JP2016164911A - Cooling control device, circuit board, cooling method, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a cooling control device which efficiently performs cooling control even when the cooling efficiency of air cooling for an IO card varies according to a position of an IO slot.SOLUTION: A cooling control device 1 includes: a slot specification part which specifies a slot, into which an extended card is inserted, from among slots 121, 122, 123, 124; and a wind force determination part which determines intensity of wind generated by a blower 132 on the basis of the slot specified by the slot specification part.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a cooling control device, a circuit board, a cooling method, and a program.

  In the cooling control device described in Patent Document 1, the necessity of unit cooling and the wind speed are determined based on the comparison result between the actual power consumption of the units connected to each slot and the maximum power consumption of the unit design value. Is determined. Hereinafter, the “slot” is also referred to as an IO (input / output) slot or an expansion slot. Hereinafter, the “unit” is also referred to as an IO card or an expansion card.

JP 2011-151332 A

  In a device having a plurality of IO slots such as the device described in Patent Document 1, the cooling efficiency of air cooling for the IO card may vary depending on the position of the IO slot. In this case, if the device determines the strength of the wind speed in accordance with, for example, the IO slot having the lowest cooling efficiency, the cooling may be excessive. That is, there is a problem that cooling control may not be performed efficiently depending on the apparatus.

  An object of the present invention is to provide a cooling control device, a circuit board, a cooling method, and a program that solve the above-described problems.

  In order to solve the above problems, a cooling control apparatus according to an aspect of the present invention is based on a slot specifying unit that specifies a slot in which an expansion card is inserted among a plurality of slots, and the slot specified by the slot specifying unit. And a wind force determining unit that determines the strength of the wind to be blown by the blower.

  The circuit board according to one aspect of the present invention includes a plurality of slots into which expansion cards can be inserted, and a blower that sends wind having a strength corresponding to the slots into which the expansion cards are inserted to the plurality of slots. Prepare.

  The cooling method according to one aspect of the present invention includes a step of identifying a slot in which an expansion card is inserted among a plurality of slots, and a step of determining the intensity of air to be blown to the blower based on the identified slot. And have.

  In addition, a program according to an aspect of the present invention allows a computer to send air to a blower based on a slot specifying unit that specifies a slot in which an expansion card is inserted from a plurality of slots, and the slot specified by the slot specifying unit. It functions as a wind force determination unit that determines the strength of the wind to be generated.

  According to at least one aspect described above, the cooling control device can control the wind speed to an intensity corresponding to the slot in which the expansion card is inserted, so that the cooling control can be efficiently performed.

It is a schematic block diagram for demonstrating the structure of the cooling control apparatus which concerns on embodiment of this invention. FIG. 2 is a plan view schematically showing an example of a positional relationship between a FAN (fan) 132 and IO slots # 1 121 to # 4 124 shown in FIG. 1. It is explanatory drawing for demonstrating the operation example of the cooling control apparatus 1 shown in FIG. It is explanatory drawing for demonstrating the operation example of the cooling control apparatus 1 shown in FIG. 3 is a flowchart for explaining an operation example of the cooling control device 1 shown in FIG. 1. It is a schematic block diagram which shows the basic composition of the cooling control apparatus 1 shown in FIG. It is a schematic block diagram which shows the basic composition of the motherboard 200 shown in FIG.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a schematic block diagram for explaining a configuration example of a cooling control apparatus 1 according to an embodiment of the present invention. In the configuration example illustrated in FIG. 1, the cooling control device 1 is included in the server device 10. The cooling control device 1 includes a BMC (Baseboard Management Controller) control unit 100 and an IO card information management table 101. FIG. 1 shows a part of hardware included in the server device 10 and software for controlling the hardware, divided into blocks. The server device 10 includes a CPU (central processing unit), a main storage device, an auxiliary storage device, an input / output device, a communication device, and the like (not shown). The server device 10 executes a program such as an OS (operating system) 141 stored in an auxiliary storage device, for example, by the CPU.

