JP2011238765A - Cooling apparatus, system and method for electronic device housing rack group - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an apparatus and the like that effectively cool an electronic device housing rack group by locally cooling an electronic device housing rack generating a large amount of heat and also by responding to changes in the amount of heat generation.SOLUTION: A cooling apparatus of the present invention is arranged in places such as between electronic device housing racks and comprises: a fan 14 for generating an air flow from a warm-air passage 3 to a cool-air passage 2; a heat exchanger 15 for turning warm air in the warm-air passage into cool air; a first vane 16 for determining the direction of cool air to be discharged into the cool-air passage 2; an infrared sensor 19 for monitoring the temperature of at least one electronic device housing rack facing the sensor; and a discharge direction control unit for controlling the direction of the first vane 16 based on the temperature obtained by the infrared sensor 19. The discharge direction control unit controls the direction of the first vane 16 so that cool air is discharged toward a specific one of the electronic device housing racks monitored by the infrared sensor.

Description

  The present invention relates to a cooling device for an electronic equipment storage rack group that stores electronic equipment such as computers and network equipment, and in particular, a passage formed between rows of electronic equipment storage racks is alternately formed into a cool air passage and a warm air passage. The present invention relates to a cooling device for a group of electronic equipment storage racks arranged to form.

  Electronic devices such as computers or network devices housed in computer rooms such as data centers are being miniaturized by increasing their density and reducing installation space, and the temperature rise of electronic devices directly leads to system troubles. It is becoming increasingly important to address the heat generation problem of these electronic devices. Also, in the computer room, warm air and cold air may be biased depending on the position, strength, direction of the air conditioner outlet, the state of cable routing in the underfloor space, and the state of use of the computer, etc. Sometimes. If there is a temperature bias in such a computer room, the part with the warm air bias and the electronic equipment / rack (hot spot) with a large amount of heat generation are locally cooled rather than cooling the entire computer room. It is known that the cooling efficiency is better.

As a prior art in which such measures are taken, there is Patent Document 1.
Specifically, a local cooling device is installed above the passage space between the rack rows of the rack on which the communication equipment is mounted, the passage space between the rack rows, an opening is provided on the side of the rack, and the upper portion of the rack A configuration is disclosed in which a blower is provided, low-temperature conditioned air from a local cooling device is taken into the rack from the opening, and exhaust heat from the communication device is locally processed.

  Furthermore, the hot spot may change over time due to changes in the use state of the computer or the like. For example, banking systems are often used during the day and generate heat, while Internet online shop systems are often used and generate heat during the night.

There is Patent Document 2 as a prior art that takes measures against such a problem.
Specifically, a timer count is started with the start of control, and each wind direction pattern is sequentially operated for a fixed time at a predetermined interval. During this period, temperature measurement is performed by a temperature sensor, and temperature distribution is performed for each wind direction pattern. The value is calculated, and based on the calculation result, the wind direction pattern with the smallest variance value is selected and the operation is continued, and it is further determined whether or not the maximum temperature is within the set temperature for the selected wind direction pattern. A configuration is disclosed in which when the temperature is out of this range, the cooling capacity is increased or decreased to perform control close to the set temperature.

JP 2002-156136 A JP 2009-264598 A

  The prior art of Patent Document 1 is a cooling device for cooling in units of cold air passages formed between rows of racks that store electronic devices, not the entire computer room, and the cable in the underfloor space If a hot spot occurs in units of electronic equipment storage racks due to the routed state or the use state of a computer or the like, it cannot be handled.

  In addition, the prior art of Patent Document 2 discloses a cooling system in which a cooling device shares a specific area in a cold air passage, but there is no partition between the areas, and air is not contained in the cooling passage. When there is a flow, the assigned area becomes ambiguous.When the hot spot moves with time, even if the wind direction pattern is controlled based on the calculation result of the temperature dispersion value in the area, it changes rapidly. In particular, it is not effective and efficient to cool the electronic device storage racks in the rack row on the same side as the cooling device.

  However, in recent years, the amount of heat generation and changes during the use of these electronic devices have been increasing. Especially, due to the recent increase in environmental awareness, it is possible to cope with such changes in local hot spots. There is a need for efficient and efficient cooling methods for electronic devices.

