JP6536303B2 - Electronic apparatus, rack apparatus, apparatus cooling method, and program therefor - Google Patents

Description

  The present invention relates to an electronic device that houses one or more information processing devices, a device cooling method, and a program for the same.

  Among electronic devices, a device is known which enhances the cooling efficiency of an information processing device stored therein. The electronic device includes a cooling unit, and supplies the air cooled by the cooling unit to the information processing apparatus.

  Patent Document 1 describes an example of such an electronic device. The electronic device described in Patent Document 1 includes a storage rack that stores a plurality of electronic devices. The storage rack individually connects the electronic devices to each other and sets supply paths for supplying the temperature-controlled air from the corresponding electronic devices to the respective electronic devices. The air supplied to each electronic device through each supply path is configured to circulate in the horizontal direction.

JP, 2011-059948, A

  However, with the technology described in Patent Document 1 described above, there is no method for dynamically controlling individually the temperature-controlled air supplied to each electronic device. Since the temperature-controlled air supplied to each electronic device can not be controlled dynamically and individually, when the number of information processing devices to be operated is dynamically reduced due to a power supply stop etc., it is described in the above-mentioned Patent Document 1 The technology can not ignore the air that slips out of the stopped equipment. In addition, when the device is temporarily removed for maintenance, the technology described in Patent Document 1 described above can not control the air volume of the entire rack device by ignoring the air which slips off the vacant portion from which the device is removed. Therefore, the technology described in Patent Document 1 has a problem that the cooling capacity (for example, the air volume of the cooling air) required for operation can not be reduced in proportion to the power during operation.

  An example of the object of the present invention is to provide an electronic device or the like that accommodates one or more information processing devices that can solve the problems described above. Specifically, an example of the object of the present invention is to provide an electronic device or the like capable of reducing the cooling capacity necessary for operation in proportion to the power in operation.

  A first electronic device according to one aspect of the present invention includes a cooling unit that cools air, a rack unit that houses one or more information processing apparatuses, and a control unit, and the rack unit includes a cooling unit and an information processing unit. Mounted between the air intake duct of the air conditioner and the air intake duct which supplies the air flow from the cooling unit to the information processing apparatus, and installed between the cooling unit and the exhaust port of the information processing apparatus; The cooling duct is provided at the opening of the mounting portion between the intake duct and the exhaust duct, and the opening control comprises the state of opening the opening and the state of closing the opening, The control unit controls only the opening control unit corresponding to the information processing apparatus to which the power is turned on so as to open the opening, and calculates the power consumption of all the active information processing apparatuses housed in the rack apparatus Control the cooling unit based on the result That.

  The first rack device according to one aspect of the present invention is a rack device on which the information processing apparatus is mounted, and is mounted between the cooling unit and the air inlet of the information processing apparatus, and the air flow from the cooling unit is transmitted to the information processing apparatus. Cooling corresponding to an intake duct unit for supplying, an exhaust duct unit for supplying exhaust air from the information processing apparatus to the cooling unit, installed between the cooling unit and the exhaust port of the information processing apparatus, and information processing apparatus for turning on power The control unit controls the cooling unit to open the opening with the unit, calculate the power consumption of all the stored information processing apparatuses in operation, and control the cooling unit based on the calculation result.

  In the first apparatus cooling method according to one aspect of the present invention, only the opening of the cooling unit corresponding to the information processing apparatus to which power is supplied is controlled to be open, and all the information processing in operation stored in the rack apparatus The power consumption of the device is calculated, and the cooling unit is controlled based on the calculation result.

  A first program according to an aspect of the present invention controls the computer to open only the opening of the cooling unit corresponding to the information processing apparatus to which power is supplied, and the above-mentioned all in-operation stored in the rack apparatus The power consumption of the information processing apparatus is calculated, and a process of controlling the cooling unit is executed based on the calculation result.

  According to the present invention, it is possible to reduce the amount of air required for operation in proportion to the power during operation.

FIG. 1 is a perspective view showing an example of the outer shape of an electronic device 100 according to a first embodiment of the present invention. FIG. 2 is a block diagram showing an example of the configuration of the electric circuit system of the electronic device 100 according to the first embodiment of the present invention. FIG. 3 is a perspective view showing an example of the structure of the housing of the information processing apparatus 200 housed in the rack device 190 in the first embodiment. FIG. 4 is a perspective view showing an example of the structure of the intake duct portion 120 corresponding to the information processing apparatus 200 of height 2U of the present invention. FIG. 5 is a diagram showing an example of a hardware configuration when the control unit 150 in the first embodiment is realized by a computer device. FIG. 6 is a flowchart showing an outline of operation of control of the movable guard unit 140 of the control unit 150 when the information processing apparatus 200 is housed in the rack device 190 and the power is turned on in the first embodiment. FIG. 7 is a perspective view showing an example of the outer shape of the electronic device 101 according to the second embodiment of the present invention. FIG. 8 is a block diagram showing an example of the configuration of the electric circuit system of the electronic device 101 according to the second embodiment of the present invention. FIG. 9 is a perspective view showing an example of the structure of the duct lock portion 160 of the present invention. FIG. 10 is a flowchart showing an outline of an operation of control of the duct lock unit 160 of the control unit 151 when the information processing apparatus 200 is stored in the rack apparatus 191 and the power is turned on in the second embodiment. FIG. 11 is a flowchart showing an outline of an operation for controlling the duct lock unit 160 of the control unit 151 at the time of maintenance replacement of the failed information processing apparatus 200 in the electronic device 101 according to the second embodiment.

