserted and removed from the system of the server 2, it may be referred to as a "system module".

The relay board 3 is a board (for example, an electronic device) for connecting a plurality of power supply devices 4, a plurality of system units 5, a plurality of I / O units 6, and the like to each other, and is an example of a power supply control device.

The power supply device 4 may include a PSU 41 as an example of a power supply device, and a fan 42 that receives power from the PSU 41 and cools the inside of the server 2. The fan 42 may be provided outside the housing of the power supply device 4.

The PSU 41 is an example of a power supply device in which AC power is input from a power tap 12-1, AC-DC conversion is performed, and DC power is output to a relay board 3. For example, the PSU 41 supplies power of a resident power source (normal power source; main power source) for operation when the power of each load unit is turned on to the system unit 5 and the I / O unit 6 via the relay board 3. (Power supply) may be applied.

As illustrated in FIG. 2, each PSU 41 may be connected to the power strip 12-1 via a cable (cable 4a in the example of FIG. 3), and the power supply path (power supply path 7a in the example of FIG. 3). It may be connected to the relay board 3 via.

As the PSU 41, for example, a general-purpose PSU for a server (which is relatively inexpensive) may be used. The general-purpose PSU may mean a PSU that can be purchased on the market with priority given to the shape, electrical specifications, etc., based on the configuration conditions of the device (for example, the server 2) that uses the PSU.

The system unit 5 is a unit equipped with a CPU (Central Processing Unit), a memory, and the like (not shown), and the system unit 5 alone has a function as an information processing device. The load in the system unit 5 is devices such as a CPU and a memory that make up the system unit 5.

As illustrated in FIG. 2, each system unit 5 may be connected to the relay board 3 via a power supply path (power supply path 7b in the example of FIG. 3), and may be connected to a cable (cable 5a in the example of FIG. 3). It may be connected to the power strip 12-2 via. The power strip 12-2 may supply (power) the power of the resident power supply (standby power supply) used when the power of the system unit 5 is turned off to each system unit 5.

The I / O unit 6 is a unit equipped with devices such as external IF (Interface) cards and having the function of an input / output device capable of transmitting and receiving data and signals from the external IF to the system and other units. be. The load in the I / O unit 6 is a device such as an IC (Integrated Circuit) element mounted on the I / O unit 6 and external IF cards.

As illustrated in FIG. 2, each I / O unit 6 may be connected to the relay board 3 via a power supply path (power supply path 7b in the example of FIG. 3), and may be connected to a cable (cable in the example of FIG. 3). It may be connected to the power strip 12-3 via 6a). The power strip 12-3 may supply (power) the power of the resident power supply (standby power supply) used when the power of the I / O unit 6 is turned off to each I / O unit 6.

The power supply paths 7a and 7b may be, for example, cables, or may be connectors that directly connect the PSU41 or the load unit and the relay board 3 (without using a cable), respectively. ..

The system unit 5 and the I / O unit 6 may have a power ON / OFF switch on each load unit so that the power can be turned on for each load unit. Further, the system unit 5 and the I / O unit 6 may be provided with a structure that enables the load unit to be attached / detached while the power is turned on by the hot swap function (hot swapping or active insertion / removal).

The system unit 5 and the I / O unit 6 are power input circuits that convert AC power input from power strips 12-2 or 12-3 into AC-DC and output DC power to the inside of the load unit, respectively. A part (not shown) may be provided.

As shown in FIG. 3, the power strip 12 and the server 2 may be housed in, for example, a housing such as a rack (server rack) 10. The rack 10 may be provided in, for example, a data center, a server room, an office, or the like, and as shown in FIG. 3, a plurality of (m units; m is a natural number) servers 2 and a plurality of power strips 12 are mounted. You can do it.