  Accordingly, the present invention has been made in view of the above problems, and an object of the present invention is to locally cool an electronic equipment storage rack that generates a large amount of heat, and to cope with changes in the amount of heat generated. Accordingly, it is an object to provide an apparatus, a system, and a method for effectively and efficiently cooling an electronic device storage rack group.

In order to solve the above problems, according to an aspect of the present invention, a plurality of electronic device storage racks having electronic devices therein are installed in a plurality of rows, and the rows of the electronic device storage racks facing each other are arranged. A cooling device for cooling a group of electronic equipment storage racks arranged such that a passage formed between the cool air passage and the warm air passage is alternately formed, and the cooling device is provided between the electronic equipment storage racks. Or a fan that is arranged at the end of the row and that generates an air flow from the warm air passage to the cold air passage, a heat exchanger that cools the warm air in the warm air passage, and the cold air passage that faces the cold air passage. Obtained from the infrared sensor, the first slat that defines the discharge direction of the cold air to be discharged into the air, the infrared sensor that monitors the temperature of at least one of the electronic device storage racks that are opposed to each other across the cold air passage And a discharge direction control unit that controls the direction of the first slats based on the temperature, and the discharge direction control unit is configured to control specific electrons in the electronic device storage rack monitored by the infrared sensor. A cooling device is provided that controls the orientation of the first slats so as to release the cold air toward the equipment storage rack.
According to this configuration, the electronic device storage rack having a large amount of heat generation among the electronic device storage racks targeted by the cooling device is effectively cooled and effectively adapted to the change in the heat generation amount. In addition, the electronic device storage rack group can be cooled.

Further, the specific electronic device storage rack is an electronic device storage rack having the highest temperature among the monitored electronic device storage racks, and the discharge direction control unit is an electronic device having the highest temperature. The direction of the first slat may be controlled so as to release the cold air toward the equipment storage rack.
According to this configuration, the electronic device storage rack that generates the largest amount of heat among the electronic device storage racks targeted by the cooling device is intensively cooled, so that the influence on the surroundings is minimized and effective. It becomes possible to cool the electronic device storage rack group efficiently.

In addition, the specific electronic device storage rack is an electronic device storage rack having the highest temperature among the monitored electronic device storage racks and an electronic device storage rack having the second highest temperature. The discharge direction control unit has two systems, the first slat of one system is in the direction of the electronic equipment storage rack having the highest temperature, and the first slat of the other system is the second highest. The direction of the first slats is controlled so as to release the cold air toward the electronic device storage rack having the temperature, and the air flow from the fan is controlled by the first slats of the one system and the other. A partition plate having a flap that distributes to the first slats of the system, and a flap control unit that controls the direction of the flap of the partition plate, wherein the flap control unit is configured to control a majority of the air volume discharged from the fan. System of To the first wings plate, the rest to the first wings plate of the other strains may be characterized in that distributed.
According to this configuration, while supplying cool air to the electronic device storage rack having the second largest heat generation amount among the electronic device storage racks targeted by the cooling device, the electronic device storage rack having the largest heat generation amount has more By providing the air volume, the electronic device storage rack group can be cooled effectively and efficiently.

Furthermore, from the power sensor or current sensor for the electronic equipment storage rack next to the cooling device, the second slat that faces the warm air passage and defines the suction direction of the warm air, and the power sensor or current sensor A suction direction control unit that controls the direction of the second slats based on the obtained power value or current value, and the suction direction control unit includes an electronic device storage rack adjacent to the cooling device. The direction of the second slat may be controlled so as to suck the warm air from the electronic equipment storage rack having the higher power value or current value.
According to this configuration, by drawing more warm air from the electronic equipment storage rack side that uses more electric power or the like on the warm air passage side, it is possible to prevent the warm air from entering the cold air passage side, etc. Thus, it can contribute to the elimination of the hot spots.

Furthermore, it is good also as providing the air volume control part which controls the air volume of the said fan.
According to this configuration, more effective and efficient cooling is possible.