  Next, embodiments of the present invention will be described in detail with reference to the drawings.

First Embodiment
FIG. 1 is a perspective view showing an example of the outer shape of an electronic device 100 according to a first embodiment of the present invention. FIG. 2 is a block diagram showing an example of the configuration of the electric circuit system of the electronic device 100 according to the first embodiment of the present invention.

  Referring to FIGS. 1 and 2, the electronic device 100 includes a cooling unit 110, a rack device 190, and a control unit 150 which is not illustrated in FIG. Further, in FIG. 1, the x-axis direction is a direction in which the cooling unit 110 and the rack device 190 are arranged. The y-axis direction is orthogonal to the x-axis direction, and is the depth direction in FIG. The z-axis direction is orthogonal to the x-axis direction and the y-axis direction, and is the vertical (height) direction in FIG.

  Although the cooling unit 110 and the rack device 190 are separately described in FIG. 1 for the purpose of explanation, the cooling unit 110 and the rack device 190 are in close contact with each other as long as there is no problem in opening and closing the opening / closing member 142 of the movable guard 140 described later. doing. The cooling unit 110 includes a movable guard unit 140.

  The rack device 190 includes an intake duct portion 120 and an exhaust duct portion 130. Further, the rack device 190 accommodates one or more information processing apparatuses 200 in the z-axis direction.

  An example of the method of storing the information processing apparatus 200, the intake duct portion 120, and the exhaust duct portion 130 by the worker is as follows. First, the operator removes two of the four sides of the rack device 190 that are opposite in the y-axis direction. Next, the worker attaches the exhaust duct portion 130 to the inside from which the side surface in the positive y-axis direction of the rack device 190 (that is, the side surface on the back side in FIG. 1) is removed. Next, the information processing apparatus 200 is attached to the inside of the rack apparatus 190 from which the side in the negative y direction of the y-axis direction (i.e., the side on the front side of FIG. 1) is removed. Attach to Finally, both sides of the removed rack device 190 facing in the y-axis direction are attached and completed.

  The above is an example of the storage method of the information processing apparatus 200, and the intake duct portion 120 is attached to the inside from which the side surface in the negative direction of the y-axis direction of the rack device 190 (that is, the side surface on the front side of FIG. Then, the information processing apparatus 200 and the exhaust duct portion 130 may be attached to the inside from which the side surface in the positive direction of the y-axis direction of the information processing apparatus 200 and the rack device 190 (that is, the side surface on the back side in FIG. . Alternatively, only one side of the rack device 190 opposite to the y-axis direction may be removed, and the intake duct portion 120, the information processing device 200, and the exhaust duct portion 130 may be attached. A storage method other than the above may be used.

  FIG. 3 is a perspective view showing an example of the structure of the housing of the information processing apparatus 200 housed in the rack device 190. As shown in FIG. The information processing apparatus 200 is provided with an air inlet 210 and an air outlet 220 at positions opposed to two surfaces facing each other in the y-axis direction. Therefore, the information processing apparatus 200 takes in the air (for example, cooling air) from the cooling unit 110 through the air inlet 210. The introduced cooling air (hereinafter, also simply referred to as air) cools the information processing circuit (not shown) and devices in the information processing apparatus 200 and then becomes heated exhaust and is discharged from the exhaust port 220 to the cooling unit 110. Ru. Therefore, in the information processing device 200, air flows in the positive direction of the y-axis direction from the air inlet 210 toward the air outlet 220.

  Next, the configuration of the electronic device 100 and the details of the information processing device 200 in the first embodiment will be described. In the following description, the information processing apparatus 200 is simply referred to as the information processing apparatus 200 or one information processing apparatus 200 in the case of one (or not specified), and in the case of two, two information processing apparatuses, When the whole is shown, it is called the whole information processing apparatus 200.