  In the server apparatus 10 shown in FIG. 1, a plurality of temperature sensors such as a temperature sensor (CPU) 111, a temperature sensor (MB) 112, and a temperature sensor (HDD) 113 are arranged at various locations. Here, MB is an abbreviation for a mother board (also called a circuit board), and HDD is an abbreviation for a hard disk drive. A temperature sensor (CPU) 111 detects the temperature inside, on or near the CPU, and outputs a signal 110 indicating the detection result. The temperature sensor (MB) 112 detects the temperature at or near the MB and outputs a signal 110 indicating the detection result. A temperature sensor (HDD) 113 detects the temperature inside, on or near the HDD, and outputs a signal 110 indicating the detection result.

  The server device 10 further includes an OS 141, an IO slot # 1 121, an IO slot # 2 122, an IO slot # 3 123, an IO slot # 4 124, a FAN control unit 131, and a FAN 132.

  The BMC control unit 100 illustrated in FIG. 1 includes a processor and a memory. The BMC control unit 100 manages the operation of each unit of the server device 10 independently or in cooperation with the OS 141 by causing the processor to execute a predetermined program. For example, the BMC control unit 100 has a function of monitoring the performance of an IO card connected to the IO slots # 1 121 to # 4 124 in cooperation with the OS 141 (hereinafter referred to as a performance monitoring function). The BMC control unit 100 uses this performance monitoring function to obtain an IO performance value 140, which is information representing the operation rate of each IO card, from the OS 141 at a certain interval via a basic input / output system (BIOS). get. The IO performance value 140 is information (for example, Max (maximum value), Typical (representative value), Idle (value at the time of idling), etc.) representing an operation level for each type of IO card.

  In this embodiment, the BMC control unit 100 inputs a predetermined signal 110 or 120 between the temperature sensors 111, 112, 113, etc., the IO slots # 1 121 to # 4 124, and the FAN control unit 131. Output. As described above, the signal 110 is a signal representing temperature information output from the temperature sensors 111, 112, 113, and the like. The signal 120 is a signal that is input / output to / from an IO card (not shown) inserted into the IO slots # 1 121 to # 4 124, and is a signal that represents IO card information such as an IO card type. Details of each function of the BMC control unit 100 will be described later.

  The IO slot # 1 121, the IO slot # 2 122, the IO slot # 3 123, and the IO slot # 4 124 detachably connect various types of IO cards. Some IO cards have relatively low power consumption, such as network cards and FC (fiber channel) cards, and some have relatively high power consumption, such as SSD (solid state drive) mounted cards. That is, the IO card has different power consumption depending on its type.

  The FAN control unit 131 controls the rotation speed of the FAN 132 based on a signal 130 that instructs the rotation speed (rotation speed) of the FAN output from the BMC control unit 100. Here, the signal 130 is a signal representing a command value for the FAN rotation speed. The FAN 132 is a blower, and is installed in a direction in which wind is blown or sucked in with respect to the installation positions of the IO slots # 1 121 to # 4 124. The rotational speed of the FAN 132 is controlled by the FAN control unit 131.

  Here, an example of the positional relationship between the FAN 132 and the IO slots # 1 121 to # 4 124 will be described with reference to FIG. FIG. 2 is a plan view schematically showing an example of the positional relationship between the FAN 132 and the IO slots # 1 121 to # 4 124 shown in FIG. In FIG. 2, four IO slots # 1 121 to # 4 124 are provided on the motherboard 200 included in the server device 10. The motherboard 200 is provided with one FAN 132 for cooling one or more IO cards inserted into the four IO slots # 1 121 to # 4 124. In FIG. 2, the direction and the amount of wind sent from the FAN 132 are schematically shown by broken-line arrows. That is, the direction of the arrow represents the direction of the wind, and the width of the arrow represents the magnitude of the air volume. As shown in FIG. 2, the air sent from the FAN 132 does not have an equal air volume in each of the IO slots # 1 121 to # 4 124. As shown in FIG. 2, there are places where strong airflow can be secured, such as IO slot # 2 122 and IO slot # 3 123, but there is a wind at the end such as IO slot # 1 121 and IO slot # 4 124. There are places where it cannot flow and get strong airflow. Further, when there is an obstacle such as a component mounted on the motherboard 200 between the FAN 132 and the IO slots # 1 121 to # 4 124, there may be a slot portion where a strong airflow cannot be obtained. The FAN 132 may be attached to the mother board 200, or may be attached to a housing or the like (not shown) of the server device 10.