In order to solve the above-described problem, according to an aspect of the present invention, there is provided a system for cooling an electronic device storage rack group on both sides of a cold air passage using the above-described cooling device. Is the electronic equipment storage rack facing the cold air passage monitored by the one cooling device, and the cold air discharged by the cooling device reaches due to the change in the direction of the first slat of the cooling device The electronic equipment storage racks in the area are to be cooled, and the cooling device is arranged in the electronic equipment storage rack rows on both sides of the cold air passages so that the areas do not overlap and have no gaps in the cold air passages. A system for cooling the electronic equipment storage rack group is provided.
According to this configuration, the electronic device storage rack having a large amount of heat generation is locally cooled, and the change in the heat generation amount is also dealt with. It is possible to provide a cooling system.

In order to solve the above problems, according to an aspect of the present invention, there is provided a method for cooling an electronic device storage rack group on both sides of a cold air passage using the cooling device, wherein the one cooling device Is the electronic equipment storage rack facing the cold air passage monitored by the one cooling device, and the cold air discharged by the cooling device reaches due to the change in the direction of the first slat of the cooling device The electronic device storage racks in the region are to be cooled, and the cooling device includes the electronic device storage rack rows on both sides of the cold air passages so that the regions do not overlap and have no gaps in the cold air passages. The cooling device is disposed in the cooling device, and cools the electronic device storage rack to be monitored by releasing cool air toward a specific electronic device storage rack in the electronic device storage rack monitored by the cooling device. A method of cooling the electronic equipment mounting rack group characterized the door is provided.
According to this configuration, the electronic device storage rack having a large amount of heat generation is locally cooled, and the change in the heat generation amount is also dealt with. It is possible to provide a cooling method.

  As described above, according to the present invention, an electronic device storage rack group can be effectively and efficiently formed by locally cooling an electronic device storage rack that generates a large amount of heat and responding to changes in the heat generation amount. It becomes possible to cool.

BRIEF DESCRIPTION OF THE DRAWINGS (a) Top view explaining the flow of the air in a computer room to which 1st Embodiment based on the cooling device of this invention is applied, (b) Sectional drawing. The top view which shows the cooling system to which 1st Embodiment which concerns on the cooling device of this invention is applied. BRIEF DESCRIPTION OF THE DRAWINGS (a) Front view, (b) Rear view, (c) Side view, (d) Top view of 1st Embodiment which concerns on the cooling device of this invention. FIG. 3 is an elevational sectional view of the first embodiment according to the cooling device of the present invention. The perspective view of 1st Embodiment which concerns on the cooling device of this invention. The flowchart which shows control of the 1st slat in 1st Embodiment which concerns on the cooling device of this invention. The flowchart which shows control of the 2nd slat in 1st Embodiment which concerns on the cooling device of this invention. In the first embodiment according to the cooling device of the present invention, (a) a diagram showing where the first slats release cool air, (b) a diagram showing where the second slats sucks warm air, ( c) Plan sectional view. Detailed drawing of the heat exchanger in 1st Embodiment which concerns on the cooling device of this invention. Detailed drawing of the fan in 1st Embodiment which concerns on the cooling device of this invention. In 2nd Embodiment which concerns on the cooling device of this invention, (a) The figure which showed the place where a 1st slat discharge | releases cold air, (b) Plane sectional drawing. Explanatory drawing explaining the flow of the air in the computer room to which a prior art is applied.

Below, the apparatus etc. which concern on each embodiment of this invention are demonstrated, referring drawings.
First, based on FIG. 11, the flow of air in a computer room using a conventional technique will be described. FIG. 11A is a plan view of the computer room, and FIG. 11B is a cross-sectional view of the elevation of the computer room.
The computer room 30 is provided with an air conditioning system 34 to cool the entire computer room 30. In particular, the cold air cooled by the air conditioning system 34 is blown into the underfloor space 33 under the floor 31 where the electronic equipment and the electronic equipment storage rack are installed, and the underfloor space 33 is filled with the cold air with a positive pressure. Accordingly, the cold air is blown upward from the floor opening 32.