  The cooling unit 110 includes two rows of openings in the vertical direction to which the movable guard unit 140 is attached. The air (exhaust from the information processing apparatus 200) flowing in from the opening of one of the rows is cooled. The air cooled by the cooling unit 110 is discharged from the opening of the other row and supplied to the information processing apparatus 200. The cooling unit (cooling device) for cooling the exhaust gas from the information processing device 200 may be provided in the cooling unit 110. The cooling device may employ any type of cooling method such as a water cooling method. In the example of FIG. 1, the exhaust of the information processing apparatus 200 flows in from the opening in the positive direction of the y-axis direction of the cooling unit 110, that is, the opening on the back side in contact with the exhaust duct 130. Then, the cooled air is discharged from the opening in the negative direction of the y-axis direction of the cooling unit 110, that is, the opening on the near side in contact with the intake duct unit 120.

  The intake duct unit 120 is mounted between the cooling unit 110 and the air intake port 210 (FIG. 3) of the information processing apparatus 200, and the air flow from the cooling unit 110 can be individual information processing apparatus (the information processing apparatus 200 in FIG. 1). Supply). The height of the intake duct portion 120 in the z-axis direction corresponds to the height of the information processing apparatus 200 to be mounted.

  If one information processing apparatus 200 is an apparatus with a height of 1 U (Unit), intake duct part 120 corresponding to the height of 1 U, and one information processing apparatus 200 with a height of 4 U (Units) In the case of the device, the intake duct portion 120 corresponding to the height of 4 U is prepared in advance. Here, the height of 1 U is equivalent to 1 U, which is the unit of height in a 19-inch rack, and is a unit standardized by EIA (Electronic Industries Alliance) (TIA / EIA-310-D Cabinets, Racks , Panels, and Associated Equipment). That is, the rack device 190 of the electronic device 100 according to the embodiment of the present invention can accommodate the information processing device 200 having a height that is an integral multiple of 1U, like the 19-inch rack.

  The exhaust duct unit 130 is mounted between the cooling unit 110 and the exhaust port 220 (FIG. 3) of the information processing apparatus 200, and cools the exhaust from the individual information processing apparatus (the information processing apparatus 200 in FIG. 1). Supply to 110. The height of the exhaust duct portion 130 in the z-axis direction corresponds to the height of the information processing apparatus 200 to be mounted, as with the intake duct portion 120. That is, the height of the exhaust duct portion 130 in the z-axis direction matches the height of the intake duct portion 120 in the z-axis direction.

  FIG. 4 is a perspective view showing an example of the structure of the intake duct portion 120 corresponding to the information processing apparatus 200 with a height 2U. The structure of the exhaust duct portion 130 is also similar to the structure of the intake duct portion 120. Referring to FIG. 4, the intake duct portion 120 includes a duct top surface 121, two duct side surface members 122 (in FIG. 4, duct side surface members 122a and duct side surface members 122b), a duct side surface joint portion 123 and a duct bottom surface 124. Become. The duct side surface members 122a and 122b are side surface members having a height in the z-axis direction corresponding to the information processing apparatus 200 having a height of 1U. The duct side surface joint portion 123 is a member that joins two duct side surface members, that is, the duct side surface member 122a and the duct side surface member 122b in FIG. 4 in the z-axis direction. The bonding method may be any method. For example, the vicinity of the surface where the duct side surface member 122a and the duct side surface member 122b are in contact may be bonded by an adhesive applied to the sheet-like duct side surface joint portion 123, or the z-axis direction upper surface of the duct side surface joint portion 123 And the lower surface thereof may be provided with receiving portions for fitting and fixing the duct side member 122a and the duct side member 122b, respectively. By sandwiching the joined duct side surface members 122a and 122b between the duct top surface 121 and the duct bottom surface 124 in the z-axis direction, the intake duct portion 120 corresponding to the information processing apparatus 200 with a height 2U is completed. That is, by joining the duct side surface members 122 of the number corresponding to the height of the information processing apparatus 200 to be mounted in the z-axis direction, the intake duct portion 120 of the optimum height can be obtained. The structure of the intake duct portion 120 and the exhaust duct portion 130 is not limited to the structure shown in FIG. 4, and the intake duct portion 120 corresponding to all the heights of the information processing apparatus 200 mounted in advance may be prepared.

  Referring again to FIG. 1, the movable guard portion 140 is provided at an opening of the cooling portion 110, which is opposed to the mounting portion with the intake duct portion 120 and the exhaust duct portion 130. The movable guard portion 140 takes a state in which the opening is opened and a state in which the opening is blocked, and blocks (guards) the air flow between the cooling unit 110 and the rack device 190. The movable guard portion 140 includes one or more opening / closing members 142, and a driving portion 141 (not shown in FIG. 1) for individually driving the opening / closing members 142. The opening and closing of the opening and closing member 142 is controlled by the drive unit 141. The movable guard portion 140 in FIG. 1 is a range of a broken line portion corresponding to the height of one information processing device 200 among the opening and closing members 142 disposed continuously in the z-axis direction at the position of the opening of the cooling portion 110. . When the height of the information processing device 200 in the z-axis direction changes, the range in the z-axis direction of the movable guard portion 140 (the range indicated by the dashed frame in FIG. 1) also changes.