  Next, functions of the BMC control unit 100 will be described in detail. In the present embodiment, the BMC control unit 100 calculates a corrected power consumption value necessary for actual cooling control, and determines an optimum FAN rotation speed from the corrected power consumption value. The corrected power consumption value varies depending on the type of each IO card connected to the IO slots # 1 121 to # 4 124, the cooling efficiency varies depending on the mounting slot position of each IO card, and the operation. It is calculated on the basis of the size of the IO operation rate that varies depending on the performance value of each IO card at the time. Therefore, the BMC control unit 100 has the following functions.

  That is, the BMC control unit 100 detects the mounting state of the IO card by inputting / outputting a predetermined signal to / from an IO card (not shown) via the IO slots # 1 121 to # 4 124. It has a function of acquiring information related to the mounting slot position.

  Further, the BMC control unit 100 accesses an IO card (not shown) via the IO slots # 1 121 to # 4 124, and acquires identification information such as a vendor ID (vendor identification code) and a device ID. The BMC control unit 100 has a function of recognizing the type of the IO card based on the identification information.

  Further, the BMC control unit 100 has a function of associating and managing in the IO information management table 101 information relating to the mounting slot position of each IO card and information representing the type of each IO card. In the present embodiment, the IO information management table 101 is a generic name for a plurality of types of tables indicating a correspondence relationship between a plurality of data corresponding to IO slots and IO cards. The IO card information 102 is a generic name for a plurality of types of data included in the IO information management table 101. The IO information management table 101 may be stored in a memory included in the BMC control unit 100 or may be stored in a predetermined memory provided outside the BMC control unit 100.

  FIG. 3A is a diagram for explaining a configuration example of a table 101-1 that is one of the tables included in the IO information management table 101. The table 101-1 is a table that associates the information related to the mounting slot position of each IO card and the information indicating the type of each IO card. In the table 101-1 shown in FIG. 3A, for each IO slot number that is identification information of the IO slots # 1 121 to # 4 124, the data indicating the type of the installed IO card or the IO card is not installed. Are associated with each other. In the example shown in FIG. 3A, in the table 101-1, an IO card B with medium power consumption is mounted in the IO slot # 1, and an IO card C with low power consumption is mounted in the IO slot # 2. This indicates that an IO card A with high power consumption is mounted in the IO slot # 3, and no IO card is mounted in the IO slot # 4.

  Further, the BMC control unit 100 has a function of holding and managing in the IO information management table 101 information representing the cooling efficiency for each IO slot, which has been obtained in advance by actual measurement or simulation, in association with the IO slot number. FIG. 3B is a diagram for describing a configuration example of a table 101-2 that is one of the tables included in the IO information management table 101. The table 101-2 is a table for associating information regarding the mounting slot position of each IO card with information representing the cooling efficiency for each IO slot. The table 101-2 shown in FIG. 3B associates data representing the cooling efficiency for each IO slot with each IO slot number that is identification information of the IO slots # 1 121 to # 4 124. . The table 101-2 includes data representing the cooling efficiency for each IO slot when the FAN 132 and the IO slots # 1 121 to # 4 124 are arranged as shown in FIG. The table 101-2 sets the cooling efficiency of the IO slot # 2 122 and the IO slot # 3 123 that receive the most FAN 132 wind to 1.0, and the cooling efficiency of the IO slot # 1 and the IO slot # 4 where the wind slightly leaks to the end. Is represented as 0.8. That is, in the example shown in FIG. 3B, the table 101-2 shows the cooling efficiency of each slot when the cooling efficiency of the slot with the highest cooling efficiency is normalized to 1.0, and the slot with the highest cooling efficiency. It represents with the value of the ratio with respect to the cooling efficiency.

  In addition, the BMC control unit 100 associates the power consumption value according to the operation level of the IO card (for example, the above-described three levels of Max, Typical, and Idle) with the type of the IO card in the IO information management table 101. It has a function to maintain and manage. The power consumption value is obtained in advance by specifications, actual measurement, or simulation. FIG. 3C is a diagram for describing a configuration example of a table 101-3 that is one of the tables included in the IO information management table 101. The table 101-3 is a table for associating information representing the type of each IO card with information representing the power consumption value corresponding to the operation level of each IO card. The table 101-3 shown in FIG. 3C corresponds to the data indicating the power consumption value for each operation level for the data indicating the type of the mounted IO card or the data indicating that the IO card is not mounted. Store with attachments. The power consumption values stored in the table 101-3 are, for example, Max operation (high load), Typical operation (medium load), and Idle operation (low load) for each of the IO card A, IO card B, and IO card C. The power consumption value when operating with is obtained by spec, actual measurement or simulation. The table 101-3 also includes the power consumption value when the mounted IO card is not mounted. In the example shown in FIG. 3C, in the table 101-3, for the IO card A, power consumption 50W during Max operation, power consumption 25W during Typical operation, and power consumption during Idle operation (low load). 3W is associated.