  Further, in the computer room 30, the electronic equipment storage racks 21 are arranged in a row in order to efficiently arrange the racks indoors. The electronic device storage rack 21 normally draws in cool air from the front surface and discharges warm air heated by the electronic device from the back surface. Therefore, when the electronic device storage rack group 20 including the electronic device storage racks 21 arranged in a row is arranged so as to be parallel to each other, in order to enhance the cooling effect of the electronic device storage racks 21, The floor opening 32 to be blown out is disposed on both sides with the front face facing the passage. Then, the back side of the electronic device storage rack 21 that discharges warm air is also arranged to face the back side of the electronic device storage rack 21 of the adjacent electronic device storage rack group 20. As a result, in the computer room 30, a passage having a floor opening 32 through which cool air blows out, that is, the cool air passage 2 and the warm air passage 3 through which the electronic device storage rack groups 20 on both sides discharge warm air alternately appear. Become.

The warm air discharged to the warm air passage 3 rises and reaches the vicinity of the ceiling of the computer room 30, and then the air conditioning system 34 sucks the warm air from the upper part of the wall surface or the opening of the ceiling (not shown). By cooling, it becomes cold air again and circulates in the computer room 30.
In this way, if the cool air passage and the warm air passage are clearly separated, the cool air and the warm air are less mixed, so that the air cooled using the air conditioning system can be efficiently supplied to the electronic device.

  However, when the calorific value is increased due to higher density of electronic devices, it is not easy to enhance the air conditioning capability of the air conditioning system 34 that cools the computer room 30. In addition, it can be said that the warm air passage 3 and the cold air passage 2 are separated, and the warm air enters the cooling passage 2, or the cold air is sucked into the air conditioning system 34 without cooling the electronic device storage rack 20, thereby reducing the cooling efficiency. Sometimes. Furthermore, when a dynamic change in the position of a hot spot occurs due to a change in the use state of a computer or the like, a static air conditioning system that cools the entire computer room cannot cope.

<First Embodiment>
For convenience of explanation, the explanation starts from FIG. FIG. 7 is a diagram (a) showing a place where cool air is discharged from the front, a diagram (b) showing a place where warm air is sucked from the back, and (a) and (b) in the first embodiment. It is sectional drawing (c) in c. On the front side of the cooling device 1, there is a front door 12, and the front door 12 is provided with a cold air outlet 10. It can be seen that the cooling device 1 is provided with the first slat 16 and the infrared sensor 19 through the cold air outlet 10. Further, a rear door 13 is provided on the rear side of the cooling device 1, and the rear door 13 is provided with a warm air suction opening 11, through which the second blade 17 is cooled. It can be seen that the device 1 is equipped.

  In (c), the first slat 16 is directed to the left and the second slat 17 is directed to the right. Accordingly, a larger amount of warm air 42 is sucked from the right direction by the fan 14 from the warm air passage 3 and becomes an air flow 40 as shown in the figure, and is cooled when the warm air 42 passes through the heat exchanger 15. More cold air 41 is discharged leftward into the passage 2. In (b), the warm air 42 is sucked from the left direction, and (a) shows the cold air 41 being discharged in the left direction. In the present embodiment, the flap 18 is kept straight in the air flow direction.

  This figure shows the state when the first slat 16 in the first embodiment is maximally directed leftward in a front view, and is attached to the first slat 16 as will be described in detail later. The infrared sensor 19 moves back and forth between the left and right directions in front view together with the first slat 16 and senses the temperature of the electronic device storage rack 21 facing the cooling passage 2. In the present embodiment, the first slat 16 can be oriented about 40 degrees on the left side and about 30 degrees on the right side, and the overall viewing angle is about 70 degrees. Of course, these angles are not limited to this, and how these angles are determined will be described later.

  In addition, this figure shows a state when the second wing plate 17 in the first embodiment is turned to the maximum in the left direction when viewed from the front. As will be described in detail later, the first wing plate 17 is In order to draw more warm air from the direction of the electronic equipment storage rack that is assumed to generate more heat than the electronic equipment storage racks on both sides, etc., it moves back and forth between the left and right directions in front view. Or In the present embodiment, the second slat 17 has a viewing angle of about 45 degrees at the same left and right angles. Of course, these angles are not limited to this.

  FIG. 1 is a plan view (a) and a sectional view (b) for explaining the flow of air in a computer room 30 to which the cooling device 1 of the first embodiment of the present invention is applied. As a result of blowing out the cool air cooled by the air conditioning system 34 to the underfloor space 33, the cool air is blown upward from the floor opening 32 to form the cool air passage 2 as in FIG. Moreover, the place where such a cool air passage 2 and a warm air passage 3 appear alternately is the same.