The plurality of servers 2 may each have a similar configuration to each other. Hereinafter, as illustrated in FIG. 3, the configuration of the server 2-1 (server # 1) will be described on behalf of the plurality of servers 2. When the servers 2-1 to 2-m are not distinguished, they are simply referred to as server 2. Further, in FIG. 3, for convenience, the PSU 41 of the power supply device 4 is focused and shown.

As shown in FIG. 3, the relay board 3 according to the embodiment may optionally include a switching switch (switch) 31, a control unit 32, and a display unit 33. In the relay board 3, for example, electric power may be supplied by the PSU 41 connected to the power strip 12-1, and the control unit 32 and the display unit 33 may operate by the supplied electric power.

The switching SW31 is connected between the power supply path 7a and the power supply path 7b, and switches the connection (energization) between the power supply paths 7a and 7b between the ON state (closed state) and the OFF state (open state). .. This makes it possible to switch ON and OFF of the power supply from the PSU 41 to the load unit. As the switching SW 31, various switches capable of switching contacts may be used.

In other words, the switching SW31 is a switching unit that switches the states of the power supply paths 7a and 7b for supplying power from the plurality of PSUs 41 to the plurality of load units provided by the server 2 to either a connected state or a disconnected state. This is an example.

The control unit 32 controls switching between the ON state and the OFF state with respect to the switching SW31. Examples of the control unit 32 include a control circuit. The control circuit may include, for example, an IC as an example of a processor, a memory device as an example of a storage device, and the like. Examples of the memory device include a non-volatile memory such as a flash memory and a ROM (Read Only Memory), a volatile memory such as a RAM (Random Access Memory), and the like.

For example, the control unit 32 may control the switching SW 31 to an OFF state, that is, a state in which the power supply path 7a and the power supply path 7b are not connected when the relay board 3 is not energized. Further, when the number of PSUs 41 to which AC power is supplied (connected to the power strip 12-1) satisfies the following conditions, the control unit 32 sets the switching SW31 to the ON state, that is, the power supply path 7a. It may be controlled so that it is connected to the power supply path 7b.

For example, in one embodiment, the control unit 32 has a total current value that can be supplied by the PSU 41 to which AC power is supplied exceeds the total peak current of each load unit mounted on the server 2 with respect to the resident power supply. In that case, it may be determined that the condition is satisfied.

Further, the control unit 32 may control the display unit 33 to display information indicating the number of PSUs 41 for satisfying the above-mentioned conditions.

As described above, according to the control unit 32, the connection from the PSU 41 to the load unit, that is, the power supply is performed until the number of PSU 41s capable of supplying the total peak current value of the load unit is connected to the power strip 12-1. It is put on hold (restricted).

As described above, the control unit 32 is an example of a switching control unit that controls the switching SW 31 to switch the states of the power supply paths 7a and 7b. The control unit 32 as the switching control unit can be regarded as performing the following processes (1) and (2), for example.

(1) The control unit 32 determines the supplyable current value that can be supplied by one or more PSUs 41 connected to the power strip 12-1 based on the power supply signal output when the PSU 41 is connected to the power strip 12-1. calculate.

(2) When the supplyable current value reaches the total value of the inrush currents of the plurality of load units, the control unit 32 switches the states of the power supply paths 7a and 7b to the switching SW31 from the disconnected state. Controls to switch to the connected state.

For example, the control unit 32 has a switching SW 31 and a display unit 33 based on an AC PON signal acquired from each PSU 41 via the communication path 8 and a unit identification signal acquired from each load unit via the communication path 9. May be controlled. The details of the control by the control unit 32 will be described later.

The display unit 33 can display information indicating a numerical value, and may display information indicating the number of PSUs 41 under the control of the control unit 32. As a result, the operator can perform the work of connecting the PSU 41 to the power strip 12-1 based on the number of units displayed on the display unit 33.

In addition, in place of or in addition to the above-mentioned information, the display unit 33 includes the number of PSUs 41 to which AC power is currently supplied, the number of remaining PSUs 41 until the conditions are satisfied, and the like. At least one piece of information may be displayed.

