JP2020145325A - Control device, storage rack, fan control system, fan control method, and computer program - Google Patents

Abstract

To provide a technology for preventing an occurrence of a heat pool situation in which temperature of a part of a region rises in a housing of a storage rack for storing an electronic device.SOLUTION: A control device 45 includes an acquisition unit 46 and a fan control unit 47. The acquisition unit 46 acquires information on the rotational speed of an air-cooled fan of an electronic device disposed within a housing of a storage rack storing an electronic device equipped with an air-cooled fan or information on temperature of exhaust air emitted from an inside of the electronic device to the outside. The fan control unit 47 drives and controls an exhaust fan to ensure that an air flow rate of exhaust air by the exhaust fan, which exhausts air from the inside of the storage rack housing to the outside, is not less than an air flow rate of exhaust air discharged from the inside of the electronic device to the outside using the information acquired by the acquisition unit 46.SELECTED DRAWING: Figure 10

Description

The present invention relates to drive control of a fan that exhausts air from the housing of a storage rack that houses electronic devices.

Electronic devices such as network devices and servers used for network connection may be aggregated and stored in a storage rack. There is a type of storage rack provided with a fan installed in the housing of the storage rack and exhausting air from the inside of the housing to the outside. By exhausting from the inside of the housing to the outside by driving the fan, the heat generated from the electronic device is discharged to the outside of the housing, thereby suppressing the temperature rise inside the housing (inside the storage rack). ing. The drive control of the fan is performed, for example, by increasing or decreasing the rotation speed of the fan according to the sensor output value of the temperature sensor that detects the temperature in the storage rack.

In Patent Document 1 (Japanese Unexamined Patent Publication No. 2017-54216), the power consumption of the information processing device housed in the rack device is obtained, and the opening and closing of the intake / exhaust duct is controlled according to the obtained power consumption. The configuration is shown. Further, in Patent Document 2 (Japanese Unexamined Patent Publication No. 2010-43817), the inside of the server room is divided into a hot zone in which a rack for accommodating the server is arranged and a cool zone in which the server is not arranged. It is shown. Further, Patent Document 2 discloses a configuration in which the air volume by the blower is controlled so that the air volume from the hot zone to the cool zone and the air volume from the cool zone to the hot zone are substantially equal to each other.

Japanese Unexamined Patent Publication No. 2017-54216 JP-A-2010-43817

By the way, as described above, in order to suppress the temperature rise in the storage rack, a part of the area in the storage rack (for example, close to the floor surface) is exhausted by driving the fan. The temperature of the area) may rise. If there is a heat-sensitive component (for example, a communication module such as a QSFP (Quad Small Form-factor Pluggable) provided in the cable terminal portion) in the region where the temperature rises, the component will be thermally damaged. There is concern that things will happen.

The present invention has been devised to solve the above problems. That is, a main object of the present invention is to provide a technique for preventing a situation in which the temperature of a part of a region rises in the housing of a storage rack for storing electronic devices (hereinafter, also referred to as a heat pool). ..

In order to achieve the above object, one form of the control device according to the present invention is
Information on the rotation speed of the air-cooled fan of the electronic device arranged in the housing of the storage rack for storing the electronic device provided with the air-cooled fan, or the temperature of the exhaust discharged from the inside of the electronic device to the outside. The acquisition department that acquires information and
Using the information acquired by the acquisition unit, the air volume of the exhaust from the exhaust fan that exhausts air from the inside of the housing of the storage rack to the outside is less than the air volume of the exhaust exhausted from the inside of the electronic device to the outside. It is provided with a fan control unit that drives and controls the exhaust fan so as not to be present.

One form of the storage rack according to the present invention is
A housing for storing electronic devices equipped with an air-cooled fan,
An exhaust fan provided in the housing that exhausts air from inside the housing to the outside,
The control device of the present invention is provided.

One form of the fan control system according to the present invention is
Information on the rotation speed of the air-cooled fan of the electronic device arranged in the housing of the storage rack for storing the electronic device provided with the air-cooled fan, or the temperature of the exhaust discharged from the inside of the electronic device to the outside. A monitoring device equipped with an acquisition unit that acquires information,
Using the information acquired by the acquisition unit, the air volume of the exhaust from the exhaust fan that exhausts air from the inside of the housing of the storage rack to the outside is lower than the air volume of the exhaust exhausted from the inside of the electronic device to the outside. It is provided with a fan control device that drives and controls the exhaust fan so as not to be present.