  As shown in (a), the cooling device 1 according to the first embodiment has a ratio of one to three electronic device storage racks in the row of the electronic device storage racks 21 or at the end of the row. Has been placed. Further, as will be described later, between the two electronic equipment storage rack rows facing each other with one cooling passage 2 interposed therebetween, the cooling device 1 does not come in front of each other with the cooling devices 1 in the opposite rows. They are staggered.

  As shown in (b), when two electronic device storage rack rows (placed by a two-dot chain line) facing each other across one cooling passage 2 at the center are viewed from the floor opening 32. The blown cold air is sucked from the electronic device storage rack 21 in the right electronic device storage rack row, and the warm air heated by the electronic device storage rack 21 is discharged to the warm air passage 3 on the right side of the electronic device storage rack row. Is done. Further, the cooling device 1 for the left electronic device storage rack row sucks the warm air from the warm air passage 3 on the left side of the electronic device storage rack row, cools it, and then cools the electronic devices in the right electronic device storage rack row facing each other. Cool air is discharged into the cooling passage 2 toward the storage rack 21.

  FIG. 2 is a plan view showing a cooling system in which the cooling device 1 of the first embodiment is applied to the computer room 30, and is an enlarged view of a portion surrounded by a two-dot chain line in FIG. The cooling devices 1 in the electronic device storage rack rows on both sides are arranged offset from each other. Further, as described above, since the cooling device 1 can discharge cool air toward the cooling passage 2 at a certain viewing angle, the cool device 1 discharges cool air to the three opposing electronic device storage racks 21. Can do. A certain viewing angle is determined by the total width of three opposing electronic equipment storage racks that are separated from the width of the cold air passage 2, and in this embodiment, as described above, the right side is about 30 degrees and the left side is about 40 degrees. The total viewing angle is about 70 degrees. In the present embodiment, there are three units, but the number of electronic device storage racks 21 that can be shared by one cooling device 1 is the viewing angle for discharging the cool air of the cooling device 1, the ability to reach the cool air, the cold air passage width, and the like. Of course, it is not limited to three.

  When attention is paid to one specific cooling device 100, this cooling device 100 is in charge of three electronic equipment storage racks 210, 211, 212, and has the highest temperature among the three devices by a method described later. Cool air is released toward the electronic equipment storage rack. Therefore, among the electronic device storage racks 210, 211, and 212 that the cooling device 1 is in charge of, the electronic device storage rack, for example, 210 that generates a large amount of heat, can be locally cooled, effectively and efficiently. It becomes possible to cool the equipment storage rack group.

  In addition, when time elapses and the electronic device storage rack 210 is cooled, for example, when the amount of heat generated in the electronic device storage rack 212 increases, the cooling device 1 senses this and puts it in the electronic device storage rack 212. The cool air can be released. Therefore, it is possible to effectively and efficiently cool the electronic device storage rack group by responding to changes in the heat generation amount of the electronic device storage rack.

  In this way, one cooling device 1 shares three electronic device storage racks, and the cooling devices 1 of the electronic device storage rack rows are shifted from each other, so that the cooling passage shown in FIG. 2, the upper base is the width of the cooling device 1, the lower base is the width of the three electronic equipment storage racks, and the height is the width of the cold air passage 1 so that one region does not overlap and there is no gap, It is divided into trapezoids (r1 to r8). In the example of the cooling device 100 and the electronic device storage racks 210, 211, and 212 described above, these form a trapezoid r3. By doing in this way, it becomes possible to provide the system which cools the electronic device storage rack group uniformly without the cold air from the cooling device 1 colliding. In addition, there is an effect that the movement of heat across these regions in the cool air passage is suppressed by the wind curtain effect.

  In addition, since the cooling device 1 at the end of the electronic device storage rack row matches the position of the end of the electronic device storage rack row between the rows, the number of electronic device storage racks to be shared is adjusted (in this embodiment, 2).