As the display unit 33, various devices such as an LED (Light Emitting Diode), an LCD (Liquid Crystal Display), a display device such as an organic EL (Electro Luminescence), and an acoustic device such as a buzzer or a speaker may be used. As the display unit 33, an existing device such as an LED provided on the relay board 3 may be used.

The control unit 32 may use an electric energy value (for example, a current value) instead of the number of PSUs 41 as the determination of whether or not the condition is satisfied and the information to be displayed on the display unit 33.

As an example, the control unit 32 may use at least one of the peak electric energy value supplied (supplyable) by the PSU 41 and the sum of the peak electric energy values of the load unit. In this case, the display unit 33 may display at least one electric energy value instead of the number of units.

[1-3] Configuration example of the control unit Next, a configuration example of the control unit 32 will be described with reference to FIG. FIG. 4 is a block diagram showing a functional configuration example of the control unit 32 according to the embodiment. As shown in FIG. 4, the control unit 32 is exemplified by a memory device 321, an identification signal receiving circuit 322, an ACPON signal receiving circuit 323, a PSU number calculation circuit 324, a switching control circuit 325, and a DC / DC conversion. Circuit 326 may be provided.

The memory device 321 is an example of a storage device having a storage area for storing information used by the control unit 32, and in one embodiment, the information of the unit table 321a and the PSU table 321b may be stored. In the following description, for convenience, these tables 321a and 321b will be described as table-format information, but in various formats (for example, an array, a bitmap format, etc.) according to the storage mode of the memory device 321. May be stored.

Examples of the memory device 321 include a non-volatile memory such as a flash memory and a ROM, a volatile memory such as a RAM, and the like.

The unit table 321a is information indicating the peak (rush) current value for each type of load unit, and is an example of the second information in which the inrush current value for each load unit identified by the module identification signal is set. As shown in FIG. 5, the unit table 321a may optionally include information on "mounting position", "unit type", "unit identification signal", and "peak current [A] of resident power supply". ..

The “mounting position” indicates the connection position of the load unit in the server 2, and may be, for example, a slot number.

“Unit type” indicates the type of load unit such as system unit 5 or I / O unit 6. Even in the same type of load unit, the peak current may fluctuate for each product (model, option, etc.). Therefore, the "unit type" may be distinguished by product (model, option, etc.). In the example of FIG. 5, "# 1" to "# 4" are added to the unit types (system unit or I / O unit) so that they can be distinguished from each other in the same type of load unit.

The “unit identification signal” is an example of a module identification signal, and indicates information for identifying a load unit.

"Peak current [A] of the resident power supply" indicates a peak (rush) current value with respect to the resident power supply generated (possibly) in the load unit. The peak current value may be a specification on the catalog provided by the manufacturer or distributor of the load unit, or may be an actually measured value measured in advance by the administrator of the server 2.

The PSU table 321b is information indicating the supplyable current value for each type of PSU41, and is an example of the first information in which the supplyable current value for each PSU41 identified by the AC PON signal is set. As shown in FIG. 6, the PSU table 321b optionally includes information on "mounting position", "unit type", "unit identification signal", and "supplyable current (peak current) [A]". It's fine.

The “mounting position” indicates the connection position of the PSU 41 in the server 2, and may be, for example, a slot number.

The "unit type" indicates the type of PSU41, for example, the type of a product (model, option, etc.) unit. This is because the amount of power supplied to the PSU 41 differs depending on the manufacturer, product (model, option, etc.) and the like. The unit type may be set to setting information such as FRU (Field Replacement Unit) information stored in the PSU 41, for example.

The "unit identification signal" indicates information for identifying the PSU 41.

“Supplyable current (peak current) [A]” indicates a current value that can be supplied by the PSU 41. The supplyable current value may mean a current value that can be supplied by the PSU 41, including a temporary (momentary) peak current value generated in the load unit. In this way, the PSU table 321b may be set with a supplyable current value according to the type of PSU 41 identified by the AC PON signal.