One form of the fan control method according to the present invention is
Information on the rotation speed of the air-cooled fan of the electronic device arranged in the housing of the storage rack for storing the electronic device provided with the air-cooled fan, or the temperature of the exhaust discharged from the inside of the electronic device to the outside. Get information,
Using the information acquired by the acquisition unit, the air volume of the exhaust gas exhausted from the inside of the housing of the storage rack to the outside is less than the air volume of the exhaust gas discharged from the inside of the electronic device to the outside. The exhaust fan is driven and controlled so as not to be present.

A form of computer program according to the present invention is
Information on the rotation speed of the air-cooled fan of the electronic device arranged in the housing of the storage rack for storing the electronic device equipped with the air-cooled fan, or the temperature of the exhaust gas discharged from the inside of the electronic device to the outside. The process of getting information and
Using the information acquired by the acquisition unit, the air volume of the exhaust from the exhaust fan that exhausts air from the inside of the housing of the storage rack to the outside is less than the air volume of the exhaust exhausted from the inside of the electronic device to the outside. The computer is made to execute the process of driving and controlling the exhaust fan so as not to be present.

According to the present invention, it is possible to prevent the occurrence of a heat pool situation in which the temperature of a part of the area rises in the housing of the storage rack for storing the electronic device.

It is a figure explaining the internal structure of the storage rack provided with the control device of 1st Embodiment which concerns on this invention. It is a figure which shows an example of the internal structure of the electronic device stored in a storage rack. It is a block diagram which shows the structure of the control device of 1st Embodiment simply. It is a flowchart which shows an example of the operation in the control device of 1st Embodiment. It is a flowchart which shows an example of another operation in the control device of 1st Embodiment. It is a figure explaining the structure of the fan control system of 2nd Embodiment. It is a figure explaining the structure of the storage rack to which the fan control system of 2nd Embodiment is applied. It is a figure explaining another embodiment of a fan control system. It is a figure explaining the internal structure of the electronic device in 3rd Embodiment. It is a figure explaining another embodiment of the control device which concerns on this invention. It is a figure explaining another embodiment of the storage rack which concerns on this invention. It is a figure explaining another embodiment of the fan control system which concerns on this invention.

Hereinafter, embodiments according to the present invention will be described with reference to the drawings.

<First Embodiment>
FIG. 1 is a diagram illustrating an internal configuration of a storage rack provided with a control device according to the first embodiment of the present invention. The storage rack 1 has a housing 2 for storing electronic devices. In the example of FIG. 1, a plurality of servers 11 and a network switch 12 for controlling the network connection of the servers 11 are housed as electronic devices in the inside 2a of the housing 2.

FIG. 2 is a diagram for simplifying an example of the internal configuration of an electronic device such as a server 11 and a network switch 12 housed in a housing 2. In the example of FIG. 2, the electronic device includes a processor 31 such as a CPU (Central Processing Unit) and a storage device 32 such as a semiconductor memory. The processor 31 and the storage device 32 are housed inside the housing 30. An air cooling fan 34 is arranged inside the housing 30. The air-cooled fan 34 has an air supply port (not shown) provided in the housing 30, an arrangement area of the processor 31 and the storage device 32, and an exhaust port (not shown) provided in the housing 30. The processor 31 and the like are air-cooled by generating ventilation in the path through which the processor 31 and the like are passed. Further, an air supply temperature sensor 35 is provided inside the housing 30. The air supply temperature sensor 35 is arranged upstream of the arrangement area (air cooling target area) of the processor 31 and the storage device 32 in the ventilation path driven by the air cooling fan 34, and the ventilation (supply) flowing into the air cooling target area. Q) temperature is detected. For example, the rotation speed of the air cooling fan 34 is controlled according to the temperature detected by the air supply temperature sensor 35.

In the first embodiment, the server 11 is equipped with a BMC (Base Management Controller), which is a management controller. This BMC has a configuration according to a standard specification by IPMI (Intelligent Platform Management Interface), and the description of the configuration is omitted here.

The housing 2 of the storage rack 1 of the first embodiment is formed with an opening of a storage space 2a in which an electronic device having an internal configuration as described above is stored, and the opening can be opened and closed by the door 3. Is provided in the housing 2. The door 3 has a configuration for passing exhaust air from the storage space 2a of the housing 2 to the outside of the housing 2. Further, an exhaust fan 4 (a plurality of exhaust fans 4 in the example of FIG. 1) is mounted on the door 3, and the door 3 is passed from the storage space 2a of the housing 2 to the outside by driving the exhaust fan 4. Is exhausted. The housing 2 is provided with an air supply hole (not shown) for supplying air to the storage space 2a from the outside, for example, in the housing portion facing the door 3.