  The cooling device 1 in the present embodiment sucks warm air from the back side facing the warm air passage 3. At this time, by sucking warm air from a hot spot where higher warm air exists, it is possible to contribute to elimination of the hot spot. For example, when the electronic device storage rack 213 uses more power or current among the electronic device storage racks 213 and 214 on both sides of the cooling device 100, more warm air is generated from the direction of the electronic device storage rack 213. By sucking the air, it is possible to prevent the warm air around the electronic equipment storage rack 213 from going around the cool air passage side. Details will be described later.

  3A is a front view, FIG. 3B is a rear view, FIG. 3C is a side view, and FIG. 3D is a top view. The direction facing the cool air passage is the front, and the direction facing the warm air passage is the back. The front door 12 is provided with a cool air blowing opening 10 on the front side, and the back door 13 is provided with a warm air suction opening 11 on the back side. The side surface comes into contact with the electronic device storage rack 21 or appears as an end of the electronic device storage rack row. It is desirable that the height and depth (width of the side surface) of the cooling device 1 be adapted to a standardized electronic equipment storage rack. The width of the cooling device 1 (the width of the front door 12 and the back door 13) is determined according to the cooling capacity of the cooling device 1 and the like.

  FIG. 4 is a cross-sectional view of the first embodiment taken along section 4 in FIG. A second slat 17 is provided immediately behind the back door 13 and defines the direction in which warm air is sucked. This regulation is performed by a suction direction control unit 161 described later. Six fans 14 are provided vertically at the back of the second slat 17 (on the left side in the figure). As shown in FIG. 9, the details of the fan 14 are blower fans. However, the fan 14 is not limited to this. The fan 14 creates an air flow from the warm air passage 3 side to the cold air passage 2 side. The number and size of the fans 14 are determined according to the cooling capacity of the cooling device 1. Usually, since a hot spot often occurs in the upper portion of the warm air passage 3, the air blowing capacity of the upper fan 14 in the cooling device 1 may be increased.

  A heat exchanger 15 is provided at the back of the fan 14 (on the left side in the figure). The heat exchanger 15 extends over the entire height and width of the cooling device 1 in order to make the warm air passing through the cooling device 1 cool without leaking. As shown in FIG. 8, the details of the heat exchanger 15 are water-cooled to obtain a high cooling capacity, and are supplied with water by a water-cooling pipe 35. A radiator 151 is provided. Of course, this may be a refrigerant type. In the present embodiment, the heat exchanger 15 is provided in the back of the fan 14 (on the left side in the figure), but conversely, the heat exchanger 15 is provided in the back of the second slats 17. A fan 14 may be provided in the back.

  A flap 18 is provided in the back of the heat exchanger 15 (on the left side in the figure). In the present embodiment, a straight state is maintained in the air flowing direction. Note that the flap 18 is controlled by the flap controller 161.

  A first slat 16 is provided at the further back of the flap 18 (left side in the figure), that is, immediately behind the front door 12, and defines the direction in which cool air is discharged. The discharge direction control unit 161 provided at the lower back of the first slat 16 controls this regulation. Details will be described later.

  FIG. 5 is a perspective view of the present embodiment as viewed from the front side. It can be seen that a first slat 16 is provided in the back of the cold air outlet 10 of the front door 12.

  FIG. 6A is a flowchart showing control of the first slat 16 by the discharge direction control unit 161 in the present embodiment. In the flowchart, “S” indicates a step of each process.

  First, when the power of the cooling device 1 is turned on (S100), control for initial positioning of the first slat 16 is performed (S102). As the premise of this control, setting of the viewing angle at the time of sensing (in this embodiment, the center position as a reference angle, a range of about 30 degrees on the right and 40 degrees on the left), setting of the resolution (number of sensing points, angle) Then, setting of the sensing interval time (for example, once every 10 minutes) is performed (S104).

Next, the electronic device storage rack 21 shared by the cooling device 1 facing the cold air passage 2 is subjected to infrared sensing by the infrared sensor 19 provided on the first slat 16 over a set viewing angle. Then, the radiant energy of the electronic device storage rack 21 is measured (S106). For example, in this embodiment, when the number of sensing points is n, the sensing setting angle is zz degrees, and radiant energy measurement is performed,
30 ° + 40 ° = zz ° x n
The relationship holds.