  Further, the BMC control unit 100 has a function of calculating a corrected power consumption value according to an actual operation state of each IO card according to an IO card type, an IO card mounting slot position, and an IO card operation level. . That is, the BMC control unit 100 refers to the IO information management table 101, acquires the power consumption value of the IO card based on the IO card type and the operation level of the IO card, and uses the acquired power consumption value of the IO card. By correcting based on the cooling efficiency by the mounting slot position, the corrected power consumption value corresponding to the actual mounting position and operation state of the IO card is calculated.

Further, the BMC control unit 100 uses the corrected power consumption value of each IO card to calculate the minimum number of rotations of the FAN 132 required for cooling according to the mounting status of the IO card and the power consumption in the IO information management table 101. The table is selected with reference to the FAN rotation speed. Then, the BMC control unit 100 outputs the FAN control unit 131 by adding the FAN rotation number necessary for cooling a processor such as a CPU and a basic module such as a memory to the rotation number corresponding to the IO card. A control signal 130 for instructing the rotational speed is set. FIG. 3D is a diagram for explaining a configuration example of a table 101-4 that is one of the tables included in the IO information management table 101. The table 101-4 is a table for associating the corrected power consumption value, which is the corrected power consumption value of each IO card, with the FAN rotation speed required to keep the temperature at that time constant. The table 101-4 shows, for example, the correspondence between the corrected power consumption value obtained in advance by actual measurement or simulation and the FAN rotational speed necessary for cooling the actually mounted IO card for each of a plurality of rotational speed regions. To store. In the example shown in FIG. 3D, in the table 101-4, for example, for an area where the corrected power consumption value is 0 W (= min ⁻¹ ) and the corrected power consumption value is greater than 0 W and less than or equal to 2 W. 200 rpm is associated.

  FIG. 4 schematically shows the relationship between the temperature and the FAN rotation speed during operation of the present embodiment. The horizontal axis represents the temperature in the server device 10, and the vertical axis represents the rotation speed of the FAN 132. A thick broken line 301 represents a FAN rotational speed necessary for cooling a processor such as a CPU and a basic module such as a memory. A thin broken line 300 represents the FAN rotational speed obtained by adding the rotational speed for the IO card converted to the maximum power consumption to the FAN rotational speed 301 for cooling the basic module. A thick solid line represents a change in the actual FAN rotation speed under the control of the BMC control unit 100. In the example shown in FIG. 4, the temperature on the horizontal axis has a tendency to increase with time.

  The relationship between the temperature and the FAN rotation speed is generally controlled such that the rotation speed increases stepwise as the temperature rises as FAN rotation speed control of the entire server apparatus 10.

  For example, when no IO card is mounted, a command value for the FAN rotational speed can be set from the value for the basic module, such as the rotational speed 301 calculated with the minimum power consumption set to 0 [W]. That is, 0 [rpm] can be set as the FAN rotational speed for the IO card in terms of the FAN rotational speed from the table 101-4.

  Next, for easy understanding of the case where the IO card is mounted, first, the case where the rotational speed is not adjusted according to the IO card type, the IO card mounting slot position and the IO card operating level will be described. Next, the case of adjusting will be described.

  When the control according to the type of IO card, the slot position and the operation level is not performed, the BMC control unit 100 predicts the temperature around the IO card based only on the information of few temperature sensors, and the value of the rotational speed is the maximum consumption. The rotation speed is 300 as calculated by electric power. That is, in the example shown in FIG. 3, it is assumed that the IO card A with the largest power consumption is mounted in the IO slot # 1 121 or the IO slot # 4 124 having a low cooling efficiency and the IO operation rate is maximized. In this case, in the example, the power consumption value is calculated as power consumption 50 [W] at the time of Max operation of the IO card A ÷ cooling efficiency 0.8 = 62.5 [W], and this is FAN rotation from the table 101-4. When converted into a number, the FAN rotation speed is set to 700 [rpm].