  The control unit 150 (FIG. 2) controls power on of all the information processing apparatuses 200 housed in the rack device 190 including the plurality of information processing apparatuses 200. Further, the control unit 150 detects the installation state of the intake ducts and the exhaust ducts of all the information processing apparatuses 200. The means by which the control unit 150 detects the installation state of the information processing apparatus 200 is, for example, a sensor or a switch. Further, the control unit 150 detects the power-on state of all the information processing apparatuses 200, and recognizes the height of each information processing apparatus 200 which is powered on based on the detected result. The control unit 150 determines the range of each movable guard unit 140 corresponding to each information processing apparatus 200 based on the height of each recognized information processing apparatus 200, and one or more corresponding to the movable guard unit 140. Control the drive unit 141 of

  Further, the control unit 150 calculates the power consumption of all the information processing apparatuses in operation stored in the rack device 190, and controls the cooling capacity of the cooling unit 110 based on the calculation result. For example, the wind speed or the cooling temperature of the cooling air from the cooling device (not shown) of the cooling unit 110 is increased or decreased according to the increase or decrease of the power consumption.

  The control unit 150 may be mounted on any part in the electronic device 100, such as the inside of the cooling unit 110 or the rack device 190. For example, the control unit 150 may be mounted inside the rack device 190 and control the cooling device and the drive unit 141 of the cooling unit 110 through an internal connection line. Alternatively, the rack apparatus 190 is provided with a part of the functions of the control unit 150, for example, a function of collecting signals from sensors or switches that detect the installation state of the information processing apparatus 200, and controls other functions, that is, the drive unit 141. The cooling unit 110 may be provided with regard to the function to perform and the function to control the cooling capacity. In addition, the control unit 150 may be provided as a device connected to the outside of the electronic device 100 via a connection cable.

  The information processing device 200 is housed in the rack device 190, and receives power supply from a power supply circuit (not shown) of the electronic device 100 to perform processing. The main object of the present embodiment is to improve the cooling method when the information processing apparatus 200 is operated by the electronic device 100. Therefore, the information processing circuit inside the information processing apparatus 200, the device, and the information processing method , I omit about the power supply circuit.

  FIG. 5 is a diagram showing an example of a hardware configuration when the control unit 150 in the first embodiment of the present invention is realized by a computer device. As shown in FIG. 5, the control unit 150 includes a communication interface 10, a CPU (Central Processing Unit) 11, and a main storage device 14, respectively.

  The communication interface 10 constitutes an input / output interface for communication with the processing device and the peripheral terminal. The communication interface 10 also includes an interface for connection control with a network (not shown) connected to the control unit 150.

  The CPU 11 operates an operating system to control the entire control unit 150 according to the first embodiment of the present invention. Moreover, CPU11 of the control part 150 may be equipped with two or more not only one.

  The main storage device 14 is a working memory based on the control of the CPU 11.

  In addition, the implementation | achievement means of each part with which the control part 150 is provided is not specifically limited. That is, the control unit 150 may be realized by one physically connected device, or may be realized by a plurality of physically separated devices by wired or wirelessly connecting two or more physically separated devices. Good.

  The operation of the electronic device 100 configured as described above will be described with reference to the flowchart of FIG.

  FIG. 6 is a flowchart showing an outline of an operation of control of the movable guard unit 140 of the control unit 150 when the information processing apparatus 200 is housed in the rack device 190 and the power is turned on in the first embodiment. The processing according to this flowchart may be executed based on the program control by the CPU described above.

  As shown in FIG. 6, first, when a power-on instruction to the information processing apparatus 200 is received, the control unit 150 controls the air intake duct 120 and the exhaust that are attached to the information processing apparatus (here, the information processing apparatus 200). It is confirmed whether the duct part 130 has been mounted (step S101). For confirmation, after receiving a power-on instruction, information for confirmation (for example, information of the above-mentioned sensor or information of a switch) may be acquired, or information may always be acquired. Further, the control unit 150 recognizes the height of the information processing apparatus 200 in the z-axis direction by acquiring the information as to whether or not it has been attached, and determines the range of the movable guard unit 140 which operates in conjunction with it.

  If the intake duct unit 120 and the exhaust duct unit 130 have not been mounted (NO in step S101), the control unit 150 does not turn on the information processing apparatus 200, and ends the processing. At this time, the control unit 150 may cause the display unit (not shown) to display that the power is not turned on in the information processing apparatus 200 because the control unit 150 has not been mounted.