The current value that can be supplied by the PSU 41 may be a specification on the catalog provided by the manufacturer or distributor of the PSU 41, or may be an actually measured value measured in advance by the administrator of the server 2.

The unit identification signals in the unit table 321a and the PSU table 321b may be expressed as a combination signal of High (1) / Low (0), respectively. The combination signal may be assigned to each load unit and each PSU41. For example, the unit identification signal may be notified from the load unit or the PSU 41 to the control unit 32 by the existing IF used in the server 2.

As an example, the PSU 41 may output an AC PON signal via the communication path 8 (see FIG. 3) when the AC power plug of the cable 4a is connected to the power strip 12-1. This AC PON signal is an example of a power feeding signal, and may be a combination signal assigned to the PSU 41 described above.

The identification signal receiving circuit 322 may be connected to each of the load units such as the system unit 5 and the I / O unit 6 via the communication path 9 (see FIG. 3), and may receive the unit identification signal from each of the load units. .. When the identification signal receiving circuit 322 receives the unit identification signal, the identification signal receiving circuit 322 may transmit (transfer) the unit identification signal to the PSU number calculation circuit 324.

As described above, the load unit has a resident power supply (standby power supply) from the power strip 12-2 or 12-3 even when the resident power supply from the PSU 41 is not supplied (the switching SW31 is in the OFF state). The supply can transmit a unit identification signal.

The AC PON signal receiving circuit 323 is connected to each of the PSU 41s via a communication path 8 (see FIG. 3), and the AC power plug of the cable 4a receives the AC PON signal from the PSU 41 connected to the power strip 12-1. It's okay. When the AC PON signal receiving circuit 323 receives the AC PON signal from the PSU 41, the AC PON signal receiving circuit 323 may transmit (transfer) the AC PON signal to the PSU number calculation circuit 324.

The communication paths 8 and 9, respectively, may be, for example, communication lines, or may be connectors that directly connect the PSU 41 or the load unit and the relay board 3 (without using a cable). ..

The PSU number calculation circuit 324 may calculate the number of PSUs 41 that can withstand (can supply) the supply of the total peak current value of the load units mounted on the server 2. In other words, the PSU number calculation circuit 324 may calculate the number of PSU 41s for supplying a current value equal to or larger than the total value of the inrush currents of the load units.

For example, when the PSU number calculation circuit 324 receives the unit identification signal of the load unit from the identification signal reception circuit 322, the PSU number calculation circuit 324 receives the peak current value from the entry of the load unit corresponding to the unit identification signal to the unit table 321a. It's okay.

Further, when the PSU number calculation circuit 324 receives the AC PON signal from the AC PON signal receiving circuit 323, the PSU number calculation circuit 324 identifies the unit type with respect to the PSU 41 (PSU 41 indicated by the unit identification signal) that has transmitted the AC PON signal.

For example, the PSU number calculation circuit 324 instructs the PSU 41 to transmit the FRU information set in the PSU 41 by an I2C (Inter-Integrated Circuit) signal or the like, and the unit type included in the FRU information received from the PSU 41. You may read the information. Next, the PSU number calculation circuit 324 may receive the supplyable current value from the entry of the PSU 41 corresponding to the unit type and the unit identification signal to the PSU table 321b.

Then, the PSU number calculation circuit 324 divides, for example, the total value of the peak current values of the load units by the supplyable current value of the PSU 41 (1 unit), and rounds up the value after the decimal point of the division result to the number of PSU 41s. It may be calculated as (target number).

The PSU number calculation circuit 324 may control the display unit 33 to display the calculated number (target number).

The PSU number calculation circuit 324 determines whether or not the number of PSUs currently connected to the power tap 12-1 has reached the target number each time the AC PON signal is received from the AC PON signal receiving circuit 323. When it reaches, ON control may be instructed to the switching control circuit 325.