On the other hand, when performing control according to the type of IO card, the slot position, and the operation level, the BMC control unit 100 performs rotation speed control according to the following procedure. That is, the BMC control unit 100 calculates the number of rotations 302 to be corrected by the mounted IO card type and the mounted position according to the IO card mounted position and the IO card type. The BMC control unit 100 subtracts the rotation speed 302 from the rotation speed 300 calculated with the maximum power consumption, and performs static rotation speed control based on the rotation speed indicated by the chain line. Further, the BMC control unit 100 calculates the rotation speed 303 to be corrected with the IO performance status per unit time from the operating status of the IO card. The BMC control unit 100 performs dynamic rotational speed control by subtracting the rotational speed 303 from the rotational speed indicated by the chain line.
That is, when the control according to the mounting slot position and the operation level is not performed, the FAN rotation speed includes a large margin corresponding to the rotation speed difference 304 without correction shown in FIG. On the other hand, the FAN rotational speed according to the present embodiment is an appropriate rotational speed obtained by subtracting the rotational speed 302 corrected by the installed IO card type and mounting position and the rotational speed 303 corrected by the IO performance status per unit time. The number (thick solid line characteristics), and the margin can be reduced.

  Next, the operation of the cooling control device 1 shown in FIG. 1 will be described with reference to FIG. FIG. 5 shows a control flow of the FAN rotation speed by the BMC control unit 100. In the flow of FIG. 5, the cooling efficiency (1) corresponds to 1.0 in FIG. 3 (A), and the cooling efficiency (2) corresponds to 0.8 in FIG. 3 (A).

  The BMC control unit 100 recognizes whether or not an IO card is mounted based on a presence signal of each IO slot when the IO card is initialized. When an IO card is mounted, the BMC control unit 100 determines the mounted IO card type for each IO slot by acquiring identification information such as the vendor ID and device ID of the IO card. For example, in the case of PCI Express (registered trademark), the identification information is acquired by reading the configuration space. Then, the BMC control unit 100 writes and holds the information of the table 101-1 in FIG. 3 in the IO card information management table 101 (400).

  The BMC control unit 100 uses the configuration of the IO card that is statically recognized until the OS is started, and the number of rotations corrected by the installed IO card type and the mounting position from the number of rotations 300 (FIG. 4) calculated with the maximum power consumption. The FAN rotational speed (characteristic of the chain line) obtained by subtracting 302 (FIG. 4) is set. In other words, in the example illustrated in FIG. 3, the BMC control unit 100 includes the IO card A having the largest power consumption than the tables 101-1 and 101-2 illustrated in FIG. The FAN rotation speed is set based on the case where becomes the maximum. The power consumption corrected by the type and position of the mounted IO card is 50 [W] power consumption during Max operation of the IO card A ÷ cooling efficiency 1.0 = 50 [W]. The BMC control unit 100 converts the power consumption 50 W into the FAN rotation speed from the table 101-4 in FIG. 3 and sets the FAN rotation speed 600 [rpm]. Then, the BMC control unit 100 starts monitoring the IO performance after the OS is started, and the IO power value 104 at a certain interval and the table 101-3 in FIG. The IO card is extracted (401).

  For example, when the IO card extracted in step (401) is the IO card A at the time of a typical operation from the IO performance value 104, the BMC control unit 100 determines the operation level of the IO card A from the table 101-3 in FIG. 25 [W] is determined as the power consumption during (typical operation). Next, the BMC control unit 100 determines that the cooling efficiency is 1.0 from the table 101-2 in FIG. From these pieces of information, the BMC control unit 100 calculates the power consumption value obtained by correcting the rotation speed 302 corrected by the mounted IO card type and mounting position and the rotation speed 303 corrected by the IO performance status per unit time. The corrected power consumption value is the power consumption 25 [W] at the operation level (typical operation) of the IO card A / cooling efficiency (1.0) = 25 [W]. Therefore, the BMC control unit 100 sets 500 [rpm] in terms of the FAN rotation speed from the table 101-4 of FIG. 3 (402, 403, 405). Thereafter, the BMC control unit 100 continues the IO performance monitoring.