  If the intake duct unit 120 and the exhaust duct unit 130 have been mounted (YES in step S101), the control unit 150 turns on the information processing apparatus 200 (step S102). The means for turning on the power may be any method such as a remote power on instruction of WOL (Wake On LAN) via a network or a power on instruction of IPMI (Intelligent Platform Management Interface).

  Next, the control unit 150 controls the drive unit 141 based on the information in step S101 to control one or more opening and closing members 142 of the movable guard unit 140 to open the opening of the cooling unit 110 (see FIG. The setting is performed (step S103). As a result, the air intake duct portion 120 and the air exhaust duct portion 130 of the information processing device 200 can transfer air with the cooling portion 110. Accordingly, the air cooled by the cooling unit 110 is supplied to the information processing apparatus 200, and the exhaust of the information processing apparatus 200 is sent to the cooling unit 110. When the power of the information processing apparatus 200 is not turned on, the corresponding opening / closing member 142 of the movable guard unit 140 is assumed to close the opening of the cooling unit 110.

  Further, the control unit 150 calculates the power consumption of all the information processing apparatuses in operation stored in the rack device 190 including the information processing apparatus 200, and controls the cooling unit 110 based on the calculation result (step S104). ). Specifically, the control unit 150 controls the cooling unit 110 by setting the number of operating fans and the operation level among the fans of the cooling device (not shown) of the cooling unit 110 to an optimal value based on the calculation result. Control of the cooling capacity of the cooling unit 110 is not limited to control of the fan.

  After the storage of the information processing apparatus 200 in the rack device 190, the control unit 150 ends the control operation when the power is turned on.

  As described above, the electronic device 100 according to the first embodiment of the present invention includes the cooling unit 110 for cooling air, the rack device 190 for storing one or more information processing apparatuses 200, and the control unit 150. Including. The rack device 190 is mounted between the cooling unit 110 and the air intake port of the information processing apparatus 200, and supplies the air flow from the cooling unit 110 to the information processing apparatus 200, the cooling unit 110, and the information processing apparatus. An exhaust duct portion 130 mounted between the exhaust ports 200 and supplying the exhaust air from the information processing device 200 to the cooling portion 110 is included. Further, the rack device 190 is provided at the opening of the mounting portion of the cooling unit 110 at the intake duct portion 120 and the exhaust duct portion 130, and the opening control portion (movable guard (a movable guard) takes a state of opening the opening and a state of closing the opening. Part 140) is also provided. The control unit 150 controls only the opening control unit corresponding to the information processing apparatus to which the power is turned on so as to open the opening, and calculates the power consumption of all the information processing apparatuses 200 in operation stored in the rack device 190 , And control the cooling unit 110 based on the calculation result.

  Next, the effect of the first embodiment of the present invention will be described.

  The electronic device 100 according to the embodiment described above proportions the cooling capacity (for example, the amount of air) of the cooling air necessary for the operation of the information processing device 200 housed in the rack device 190 to the power of the information processing device 200 in operation. Can be reduced.

  The reason is that the following configuration is included. That is, first, the control unit 150 controls the opening of the movable guard unit 140 corresponding to the information processing apparatus 200 to which the power is turned on to be opened. As a result, it is possible to prevent the cooling air from being blown to the information processing apparatus 200 which is not powered on, and it is possible to reduce the useless air volume. Second, the control unit 150 calculates the power consumption of all the information processing apparatuses accommodated in the rack device 190 in operation, and controls the cooling unit 110 based on the calculation result. As a result, the electronic device 100 supplies the air cooled by the cooling unit 110 to the information processing apparatus in operation, and the cooling unit 110 is also optimum for the power consumption of all the information processing apparatuses in operation. Are set to perform various control. For this reason, the electronic device 100 has the effect of being able to reduce the amount of air required for operation in proportion to the power in operation.

  The rack device 190 according to the first embodiment of this invention may have the following configuration. The rack apparatus is a rack apparatus on which the information processing apparatus is mounted, and includes an intake duct unit 120, an exhaust duct unit 130, and a control unit 150. The intake duct unit 120 is mounted between the cooling unit and the intake port of the information processing apparatus, and supplies the air from the cooling unit to the information processing apparatus. The exhaust duct unit 130 is mounted between the cooling unit and the exhaust port of the information processing apparatus, and supplies the exhaust from the information processing apparatus to the cooling unit. Further, the control unit 150 controls to open the opening with the cooling unit corresponding to the information processing apparatus to which the power is turned on, calculates the power consumption of all the information processing apparatuses in operation stored, and calculates the power consumption Control the cooling unit based on the result. Even with such a rack device, the same effects as described above can be obtained.

Second Embodiment
Next, a second embodiment of the present invention will be described in detail with reference to the drawings. Hereinafter, in the range in which the description of the present embodiment is not unclear, the description overlapping with the above description will be omitted.