Further, the door 3 is provided with a heat receiving portion 6 of a circulation path 5 in which a refrigerant for cooling the exhaust gas passing through the door 3 circulates. That is, in the circulation path 5, the refrigerant circulates through a heat receiving unit 6 that cools the exhaust by exchanging heat with the refrigerant and a heat radiating unit (not shown) that dissipates heat to the refrigerant and cools the refrigerant. It is a road. The heat receiving portion 6 of the circulation path 5 is provided on the door 3 so as to be located in the ventilation path of the exhaust gas driven by the exhaust fan 4. The circulation path 5 is provided with a refrigerant temperature sensor 7 that detects the temperature of the refrigerant flowing into the heat receiving unit 6.

Further, the housing 2 is provided with a temperature sensor 8 that detects the temperature of the storage space 2a. In the first embodiment, the temperature sensor 8 is installed at a position where the temperature of the exhaust gas on the upstream side of the heat receiving unit 6 is detected in the ventilation path of the exhaust gas driven by the exhaust fan 4.

Furthermore, the housing 2 is provided with a control device 10. The control device 10 has a function of driving and controlling the exhaust fan 4. In the first embodiment, the control device 10 is connected to the BMC of the server 11 housed inside the housing 2 of the storage rack 1, and information can be acquired from the BMC. Further, the control device 10 is also connected to the network switch 12, and information can be acquired from the network switch 12.

FIG. 3 is a block diagram showing the configuration of the control device 10 in a simplified manner. The control device 10 includes a processor 20 such as a CPU and a storage device 21.

The storage device 21 is a storage medium for storing a computer program (hereinafter, also referred to as a program) 27 and various data. There are various types of storage media such as a hard disk device and a semiconductor memory. Here, any type of storage medium may be adopted as the storage device 21, and the description of the configuration of the storage medium will be omitted. Further, a plurality of types of storage media may be provided in the control device 10, but even in such a case, they are collectively referred to as the storage device 21 here for convenience.

The processor 20 can have a function based on the program 27 by reading the program 27 of the storage device 21 and executing the program 27. For example, in the first embodiment, the processor 20 includes an acquisition unit 23, a lower limit value setting unit 24, and a fan control unit 25 as functional units.

The acquisition unit 23 has a function of acquiring the sensor output value of the refrigerant temperature sensor 7 and the sensor output value of the temperature sensor 8 at predetermined timings (for example, at predetermined time intervals). Further, the acquisition unit 23 receives information on the rotation speed of the air-cooled fan 34 from the BMC of each server 11 housed in the housing 2 of the storage rack 1 at a predetermined timing (for example, at predetermined time intervals). It also has a function to acquire it. Further, the acquisition unit 23 also has a function of acquiring information on the rotation speed of the air cooling fan 34 provided in the network switch 12 in the same manner as described above.

Furthermore, the acquisition unit 23 has a function of registering the acquired sensor output value in the storage device 21 in association with information such as sensor identification information for identifying the source sensor and the output time (or acquisition time) of the sensor output value. May be provided. Further, the acquisition unit 23 has a function of registering the rotation speed information of the air-cooled fan 34 acquired from the server 11 or the like in the storage device 21 in association with information such as identification information for identifying the acquisition source server 11 and acquisition time. You may have it.

The lower limit value setting unit 24 has a function of setting a lower limit value of the rotation speed of the exhaust fan 4 in order to prevent a situation where heat is accumulated inside the housing 2 of the storage rack 1. That is, as for the heat pool inside the housing 2, the air volume by the air cooling fan 34 of the server 11 is larger than the air volume by the exhaust fan 4 of the housing 2, and the ventilation inside the housing 2 smoothly passes through the door 3 to the outside. It is thought that this is because it is not discharged to the air. For this reason, the lower limit value setting unit 24 has a function of variably setting the lower limit value of the rotation speed of the exhaust fan 4 so that the air volume by the exhaust fan 4 of the housing 2 does not fall below the air volume by the air cooling fan 34 of the server 11. ..