In this way, the PSU number calculation circuit 324 can acquire (receive) various current values by using the preset unit table 321a and PSU table 321b, and the current values can be accurately or at high speed. Can be compared and judged.

Further, by using the PSU table 321b in which the power supply amount is set for each type of PSU 41, it is possible to cope with the case where a plurality of types of PSU 41 are adopted (introduced) in the server 2.

The switching control circuit 325 controls the switch of the switching SW 31 to the ON state (closed state) according to the ON control instruction from the PSU number calculation circuit 324.

The DC / DC conversion circuit 326 converts the resident power supply (DC power supply) supplied from the PSU 41 connected to the power strip 12-1 into DC-DC, and converts the converted DC power supply into blocks 321 to 325 in the control unit 32. , And output to the display unit 33.

As described above, according to the control unit 32, when the supplyable current value of one or more PSU 41s connected to the power strip 12-1 reaches the total peak current value (inrush current) of the load unit, the switching unit 31 As a result, the states of the power supply paths 7a and 7b are switched and controlled to the connected states.

On the other side, according to the control unit 32, the current value that can be supplied to one or more PSUs 41 connected to the power strip 12-1 is the load unit from the state where the PSU41 is not connected to the power strip 12-1. It remains disconnected until the total inrush current is reached. That is, the connection (power supply) from the PSU 41 to the load unit is suspended (restricted).

As a result, even if the switching unit 31 is turned on and the entire inrush current of the load unit of the server 2 is generated, the current corresponding to the inrush current can be supplied by the plurality of PSU 41s to which the AC power is already supplied. Therefore, the operation of the Hiccup function can be suppressed, and the shutdown of the output (DC) of the PSU 41 can be prevented, so that stable operation of the server 2 can be realized.

In addition, it is possible to eliminate the need to introduce an outlet box having a power switch, a high-performance PSU, and control the power ON / OFF timing by a management device. Further, it is possible to eliminate the need to set different time constants for the inrush prevention circuit of the load unit, and it is possible to suppress an increase in the number of products (number of parts).

From the above, according to the method according to the embodiment, the power supply control in the server 2 can be easily or at low cost.

[1-4] Operation Example Next, an operation example of power supply control by the server 2 will be described with reference to FIG. 7. FIG. 7 is a flowchart showing an operation example of power supply control by the server 2 according to the embodiment.

In the following description, the PSU 41 and the load unit are connected to each other via the relay board 3, and the power strip 12-2 or 12-3 is connected to each load unit, respectively. And. Further, it is assumed that each PSU 41 (PSU # 1 to PSU # n in the example of FIG. 3) is not connected to the power strip 12-1.

For example, the operator connects PSU # 1 (see FIG. 3) to the power strip 12-1 by the cable 4a. As a result, power is supplied from PSU # 1 to the relay board 3 via the power supply path 7a, and an AC PON signal is output from PSU # 1 to the control unit 32 via the communication path 8.

The control unit 32 receives power from PSU # 1 connected to the power strip 12-1 and is activated (step S1). For example, the DC / DC conversion circuit 326 converts the power input from PSU # 1 into DC-DC, and outputs the power to each circuit module (reference numerals 321 to 325, 33; see FIG. 4).

Further, the AC PON signal receiving circuit 323 receives the AC PON signal from PSU # 1 (step S2), and transmits (transfers) the received AC PON signal to the PSU number calculation circuit 324. The AC PON signal may be a high / low combination signal (unit identification signal).

The identification signal receiving circuit 322 receives a unit identification signal from each of the load units operated by the standby power supply supplied from the power strip 12-2 or 12-3, and outputs (transfers) to the PSU number calculation circuit 324.

The PSU number calculation circuit 324 calculates the total electric energy of the load unit connected to the server 2 based on the unit identification signal received from the identification signal receiving circuit 322 (step S3).