  FIG. 7 is a perspective view showing an example of the outer shape of the electronic device 101 according to the second embodiment of the present invention. FIG. 8 is a block diagram showing an example of the configuration of the electric circuit system of the electronic device 101 according to the second embodiment of the present invention.

  Referring to FIGS. 7 and 8, the electronic device 101 according to the present embodiment includes a cooling unit 111 and a rack device 191 instead of the cooling unit 110 and the rack device 190 in comparison with that of the first embodiment. The rack device 191 additionally includes a duct lock portion 160, an intake air temperature sensor portion 170, and an external device temperature sensor portion 180 in addition to the configuration of the rack device 190 of the first embodiment (the external device temperature sensor portion 180 is shown in FIG. Not shown in 6). The rack device 191 further includes a control unit 151 in place of the control unit 150. The cooling unit 111 is provided with a restraining piece 112 and a gap 113 which are newly shown in FIG.

  The duct lock portion 160 takes two states, a state in which the intake duct portion 120 and the exhaust duct portion 130 and the cooling portion 111 are fixed, and a state in which the fixing is released.

  FIGS. 9A, 9B, and 9C are perspective views showing an example of the structure of the duct lock portion 160 according to the present invention. The duct lock portion 160 shown in FIG. 9 is provided in the intake duct portion 120. Referring to FIG. 9A, the duct lock portion 160 has a notch 161. Further, the cooling unit 111 is provided with a gap 113 in which the duct lock portion 160 can be inserted at a position corresponding to the duct lock portion 160 of the intake duct portion 120 when the intake duct portion 120 and the cooling portion 111 are fixed. Furthermore, the cooling unit 111 has, within the gap, the restraining piece 112 which takes two states, a state of fitting with the notch portion 161 of the duct lock portion 160 and a state of not fitting.

  An example of a method in which the intake duct portion 120 is fixed to the cooling portion 111 by the duct lock portion 160 will be described. Referring to FIG. 9 (b), the intake duct portion 120 is mounted to the cooling portion 111. At this time, the duct lock portion 160 is inserted into the gap 113. Referring to FIG. 9C, the restraining piece 112 transitions to a state in which it engages with the notch portion 161 of the duct lock portion 160 inserted into the gap 113. In this state, the intake duct portion 120 can not be removed from the cooling portion 111 due to the fixation of the duct lock portion 160. Thus, the intake duct portion 120 is fixed to the cooling portion 111 by the duct lock portion 160. The fixing method is not limited to this. The duct lock portion 160 instead of the cooling portion 111 may be provided with the restraining piece 112. The fixing method may be an electromagnetic lock.

  The intake air temperature sensor unit 170 detects the temperature in the intake duct unit 120. The intake air temperature sensor unit 170 may be installed in any place as long as the temperature in the intake air duct unit 120 can be detected.

  The external device temperature sensor unit 180 detects the temperature outside the electronic device 101. The external device temperature sensor unit 180 may be installed in any place as long as the temperature outside the electronic device 101 can be detected.

  The control unit 151 has the temperature in the intake duct 120 detected by the intake temperature sensor unit 170 and the temperature outside the electronic device 101 detected by the external temperature sensor unit 180 in addition to the function of the control unit 150 in the first embodiment. And the duct lock unit 160 based on the difference between

  Next, the operation of the electronic device 101 will be described with reference to the flowcharts shown in FIGS.

  FIG. 10 is a flowchart showing an outline of an operation of control of the duct lock unit 160 of the control unit 151 when the information processing apparatus 200 is stored in the rack apparatus 191 and the power is turned on in the second embodiment. The processing according to this flowchart may also be performed based on the program control by the CPU described above. When the information processing apparatus 200 is housed in the rack apparatus 190 and the power is turned on in the first embodiment, the parts overlapping the flowcharts showing the outline of the operation of the movable guard part 140 control of the control part 150 will be omitted. Do.

  First, it is confirmed whether or not the intake duct portion 120 and the exhaust duct portion 130 have been attached. If the intake duct portion 120 and the exhaust duct portion 130 have been attached, the control unit 151 controls the movable guard 140 to open the opening, and controls the cooling unit 111. Correct the as appropriate. Processing in a state in which the movable guard portion 140 is opened is the same as steps S101 to S104 of the flowchart in the first embodiment.

  Furthermore, the control unit 151 controls the duct lock unit 160 to fix the intake duct unit 120 and the exhaust duct unit 130 and the cooling unit 111 (step S201). At this time, even if the duct lock portion 160 indicates that the intake duct portion 120 and the exhaust duct portion 130 and the cooling portion 111 are fixed, that is, the fact that the information processing apparatus 200 is in operation is displayed on a display portion not shown. Good.

  Above, control part 151 ends operation of duct lock part 160 control at the time of storing information processor 200 in rack device 191, and turning on power.