In the first embodiment, the lower limit value setting unit 24 uses the information on the rotation speeds of the air-cooled fan 34 of the server 11 and the network switch 12 for setting the lower limit value of the rotation speeds of the exhaust fan 4. That is, the air volume driven by the fan increases or decreases in proportion to the rotation speed of the fan. For this reason, the lower limit value setting unit 24 multiplies the rotation speed of the air-cooled fan 34 acquired by the acquisition unit 23 by a proportional constant determined in advance based on the performance of the air-cooled fan 34 and obtains the air volume by the air-cooled fan 34. calculate. In the first embodiment, since a plurality of servers 11 and a network switch 12 are housed inside the housing 2 and there are a plurality of air-cooled fans 34, the lower limit value setting unit 24 determines the air volume by each air-cooled fan 34. After the calculation, the total air volume by the air-cooled fans 34 is calculated. The lower limit value setting unit 24 sets the sum of the calculated air volumes as the lower limit value of the air volume by the exhaust fan 4, and uses the lower limit value of the air volume and the proportionality constant predetermined by the performance of the exhaust fan 4 and the like. Then, the lower limit of the rotation speed of the exhaust fan 4 is calculated. When a plurality of exhaust fans 4 are provided, the lower limit value setting unit 24 determines that the total air volume driven by the plurality of exhaust fans 4 is the lower limit value of the air volume set as described above. The rotation speed is calculated as the lower limit of the rotation speed.

The fan control unit 25 uses the sensor output value of the refrigerant temperature sensor 7 and the sensor output value of the temperature sensor 8 acquired by the acquisition unit 23 to set the temperature of the exhaust discharged from the housing 2 to the outside. It has a function of controlling the rotation speed of the exhaust fan 4 so as to reach the temperature. The method by which the fan control unit 25 controls the rotation speed of the exhaust fan 4 is not limited here. However, in the first embodiment, the fan control unit 25 rotates the exhaust fan 4 within the rotation speed range from the lower limit value set by the lower limit value setting unit 24 to the upper limit value determined by the specifications of the exhaust fan 4. Control the number. That is, the upper limit value and the lower limit value of the rotation speed range for variably controlling the rotation speed of the exhaust fan 4 are set in advance according to the performance and specifications of the exhaust fan 4, and usually exhaust within the set fixed rotation speed range. The rotation speed of the fan 4 is controlled. On the other hand, in the first embodiment, the lower limit value of the rotation speed of the exhaust fan 4 is variably set by the lower limit value setting unit 24 according to the drive control status of the air cooling fan 34 such as the server 11. Therefore, the fan control unit 25 also performs the following processing.

For example, the fan control unit 25 calculates a candidate value of the rotation speed for controlling the exhaust fan 4 within the fixed rotation speed range as described above. Then, the fan control unit 25 compares the calculated candidate value with the lower limit value of the rotation speed set by the lower limit value setting unit 24, and if the candidate value is equal to or more than the lower limit value, sets the candidate value. Determined as the target value for the number of revolutions. On the other hand, the fan control unit 25 compares the candidate value with the lower limit value set by the lower limit value setting unit 24, and when the candidate value is less than the lower limit value, the lower limit value set by the lower limit value setting unit 24 is set to the target value of the rotation speed. Confirmed as. Then, the fan control unit 25 controls the rotation speed of the exhaust fan 4 so as to reach the target value of the rotation speed determined in this way.

The control device 10 of the first embodiment and the storage rack 1 provided with the control device 10 are configured as described above. Next, an example of a control operation for setting the lower limit value of the exhaust fan 4 in the control device 10 and an example of an operation for driving and controlling the exhaust fan 4 will be described with reference to FIGS. 4 and 5. Note that FIG. 4 is a flowchart showing a processing process for setting the lower limit value of the exhaust fan 4, and FIG. 5 is a flowchart showing a processing process for driving and controlling the exhaust fan 4.

For example, the lower limit value setting unit 24 of the control device 10 acquires information on the rotation speed of the air cooling fan 34 from the server 11 and the network switch 12 (step S1 in FIG. 4). Then, the lower limit value setting unit 24 calculates the air volume by the air-cooled fan 34 by multiplying the acquired rotation speed by a proportional constant given in advance by the performance of the air-cooled fan 34 or the like (step S2). Further, the lower limit value setting unit 24 calculates the total air volume of the air-cooled fans 34 of all the electronic devices of the server 11 and the network switch 12 housed inside the housing 2 (step S3). After that, the lower limit value setting unit 24 calculates the lower limit value of the rotation speed of the exhaust fan 4 from the calculated sum of the air volumes by using the proportionality constant predetermined and given by the performance of the exhaust fan 4. (Step S4). After that, the lower limit value setting unit 24 prepares for the timing next to the start of the predetermined process, and executes the operations after step S1 when the timing of the start of the process is reached.