  Thereby, according to this embodiment, the BMC control part 100 can reduce FAN rotation speed. Specifically, the BMC control unit 100 sets the FAN rotation speed to 700 [pm, which is the rotation speed calculated based on the maximum power consumption when the control according to the type of the IO card, the mounting slot position, and the operation level is not performed. ], It can be suppressed to 600 [rpm] of the number of rotations corrected by the type of the mounted IO card and the mounting position. Furthermore, the BMC control unit 100 can correct the FAN rotation speed to 500 [rpm], which is the rotation speed corrected in the IO performance status per unit time, and can suppress the rotation speed to the minimum FAN rotation speed.

  The other cases in the flow of FIG. 5 are the same, and the IO card extracted in step (401) is mounted in IO slot # 1 or # 4 by IO card A (404), or the case of IO card B In the case of (406, 407, 408, 409) and IO card C (410, 411, 412, 413), the optimum FAN rotation speed can be determined by the same control flow. If no IO card is installed in any IO slot, the BMC control unit 100 sets the power consumption for the IO card to 0 [W] and sets the FAN rotation speed to 0 [rpm] (414).

  As described above, the server device 10 according to the present embodiment includes four slots, that is, the IO slot # 1 121, the IO slot # 2 122, the IO slot # 3 123, and the IO slot # 4 124 as the IO slots. These IO slots 121 to 124 are cooled by controlling the FAN 132 via the FAN control unit 131. The IO card information management table 101 is a storage unit that stores an IO card mounting position, an IO card type, and an IO card operating status. The BMC control unit 100 acquires temperature information 110 from various temperature sensors, monitors each IO performance when the OS is operating, acquires an IO performance value 140, and IO card information with the IO card management table 101. By updating and acquiring 102, the optimum FAN rotation speed is determined, and the FAN rotation speed 130 is set in the FAN control unit 131. According to this configuration, the optimal FAN rotation with a small margin is possible depending on the mounting status, type, and operating status of the IO card without having to obtain detailed information by mounting a large number of hardware such as temperature sensors in each IO slot. Since the number can be set, there is an efficient power consumption reduction effect according to the machine configuration and machine operation status. Further, since an excessive FAN rotation speed including a large margin is not set, there is an effect that the noise of FAN can be reduced.

The embodiment of the present invention is not limited to the above. For example, the above embodiment is an example in the case where there is one FAN, but the cooling efficiency based on the positional relationship between the FAN and the IO slot can also be applied to a configuration having two or more FANs. For example, there is no partition between two FANs, and the IO slot between the two FANs is cooled by receiving wind from both FANs, so the cooling efficiency of this IO slot can be set high. .
In addition, for example, there is a large device-specific part between the FAN and a specific IO slot, and even if the device has a special structure in which the wind does not easily hit the IO slot, the cooling efficiency can be improved by taking this effect into account. It can also be reflected.

  In the above embodiment, the rotational speed is controlled based on the IO card with the maximum power consumption (IO card A in the above example), but this is required in view of the power consumption and the slot position. It can also be controlled based on the highest wind power. That is, in step (401) of FIG. 5, the BMC control unit 100 calculates the corrected power consumption value for each IO card based on the power consumption and the slot position, and the rotation speed corresponding to the calculated corrected power consumption value. Are extracted from the IO card information management table 101. In step (401), the BMC control unit 100 can compare the rotational speeds of the IO cards extracted from the IO card information management table 101 and extract the IO card having the maximum rotational speed.

  Next, the basic configuration of the embodiment of the present invention will be described with reference to FIGS. FIG. 6 is a schematic block diagram showing the basic configuration of the cooling control apparatus 1 according to the present invention. In the above-described embodiment, the configuration illustrated in FIG. 1 is described as an embodiment of the cooling control device 1, but the basic configuration of the cooling control device 1 is as illustrated in FIG. 6. That is, the cooling control device 1 has the basic configuration of the slot specifying unit 2 and the wind power determining unit 3. The slot specifying unit 2 specifies the slot 4 in which the expansion card 5 is inserted among the plurality of slots 4. The wind force determining unit 3 determines the strength of the wind to be blown to the blower 6 based on the slot 4 specified by the slot specifying unit 2. Thereby, the cooling control apparatus 1 can reduce power consumption, cooling the expansion card 5 appropriately.