For example, the PSU number calculation circuit 324 requests the unit table 321a stored in the memory device 321 to transmit the peak current (A) corresponding to the unit identification signal, and the peak current (A) received from the memory device 321. May be calculated.

Further, the PSU number calculation circuit 324 acquires the unit type and the amount of power that can be supplied to the PSU 41 (PSU # 1) to which AC power is supplied, based on the AC PON signal received from the AC PON signal reception circuit 323 (step). S4).

For example, the PSU number calculation circuit 324 requests PSU # 1 to transmit FRU information including the unit type by an I2C signal via a communication path (not shown), and receives FRU information from PSU # 1. You can do it. Further, the PSU number calculation circuit 324 may extract the unit type from the received FRU information. Further, the PSU number calculation circuit 324 requests the PSU table 321b stored in the memory device 321 to transmit the unit identification signal and / or the supplyable current (A) corresponding to the unit type, and supplies the current from the memory device 321. The possible current (A) may be received.

Then, the PSU number calculation circuit 324 calculates the number of PSUs 41 for supplying the total electric energy of the load units connected to the server 2 (step S5). For example, the PSU number calculation circuit 324 divides the total of the peak current values calculated in step S3 by the supplyable current value of PSU # 1, and rounds up the value after the decimal point of the division result to the number of PSUs 41 (target number). ) May be calculated.

The PSU number calculation circuit 324 controls the display unit 33 to display the calculated number (target number) of the PSU 41 calculated in step S5 (step S6).

For example, the operator confirms whether or not the number of PSUs 41 connected to the power strip 12-1 has reached the number (target number) displayed on the display unit 33, and powers the PSU41 until the target number is reached. Connect to taps 12-1 in sequence.

The PSU number calculation circuit 324 determines whether or not the number of PSUs 41 that have received the AC PON signal has reached the calculated number (step S7).

When the number of PSUs 41 that have received the AC PON signal has not reached the calculated number (No in step S7), the PSU number calculation circuit 324 waits for the reception of the next AC PON signal (No in step S8 and step S8). When the next AC PON signal is received (Yes in step S8), the process proceeds to step S7.

When the number of PSUs 41 that have received the AC PON signal reaches the calculated number (Yes in step S7), the PSU number calculation circuit 324 instructs the switching control circuit 325 to control the switching SW31 to the ON state. The switching control circuit 325 controls the switching SW 31 to be in the ON state (step S9), and the process ends.

By controlling the switching SW 31 to the ON state, the power supply paths 7a and 7b are connected, and standby power is supplied to each of the load units from the plurality of PSU 41s.

The processing shown in FIG. 7 is not limited to the above-mentioned processing order and processing content. For example, the process of step S3 and the process of step S4 may be executed in the reverse order or may be executed in parallel.

[2] Others The technique according to the above-described embodiment can be modified or modified as follows.

For example, each functional block of the control unit 32 shown in FIG. 4 may be merged or divided in any combination.

[3] Additional notes The following additional notes will be further disclosed with respect to the above embodiments.

(Appendix 1)
A switching unit that switches the state of the power supply path for supplying power from a plurality of power supply devices to a plurality of system modules equipped with an information processing device to either a connected state or a disconnected state.
Based on the power supply signal output when the power supply device is connected to the power supply source, the supplyable current value that can be supplied by one or more power supply devices connected to the power supply source is calculated, and the supplyable current is calculated. When the value reaches the total value of the inrush currents of the plurality of system modules, the switching control unit controls the switching unit to switch the state of the power supply path from the disconnected state to the connected state. And, a power supply control device.

(Appendix 2)
It has a storage area for storing the first information in which the supplyable current value for each power supply device identified by the power supply signal is set.
The switching control unit calculates a supplyable current value that can be supplied by one or more power supply devices connected to the power supply source based on the power supply signal and the first information, according to Appendix 1. Power control device.