The fan control unit 25 executes a processing process related to drive control of the exhaust fan 4 as shown in FIG. That is, the fan control unit 25 calculates a candidate value for the rotation speed of the exhaust fan 4 by using the temperature information from the sensor output values of the refrigerant temperature sensor 7 and the temperature sensor 8 (step S11). Then, the fan control unit 25 compares the calculated candidate value with the lower limit value of the rotation speed of the exhaust fan 4 calculated by the lower limit value setting unit 24, and determines whether or not the candidate value is equal to or greater than the lower limit value. (Step S12). As a result of this comparison, when the candidate value is equal to or higher than the lower limit value, the fan control unit 25 determines the candidate value as the target value of the rotation speed of the exhaust fan 4 (step S13). On the other hand, when the candidate value is not equal to or more than the lower limit value (the candidate value is less than the lower limit value), the fan control unit 25 determines the lower limit value as the target value of the rotation speed of the exhaust fan 4 (step S14). Then, the fan control unit 25 controls the rotation speed of the exhaust fan 4 so as to reach the target value of the rotation speed determined in this way. Such a series of processes of the fan control unit 25 is repeated.

As described above, the storage rack 1 of the first embodiment includes the housing 2, the exhaust fan 4, and the control device 10. In the control device 10, the air volume of the exhaust fan 4 is that of an electronic device such as a server 11. It has a function of setting a lower limit of the rotation speed of the exhaust fan 4 so as not to fall below the air volume of the air cooling fan 34. As a result, the control device 10 and the storage rack 1 provided with the control device 10 can prevent the air volume from the exhaust fan 4 from falling below the air volume from the air cooling fan 34. Therefore, the control device 10 and the storage rack 1 provided with the control device 10 can prevent heat accumulation inside the housing 2 due to the air volume of the exhaust fan 4 being less than the air volume of the air cooling fan 34. It is possible to prevent thermal damage to parts and devices due to the heat of the heat pool.

<Second Embodiment>
The second embodiment according to the present invention will be described below. In the second embodiment, one embodiment of the fan control system will be described. In the description of the second embodiment, the same reference numerals are given to the components having the same names as the components constituting the control device, the storage rack, and the electronic device (server and network switch) in the first embodiment, and the common parts thereof. Duplicate explanation is omitted.

FIG. 6 is a block diagram showing a simplified configuration of an embodiment of the fan control system according to the second embodiment. The fan control system 15 of the second embodiment includes a monitoring device 16 and a fan control device 17. The monitoring device 16 includes an acquisition unit 23 and a lower limit value setting unit 24. In the second embodiment, as shown in FIG. 7, one of the servers 11 stored in the storage rack 1 also functions as the monitoring device 16. That is, the processor 31 of the server 11 that also has a function as the monitoring device 16 realizes the acquisition unit 23 and the lower limit value setting unit 24 by executing the program. The functions of the acquisition unit 23 and the lower limit value setting unit 24 are the same as those of the acquisition unit 23 and the lower limit value setting unit 24 described in the first embodiment.

The fan control device 17 has the same function as the fan control unit 25 described in the first embodiment, and is realized by the processor 20 of the control device 10 of the storage rack 1. That is, the fan control device 17 acquires information from the acquisition unit 23 and the lower limit value setting unit 24 in the monitoring device 16, and also acquires temperature information from the refrigerant temperature sensor 7 and the temperature sensor 8 and uses the acquired information. Then, it has a function of driving and controlling the exhaust fan 4. In the drive control of the exhaust fan 4 by the fan control device 17, the lower limit of the rotation speed range for variably controlling the rotation speed of the exhaust fan 4 is the lower limit set by the lower limit value setting unit 24, as in the first embodiment. The value.

Since the fan control system 15 of the second embodiment has the same functions as the acquisition unit 23, the lower limit value setting unit 24, and the fan control unit 25 described in the first embodiment, the control device of the first embodiment The same effect as that of 10 and the storage rack 1 provided with the 10 can be obtained. That is, the fan control system 15 of the second embodiment can prevent the generation of heat pool inside the housing 2 due to the air volume of the exhaust fan 4 being less than the air volume of the air-cooled fan 34, and can reduce the heat of the heat pool. It is possible to prevent thermal damage to parts and equipment caused by this.