  FIG. 11 is a flowchart showing an outline of an operation for controlling the duct lock unit 160 of the control unit 151 at the time of maintenance replacement of the failed information processing apparatus 200 in the electronic device 101 according to the second embodiment. The processing according to this flowchart may also be performed based on the program control by the CPU described above.

  As shown in FIG. 11, first, when detecting an information processing apparatus (in this case, the information processing apparatus 200) to be subjected to maintenance replacement, the control unit 151 controls the movable guard unit 140 through which the air supplied to the information processing apparatus 200 passes. The opening is controlled to be closed (step S301). The case where an information processing apparatus to be subjected to maintenance replacement is detected is, for example, shutdown due to shutdown or failure of the information processing apparatus. The detection means may be any method.

  Next, the control unit 151 obtains the temperature inside the intake duct unit 120 and the temperature outside the electronic device 101 from the intake temperature sensor unit 170 and the device outside temperature sensor unit 180, respectively (step S302).

  If the difference between the acquired temperature in the intake duct unit 120 and the temperature outside the electronic device 101 exceeds the predetermined temperature (YES in step S303), the control unit 151 waits until the predetermined temperature is not exceeded. (Return to step S302). If the temperature difference does not exceed the predetermined temperature (NO in step S303), control unit 151 controls duct lock portion 160 to take a state in which fixing of intake duct portion 120 and exhaust duct portion 130 is released ( Step S304). Since the fixation of the intake duct portion 120 and the exhaust duct portion 130 is released, the intake duct portion 120 and the exhaust duct portion 130 are removed by the operator. As a result, the information processing apparatus 200 can be extracted by the worker.

  Above, control part 151 ends operation of control of duct lock part 160 at the time of maintenance exchange of failed information processor 200.

  Next, the effects of the second embodiment of the present invention will be described.

  The electronic device 101 in the above-described embodiment can improve maintainability.

  The reason is that the following configuration is included. That is, first, the control unit 151 controls the movable guard unit 140, through which the air supplied to the information processing apparatus 200 passes, to close the opening. Secondly, the control unit 151 is configured such that the information processing apparatus 200 can be removed when the difference between the acquired temperature in the intake duct unit 120 and the temperature outside the electronic device 101 does not exceed a predetermined temperature. Control is performed to release the fixation of the exhaust duct portion 130 and the exhaust duct portion 130. When the difference between the temperature of the information processing apparatus 200 to be removed and the outside air temperature is large, condensation may occur in the information processing apparatus 200 when the information processing apparatus 200 is removed. Therefore, condensation does not occur in the information processing apparatus 200 to be removed. Further, since the supply of air is divided for each information processing apparatus by the intake duct unit 120 and the exhaust duct unit 130, the temperature of the other information processing apparatuses in operation in the rack apparatus 191 at the time of insertion and removal of the information processing apparatus 200. And prevent the rise of humidity. Therefore, the electronic device 101 has an effect of being able to improve the maintainability.

  As a modification, the electronic device 101 may be provided with a lock release unit for manually releasing the fixing of the intake duct unit 120 and the exhaust duct unit 130 by the duct lock unit 160. The shape of the unlocking portion may be any shape such as a button or a touch panel. In this case, in addition to the condition in step S303, when the unlocking unit is activated by the operation of the operator, the control unit 151 determines that the duct locking unit 160 releases the fixing of the intake duct unit 120 and the exhaust duct unit 130. Control to take.

  With this configuration, even if the difference between the temperature in air intake duct 120 and the temperature outside electronic apparatus 101 does not fall below a predetermined temperature for some reason, and, for example, even if any abnormality is detected by visual inspection of a worker, Thus, the information processing apparatus 200 can be removed. Thereby, the electronic device 101 can further improve the maintainability.

  As mentioned above, although this invention was demonstrated with reference to each embodiment, this invention is not limited to the said embodiment. The configurations and details of the present invention can be modified in various ways that can be understood by those skilled in the art within the scope of the present invention.

  For example, each component described in each of the above embodiments does not have to be an independent entity. For example, each component may be realized by a plurality of components as one module, or one component may be realized by a plurality of modules. In addition, each component is configured such that a component is a part of another component, a part of a component and a part of another component overlap, etc. It is also good.

  Moreover, in each embodiment described above, although a plurality of operations are described in the form of a flowchart in order, the order of the description does not limit the order of executing the plurality of operations. For this reason, when implementing each embodiment, the order of the plurality of operations can be changed within a range that does not affect the content.

  Furthermore, in each of the embodiments described above, a certain operation is described as a trigger for another operation, but the description does not limit the entire relationship between a certain operation and another operation. For this reason, when implementing each embodiment, the relationship of the some operation | movement can be changed in the range which does not have a trouble in content. Further, the specific description of each operation of each component does not limit each operation of each component. For this reason, the specific operations of the components may be changed within the range that does not affect the functional, performance, and other characteristics in implementing the embodiments.