(Appendix 3)
In the first information, a supplyable current value according to the type of the power supply device identified by the power supply signal is set.
The switching control unit is supplied by one or more power supply devices connected to the power supply source based on the type of the power supply device identified by the power supply signal, the power supply signal, and the first information. The power supply control device according to Appendix 2, which calculates a possible supplyable current value.

(Appendix 4)
It has a storage area for storing the second information in which the inrush current value for each system module identified by the module identification signal is set.
The switching control unit receives a module identification signal from each of the plurality of system modules provided by the information processing apparatus, and based on the received module identification signal and the second information, the total value of the inrush current. The power supply control device according to any one of Supplementary note 1 to 3, wherein the power supply control device is calculated.

(Appendix 5)
Equipped with a display unit that can display information indicating numerical values,
The switching control unit calculates and calculates the number of power supply devices for supplying a current value equal to or higher than the total value of the inrush current based on the supplyable current value and the total value of the inrush current. The power supply control device according to any one of Supplementary note 1 to 4, which controls the display of the number of units to be displayed on the display unit.

(Appendix 6)
Equipped with a display unit that can display information indicating numerical values,
The power supply control device according to any one of Supplementary note 1 to 4, wherein the switching control unit controls to display at least one of the supplyable current value and the total value of the inrush current on the display unit. ..

(Appendix 7)
The switching control unit supplies power to the switching unit from the state in which the power supply device is not connected to the power supply source until the supplyable current value reaches the total value of the inrush current. The power supply control device according to any one of Supplementary note 1 to 6, which controls to maintain the state of the supply path in the disconnected state.

(Appendix 8)
With multiple power supply devices,
With multiple system modules
Equipped with a power control device,
The power supply control device is
A switching unit that switches the state of the power supply path for supplying power from the plurality of power supply devices to the plurality of system modules to either a connected state or a disconnected state.
Based on the power supply signal output when the power supply device is connected to the power supply source, the supplyable current value that can be supplied by one or more power supply devices connected to the power supply source is calculated, and the supplyable current is calculated. When the value reaches the total value of the inrush currents of the plurality of system modules, the switching control unit controls the switching unit to switch the state of the power supply path from the disconnected state to the connected state. An information processing device equipped with.

(Appendix 9)
The power supply control device is
It has a storage area for storing the first information in which the supplyable current value for each power supply device identified by the power supply signal is set.
The switching control unit calculates a supplyable current value that can be supplied by one or more power supply devices connected to the power supply source based on the power supply signal and the first information, as described in Appendix 8. Information processing equipment.

(Appendix 10)
In the first information, a supplyable current value according to the type of the power supply device identified by the power supply signal is set.
The switching control unit is supplied by one or more power supply devices connected to the power supply source based on the type of the power supply device identified by the power supply signal, the power supply signal, and the first information. The information processing apparatus according to Appendix 9, which calculates a possible supplyable current value.

(Appendix 11)
The power supply control device is
It has a storage area for storing the second information in which the inrush current value for each system module identified by the module identification signal is set.
The switching control unit receives a module identification signal from each of the plurality of system modules provided by the information processing apparatus, and based on the received module identification signal and the second information, the total value of the inrush current. The information processing apparatus according to any one of Supplementary note 8 to 10, wherein the information processing apparatus is calculated.

(Appendix 12)
Equipped with a display unit that can display information indicating numerical values,
The switching control unit calculates and calculates the number of power supply devices for supplying a current value equal to or higher than the total value of the inrush current based on the supplyable current value and the total value of the inrush current. The information processing apparatus according to any one of Supplementary note 8 to 11, which controls the display of the number of units to be displayed on the display unit.

(Appendix 13)
Equipped with a display unit that can display information indicating numerical values,
The information processing apparatus according to any one of Supplementary note 8 to 11, wherein the switching control unit controls to display at least one of the supplyable current value and the total value of the inrush current on the display unit. ..