In the second embodiment, an example in which the monitoring device 16 is realized by the server 11 housed in the storage rack 1 is described. Instead of this, as shown in FIG. 8, the monitoring device 16 may be realized by a server 40 outside the housing 2 of the storage rack 1. The server 40 is stored in, for example, another storage rack.

<Third Embodiment>
The third embodiment according to the present invention will be described below. In the description of the third embodiment, the same reference numerals are given to the components and the same names of the control device, the storage rack, and the electronic device (server and network switch) described in the first and second embodiments. The duplicate description of the common part is omitted.

In the third embodiment, the exhaust temperature sensor 36 as shown in FIG. 9 is provided inside the housing 30 of the electronic devices (server 11 and network switch 12) housed inside the housing 2. There is. The exhaust temperature sensor 36 is arranged downstream from the air-cooled target area (arrangement area of the processor 31 and the storage device 32) in the ventilation path driven by the air-cooled fan 34, and the ventilation (exhaust) passing through the air-cooled target area. Detects the temperature of.

In electronic devices such as servers, it is common that only the supply air temperature sensor 35 out of the supply air temperature sensor 35 and the exhaust temperature sensor 36 is provided, but here, the supply air temperature sensor 35 and the exhaust temperature sensor are provided. Both 36 are provided.

The acquisition unit 23 of the control device 10 or the monitoring device 16 acquires information on the rotation speed of the air cooling fan 34 as described in the first and second embodiments from the server 11 and the network switch 12. It has a function of acquiring the sensor output value of the exhaust temperature sensor 36. That is, the acquisition unit 23 acquires the sensor output value of the exhaust temperature sensor 36 from the BMC of the server 11 and the network switch 12 in the same manner as when acquiring the information on the rotation speed of the air cooling fan 34.

Further, the lower limit value setting unit 24 sets the lower limit value of the exhaust fan 4 by using the air volume based on the rotation speed of the air cooling fan 34 as described in the first and second embodiments. Then, the lower limit value of the exhaust fan 4 is set by using the temperature of the exhaust gas by the exhaust temperature sensor 36. For example, the lower limit value setting unit 24 has the exhaust detection temperature of the exhaust temperature sensor 36 acquired at the same acquisition timing from all the electronic devices (server 11 and network switch 12) arranged inside the housing 2. , Extract the highest detection temperature. The detected temperature extracted in this way is used as information according to the air volume by the air cooling fan 34 of the electronic device. That is, it is assumed that the change in the temperature detected by the exhaust temperature sensor 36 and the change in the air volume due to the air cooling fan 34 have the same tendency. From this, the relationship data between the detection temperature of the exhaust temperature sensor 36 and the lower limit of the rotation speed of the exhaust fan 4 for setting the lower limit of the rotation speed of the exhaust fan 4 using the detection temperature of the exhaust temperature sensor 36. Is obtained in advance by simulation or the like and registered in the storage device 21. The lower limit value setting unit 24 sets the lower limit value of the rotation speed of the exhaust fan 4 based on such relational data and the detected temperature of the extracted exhaust temperature sensor 36. Also in the third embodiment, the set lower limit value of the rotation speed of the exhaust fan 4 prevents the air volume by the exhaust fan 4 from falling below the air volume by the air cooling fan 34, as in the first and second embodiments. It is a value to be used.

The configurations other than the above in the third embodiment are the same as the configurations of the control device 10 and the storage rack 1 of the first embodiment or the configuration of the fan control system of the second embodiment, and the duplicate description thereof will be omitted here. .. Also in the third embodiment, since the lower limit value of the rotation speed of the exhaust fan 4 is set as described above, the same effect as that of the first embodiment can be obtained. That is, in the third embodiment, it is prevented that the air volume by the exhaust fan 4 is less than the air volume by the air cooling fan 34. Therefore, in the third embodiment, the generation of heat pool inside the housing 2 due to the air volume of the exhaust fan 4 being less than the air volume of the air cooling fan 34 is prevented, and the parts and parts due to the heat of the heat pool are prevented. Prevents thermal damage to the equipment.

<Fourth Embodiment>
The fourth embodiment according to the present invention will be described below. In the description of the fourth embodiment, the same reference numerals are given to the components having the same names as the components of the control device, the storage rack, and the electronic device (server and network switch) described in the first to third embodiments. The duplicate description of the common part is omitted.