10 Communication interface 11 CPU
14 main storage unit 100, 101 electronic unit 110, 111 cooling unit 112 restraint piece 113 gap 120 intake duct unit 121 duct top surface 122, 122a, 122b duct side surface member 123 duct side surface joint portion 124 duct bottom surface 130 exhaust duct portion 140 movable guard Part 150, 151 Control part 160 Duct lock part 161 Notch part 170 Intake air temperature sensor part 180 Device outside temperature sensor part 190, 191 Rack device 200 Information processing device 210 Intake port 220 Exhaust port

Claims (7)

A cooling unit that cools air, a rack unit that houses one or more information processing devices, and a control unit;
The rack device is
An air intake duct unit mounted between the cooling unit and an air intake port of the information processing apparatus for supplying air flow from the cooling unit to the information processing apparatus;
An exhaust duct unit mounted between the cooling unit and an exhaust port of the information processing apparatus and supplying exhaust air from the information processing apparatus to the cooling unit ;
A duct lock portion which takes a state of fixing the air intake duct portion and the exhaust duct portion and the cooling portion and a state of releasing the fixation;
An intake temperature sensor unit for detecting a temperature in the intake duct unit;
An external device temperature sensor unit that detects the temperature outside the rack device;
Equipped with
The cooling unit is
An opening control unit provided at an opening of a mounting portion of the intake duct unit and the exhaust duct unit, the opening control unit taking a state of opening the opening and a state of closing the opening;
The control unit controls only the opening control unit corresponding to the information processing apparatus to which power is supplied so as to open the opening, and calculates the power consumption of all the information processing apparatuses in operation stored in the rack apparatus Based on the calculation result, and based on the difference between the temperature in the intake duct portion detected by the intake temperature sensor portion and the temperature outside the rack device detected by the outside temperature sensor portion detected by the intake temperature sensor portion. Electronic device for controlling the duct lock portion . The rack device is
It further has a lock release unit for manually releasing fixation of the intake duct unit and the exhaust duct unit by the duct lock unit,
2. The electronic device according to claim 1 , wherein, when the lock release unit is activated, the control unit controls the duct lock unit to release the fixing of the intake duct unit and the exhaust duct unit. A rack device on which an information processing device is mounted,
An air intake duct unit mounted between a cooling unit and an air intake port of the information processing apparatus and supplying air from the cooling unit to the information processing apparatus;
An exhaust duct unit mounted between the cooling unit and an exhaust port of the information processing apparatus and supplying exhaust air from the information processing apparatus to the cooling unit;
A duct lock portion which takes a state of fixing the air intake duct portion and the exhaust duct portion and the cooling portion and a state of releasing the fixation;
An intake temperature sensor unit for detecting a temperature in the intake duct unit;
An external device temperature sensor unit that detects the temperature outside the rack device;
Control is performed to open the opening with the cooling unit corresponding to the information processing apparatus to which power is supplied, and the power consumption of all the stored information processing apparatuses in operation is calculated, and based on the calculation result, The cooling unit is controlled , and the duct lock unit is controlled based on the difference between the temperature in the intake duct detected by the intake temperature sensor and the temperature outside the rack detected by the external temperature sensor. A rack apparatus comprising a control unit. Control is performed to open only the opening of the cooling unit corresponding to the information processing apparatus to which power is supplied, and the power consumption of all the information processing apparatuses in operation stored in the rack apparatus is calculated, and based on the calculation result The control unit controls the cooling unit, and fixes and cancels the intake duct unit and the exhaust duct unit and the cooling unit based on the difference between the temperature in the intake duct unit and the temperature outside the rack device. Control the duct lock to take out the equipment cooling method. The duct lock is configured to release the fixing of the intake duct and the exhaust duct when an unlocking unit is operated to manually release the fixing of the intake duct and the exhaust duct by the duct lock. The device cooling method according to claim 4 , wherein the control unit controls the unit. Control is performed to open only the opening of the cooling unit corresponding to the information processing apparatus to which power is supplied, and the power consumption of all the information processing apparatuses in operation stored in the rack apparatus is calculated, and based on the calculation result The control unit controls the cooling unit, and fixes and cancels the intake duct unit and the exhaust duct unit and the cooling unit based on the difference between the temperature in the intake duct unit and the temperature outside the rack device. A program that causes a computer to execute a process to control a duct lock that takes The duct lock is configured to release the fixing of the intake duct and the exhaust duct when an unlocking unit is operated to manually release the fixing of the intake duct and the exhaust duct by the duct lock. The program according to claim 6 , making the computer execute a process of controlling the unit.

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