  FIG. 7 is a schematic block diagram showing a basic configuration of a circuit board according to the present invention. In the above-described embodiment, the configuration illustrated in FIGS. 1 and 2 has been described as an embodiment of the cooling control device 1 and the motherboard 200. However, the basic configuration of the motherboard 200 is as illustrated in FIG. That is, the circuit board 7 has a plurality of slots 4 and the blower 6 as a basic configuration. An expansion card 5 can be inserted into the plurality of slots 4. The blower 6 sends wind having a strength corresponding to the slot 4 in which the expansion card 5 is inserted to the plurality of slots 4. Thereby, the circuit board 7 can reduce power consumption, cooling the expansion card 5 appropriately.

  1, 2, and 5, the process of step (400) executed by the BMC control unit 100 corresponds to the slot specifying unit 2, and the steps (401) and (404) or ( 405) corresponds to the wind power determination unit 3. Further, the processing of steps (401) and (402) executed by the BMC control unit 100 corresponds to the power consumption specifying unit. Further, the process of step (400) executed by the BMC control unit 100 corresponds to the type specifying unit. Moreover, the process of step (400) which the BMC control part 100 performs respond | corresponds to a cooling efficiency specific | specification part. The IO card information management table 101 corresponds to the cooling efficiency storage unit.

  Further, for example, the blocks shown in FIG. 1 can be appropriately integrated, divided, or distributed. For example, the cooling control device 1 is configured without using the BMC control unit 100 or integrally using the processor of the server device 10 and the OS 141, or the cooling control device 1 is part or all of the functions of the FAN control unit 131. Can be provided. A part or all of the program executed by the processor of the present embodiment can be distributed via a computer-readable recording medium or a communication line.

DESCRIPTION OF SYMBOLS 1 Cooling control apparatus 2 Slot specification part 3 Wind power determination part 4 Slot 5 Expansion card 6 Blower 7 Circuit board 10 Server apparatus 100 BMC control part 101 IO card information management table 121 IO slot # 1
122 IO slot # 2
123 IO slot # 3
124 IO slot # 4
131 FAN controller 132 FAN
141 OS
200 Motherboard

Claims (9)

A slot identifying unit that identifies a slot in which an expansion card is inserted among a plurality of slots;
A cooling control device comprising: a wind force determining unit that determines the intensity of wind to be blown by a blower based on the slot specified by the slot specifying unit. A power consumption specifying unit for specifying the power consumption of the expansion card;
The cooling control device according to claim 1, wherein the wind force determination unit further determines the intensity of the wind to be blown to the blower based on the power consumption specified by the power consumption specification unit. A type specifying unit for specifying the type of the expansion card;
The cooling control device according to claim 1, wherein the wind power determination unit further determines the intensity of the wind to be blown to the blower based on the type specified by the type specifying unit. A cooling efficiency storage unit that stores the cooling efficiency of the expansion card inserted into the slot by the blower for each slot;
A cooling efficiency specifying unit that specifies the cooling efficiency stored in the cooling efficiency storage unit in association with the slot specified by the slot specifying unit;
The cooling control according to any one of claims 1 to 3, wherein the wind power determination unit further determines the strength of the air blown to the blower based on the cooling efficiency specified by the cooling efficiency specifying unit. apparatus. When the wind power determining unit has a plurality of expansion cards inserted into the slot, the blower is based on the slot into which the expansion card with the highest power consumption is inserted among the slots specified by the slot specifying unit. The cooling control device according to any one of claims 1 to 4, wherein the strength of air to be blown is determined. Multiple slots for inserting expansion cards,
A circuit board comprising: a blower for sending wind having a strength corresponding to the slot into which the expansion card is inserted to the plurality of slots. The circuit board according to claim 6, further comprising the cooling control device according to claim 1. Identifying a slot in which an expansion card is inserted among a plurality of slots;
Determining the intensity of the air to be blown to the blower based on the identified slot. Computer
A slot identifying unit for identifying a slot in which an expansion card is inserted among a plurality of slots;
The program for functioning as a wind power determination part which determines the intensity | strength of the wind blown to a fan based on the slot which the said slot specific part specified.

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