In the fourth embodiment, as in the third embodiment, the server 11 and the network switch 12 housed in the storage rack 1 include the exhaust temperature sensor 36. The acquisition unit 23 of the control device 10 or the monitoring device 16 acquires the sensor output value (detection temperature) of the exhaust temperature sensor 36 from the server 11 and the network switch 12 instead of the information on the rotation speed of the air cooling fan 34.

In the fourth embodiment, the lower limit value setting unit 24 of the control device 10 or the monitoring device 16 is omitted. The fan control unit 25 or the fan control device 17 of the control device 10 uses the sensor output value (detection temperature) of the exhaust temperature sensor 36 acquired by the acquisition unit 23 instead of the sensor output value of the temperature sensor 8. The exhaust fan 4 is driven and controlled. The detection temperature of the exhaust temperature sensor 36 used here is, for example, among the detection temperatures of the exhaust by the exhaust temperature sensor 36 acquired from all the servers 11 and the network switch 12 inside the housing 2 at the same acquisition timing. This is the highest detection temperature.

As described above, the detection temperature of the exhaust gas by the exhaust temperature sensor 36 shows a high and low change similar to the increase and decrease of the air volume by the air cooling fan 34 of the server 11 or the network switch 12. From this, the fan control unit 25 or the fan control device 17 of the control device 10 drives and controls the exhaust fan 4 by using the temperature detected by the exhaust temperature sensor 36 instead of the temperature detected by the temperature sensor 8. The same effect as that of the first to third embodiments can be obtained.

Further, since the temperature detected by the exhaust temperature sensor 36 is used instead of the temperature detected by the temperature sensor 8, the temperature sensor 8 can be omitted.

<Other Embodiments>
The present invention is not limited to the first to fourth embodiments, and various embodiments can be adopted. For example, FIG. 10 is a block diagram showing a configuration of another embodiment of the control device according to the present invention. The control device 45 in FIG. 10 includes an acquisition unit 46 and a fan control unit 47. The acquisition unit 46 is information on the rotation speed of the air-cooling fan of the electronic device arranged in the housing of the storage rack for accommodating the electronic device equipped with the air-cooling fan, or the exhaust discharged from the inside of the electronic device to the outside. It has a function to acquire information about temperature. The fan control unit 47 uses the information acquired by the acquisition unit 46 to exhaust air from the inside of the housing of the storage rack to the outside. The air volume of the exhaust from the exhaust fan is discharged from the inside of the electronic device to the outside. It has a function to drive and control the exhaust fan so that the air volume does not fall below the air volume. The control device 45 having such a configuration is provided in, for example, the storage rack 50 as shown in FIG. That is, the storage rack 50 in FIG. 11 includes the above-mentioned control device 45 in addition to the housing 51 and the exhaust fan 52. The housing 51 has a configuration for accommodating an electronic device provided with an air cooling fan. The exhaust fan 52 is installed in the housing 51 so as to exhaust air from the inside of the housing to the outside.

In the control device 45 in FIG. 10 and the storage rack 50 in FIG. 11, the air volume of the exhaust gas exhausted by the exhaust fan that exhausts air from the inside of the storage rack housing to the outside is lower than the air volume of the exhaust gas discharged from the inside of the electronic device to the outside. Drive and control the exhaust fan so that there is no such thing. Therefore, the control device 45 and the storage rack 50 can obtain the same effects as those in the first to fourth embodiments.

FIG. 12 is a block diagram showing a configuration of another embodiment of the fan control system according to the present invention. The fan control system 54 in FIG. 12 includes a monitoring device 55 and a fan control device 56. The monitoring device 55 includes an acquisition unit 57. The acquisition unit 57 is information on the rotation speed of the air-cooling fan of the electronic device arranged in the housing of the storage rack for accommodating the electronic device equipped with the air-cooling fan, or the exhaust discharged from the inside of the electronic device to the outside. It has a function to acquire information about temperature.

The fan control device 56 uses the information acquired by the acquisition unit 57 to exhaust the exhaust air from the inside of the housing of the storage rack to the outside, and the air volume of the exhaust from the exhaust fan is discharged from the inside of the electronic device to the outside. It has a function to drive and control the exhaust fan so that the air volume does not fall below the air volume.

The fan control system 54 can also obtain the same effects as those in the first to fourth embodiments.