(Appendix 14)
The switching control unit supplies power to the switching unit from a state in which the power supply device is not connected to the power supply source until the supplyable current value reaches the total value of the inrush current. The information processing apparatus according to any one of Supplementary note 8 to 13, which controls the state of the supply path to be maintained in the disconnected state.

1 Information processing system 10 Rack 11 AC power supply 12, 12-1 to 12-3 Power strip 2, 2-1 to 2-m server 3 Relay board 31 Switching SW
32 Control unit 321 Memory device 321a Unit table 321b PSU table 322 Identification signal reception circuit 323 AC PON signal reception circuit 324 PSU number calculation circuit 325 Switching control circuit 326 DC / DC conversion circuit 33 Display unit 4, 4-1 to 4-n Power supply 4a, 5a, 6a cable 41 PSU
42 Fan 5, 5-1 to 5-i System unit 6, 6-1 to 6-j I / O unit 7a, 7b Power supply path 8, 9 Communication path

Claims (8)

A switching unit that switches the state of the power supply path for supplying power from a plurality of power supply devices to a plurality of system modules equipped with an information processing device to either a connected state or a disconnected state.
Based on the power supply signal output when the power supply device is connected to the power supply source, the supplyable current value that can be supplied by one or more power supply devices connected to the power supply source is calculated, and the supplyable current is calculated. When the value reaches the total value of the inrush currents of the plurality of system modules, the switching control unit controls the switching unit to switch the state of the power supply path from the disconnected state to the connected state. And, a power supply control device. It has a storage area for storing the first information in which the supplyable current value for each power supply device identified by the power supply signal is set.
The switching control unit calculates a supplyable current value that can be supplied by one or more power supply devices connected to the power supply source based on the power supply signal and the first information, according to claim 1. The power control device described. In the first information, a supplyable current value according to the type of the power supply device identified by the power supply signal is set.
The switching control unit is supplied by one or more power supply devices connected to the power supply source based on the type of the power supply device identified by the power supply signal, the power supply signal, and the first information. The power supply control device according to claim 2, which calculates a possible supplyable current value. It has a storage area for storing the second information in which the inrush current value for each system module identified by the module identification signal is set.
The switching control unit receives a module identification signal from each of the plurality of system modules provided by the information processing apparatus, and based on the received module identification signal and the second information, the total value of the inrush current. The power supply control device according to any one of claims 1 to 3, wherein the power control device is calculated. Equipped with a display unit that can display information indicating numerical values,
The switching control unit calculates and calculates the number of power supply devices for supplying a current value equal to or higher than the total value of the inrush current based on the supplyable current value and the total value of the inrush current. The power supply control device according to any one of claims 1 to 4, which controls the display of the number of units to be displayed on the display unit. Equipped with a display unit that can display information indicating numerical values,
The power supply control according to any one of claims 1 to 4, wherein the switching control unit controls to display at least one of the supplyable current value and the total value of the inrush current on the display unit. Device. The switching control unit supplies power to the switching unit from the state in which the power supply device is not connected to the power supply source until the supplyable current value reaches the total value of the inrush current. The power supply control device according to any one of claims 1 to 6, which controls the state of the supply path so as to maintain the disconnected state. With multiple power supply devices,
With multiple system modules
Equipped with a power control device,
The power supply control device is
A switching unit that switches the state of the power supply path for supplying power from the plurality of power supply devices to the plurality of system modules to either a connected state or a disconnected state.
Based on the power supply signal output when the power supply device is connected to the power supply source, the supplyable current value that can be supplied by one or more power supply devices connected to the power supply source is calculated, and the supplyable current is calculated. When the value reaches the total value of the inrush currents of the plurality of system modules, the switching control unit controls the switching unit to switch the state of the power supply path from the disconnected state to the connected state. An information processing device equipped with.

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