1,50 Storage rack 2,51 Housing 4,52 Exhaust fan 7 Refrigerator temperature sensor 8 Temperature sensor 10,45 Control device 11 Server 12 Network switch 15,54 Fan control system 16,55 Monitoring device 17,56 Fan control device 23 , 46, 57 Acquisition unit 24 Lower limit value setting unit 25, 47 Fan control unit 36 Exhaust temperature sensor

Claims (9)

Information on the rotation speed of the air-cooled fan of the electronic device arranged in the housing of the storage rack for storing the electronic device provided with the air-cooled fan, or the temperature of the exhaust discharged from the inside of the electronic device to the outside. The acquisition department that acquires information and
Using the information acquired by the acquisition unit, the air volume of the exhaust from the exhaust fan that exhausts air from the inside of the housing of the storage rack to the outside is lower than the air volume of the exhaust exhausted from the inside of the electronic device to the outside. A control device including a fan control unit that drives and controls the exhaust fan so as not to be present. Using the information acquired by the acquisition unit, the air volume of the exhaust gas exhausted by the exhaust fan that exhausts air from the inside of the housing of the storage rack to the outside is less than the air volume of the exhaust gas discharged from the inside of the electronic device to the outside. Further provided with a lower limit value setting unit for setting the lower limit value of the rotation speed of the exhaust fan so as not to occur.
The fan control unit acquires predetermined information used for driving control of the exhaust fan, and uses the acquired information to set the rotation speed of the exhaust fan by the lower limit value setting unit. The control device according to claim 1, which is set within a rotation speed range from a lower limit value to a predetermined upper limit value, and drives and controls the exhaust fan based on the set rotation speed. The information acquired and used by the fan control unit includes the sensor output value of the exhaust temperature sensor provided in the housing of the storage rack and detecting the temperature of the exhaust from the inside of the housing to the outside by the exhaust fan. The sensor output value of the refrigerant temperature sensor that detects the temperature of the refrigerant flowing into the portion where the exhaust and the refrigerant exchange heat in the circulation path where the refrigerant that cools the exhaust by the exhaust fan circulates provided in the housing. The control device according to claim 2, wherein one or both are included. When a plurality of the electronic devices are housed in the housing of the storage rack, the lower limit value setting unit uses information on the rotation speed of the air-cooling fan acquired from the electronic devices in the housing. Then, the total air volume of the air-cooled fan of the electronic device in the housing is calculated, and the lower limit of the rotation speed of the exhaust fan is set so that the air volume of the exhaust exhausted by the exhaust fan does not fall below the total air volume. The control device according to item 2 or claim 3. A housing for storing electronic devices equipped with an air-cooled fan,
An exhaust fan provided in the housing that exhausts air from inside the housing to the outside,
A storage rack including the control device according to any one of claims 1 to 4. Information on the rotation speed of the air-cooled fan of the electronic device arranged in the housing of the storage rack for storing the electronic device provided with the air-cooled fan, or the temperature of the exhaust discharged from the inside of the electronic device to the outside. A monitoring device equipped with an acquisition unit that acquires information,
Using the information acquired by the acquisition unit, the air volume of the exhaust from the exhaust fan that exhausts air from the inside of the housing of the storage rack to the outside is less than the air volume of the exhaust exhausted from the inside of the electronic device to the outside. A fan control system including a fan control device that drives and controls the exhaust fan so as not to be present. The fan control system according to claim 6, wherein the monitoring device is arranged outside the housing of the storage rack. Information on the rotation speed of the air-cooled fan of the electronic device arranged in the housing of the storage rack for storing the electronic device provided with the air-cooled fan, or the temperature of the exhaust discharged from the inside of the electronic device to the outside. Get information,
Using the information acquired by the acquisition unit, the air volume of the exhaust from the exhaust fan that exhausts air from the inside of the housing of the storage rack to the outside is less than the air volume of the exhaust exhausted from the inside of the electronic device to the outside. A fan control method for driving and controlling the exhaust fan so as not to be present. Information on the rotation speed of the air-cooled fan of the electronic device arranged in the housing of the storage rack for storing the electronic device equipped with the air-cooled fan, or the temperature of the exhaust gas discharged from the inside of the electronic device to the outside. The process of getting information and
Using the information acquired by the acquisition unit, the air volume of the exhaust gas exhausted from the inside of the housing of the storage rack to the outside is lower than the air volume of the exhaust gas discharged from the inside of the electronic device to the outside. A computer program that causes a computer to execute a process of driving and controlling the exhaust fan so as not to be present.

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