  In this embodiment, there are two operation modes, the operation mode 00 is PeakCooling, and the operation mode 01 is PIDCooling (S108). In the operation mode 00, the maximum measurement value is detected and the measurement location is determined (S118). That is, the maximum value is detected from the measurement results m1, m2,. Then, the first slat 16 is controlled in order to release cool air toward the measurement position (S120). Once the orientation of the first slat 16 is determined, the set sensing interval time is waited (S116).

  In the operation mode 01, first, an average value of the left and right measured values is calculated (S110). Specifically, using the current position of the first slat 16 as a reference, the measurement average value XX on the left side and the measurement average value YY on the right side are calculated from that position. Then, an operation amount is calculated so that it can be brought close to the target value smoothly by PID control (S112). Based on the calculated operation amount, the direction of the first slat 16 is controlled (S114). Once the orientation of the first slat 16 is determined, the set sensing interval time is waited (S116).

  In any operation mode, after waiting for the set sensing interval time, the radiant energy of the electronic device storage rack 21 in the next cycle is measured (S106). By repeating this, when there is a change in the amount of heat generated in the electronic device storage rack 21 shared by the cooling device 1, it is possible to follow the change and cause the cool air to be directed to the electronic device storage rack 21 having a large heat generation amount. By locally cooling a large amount of electronic equipment storage racks and responding to changes in heat generation, it is possible to construct a cooling system that effectively and efficiently cools electronic equipment storage racks as a whole. It becomes.

  FIG. 6B is a flowchart showing the control of the second slats 17 by the suction direction control unit 161 in the present embodiment. First, when the power supply of the cooling device 1 is turned on (S200), control for initial positioning of the second slats 17 is performed (S202). As a premise of this control, a sensing interval time is set (for example, once every 10 minutes) (S204).

  Next, the power value or current value of the two electronic device storage racks 21 on both sides of the cool air device 1 is sensed. Moreover, you may sense the electric power value or electric current value of all or one part electronic device storage rack group in the left side and the right side of this cooling device 1 in an electronic device storage rack row | line | column. Here, for the latter, measurement is performed for each of the three adjacent vehicles (S206). The sum of the power value or current value (x1, x2, x3) of the electronic device storage rack group on the left side of the cooling device 1 is Px, and the power value or current value (y1, y2, y2) of the electronic device storage rack group on the right side. The sum of y3) is set as Py, and the comparison is performed (S208). When Px is larger than Py, the suction direction control unit 161 turns the second wing plate 17 to the left (S214). Conversely, if Py is greater than Px, the second slat 17 is turned to the right (S216). If Px and Py are equal, the suction direction control unit 161 controls the second wing plate 17 to face the center (S210).

  In any case, after waiting for the set sensing interval time, the power value of the next cycle is measured (S206). By repeating this, if there is a change in the amount of power of the electronic device storage rack 21 of the cooling device 1 or the like, the direction of sucking warm air is changed following the change, so that the warm air flows toward the cold air passage side. It is possible to prevent wraparound and contribute to the elimination of hot spots that occur in this way, so that it is possible to build a cooling system that effectively and efficiently cools the electronic equipment storage racks as a whole. It becomes.

Second Embodiment
FIG. 10 is a diagram (a) showing the discharge of cool air from the front in the second embodiment, and a cross-sectional view (b) at b in (a). There is a front door 12A on the front side of the cooling device 1A, and the front door 12A is provided with a cold air outlet 10A. It can be seen that the first blade 16A and the infrared sensor 19 are provided in the two systems, the cooling device 1A, through the cold air blowing opening 10A. The back side of the cooling device 1 is the same as that in the first embodiment.

  In (b), the first slat 16A is directed leftward and rightward from the center. Inside, the air flow sucked from the back door 13 and cooled is bent toward the first slat 16A of the left system by the flap 18 being directed to the right in the figure, and more Can send cold air. In addition, more cold air 41 is discharged to the cold air passage 2 in the left direction, and the cold air 41 can be discharged in the right direction. Accordingly, while supplying cool air to the electronic device storage rack having the second largest amount of heat generation among the electronic device storage racks shared by the cooling device 1A, a larger air volume is given to the electronic device storage rack having the largest heat generation amount. Thus, the electronic device storage rack group can be cooled effectively and efficiently.

  In this figure, in the second embodiment, the first slat 16A of one system is maximally directed leftward in front view, and the first slat 16A of other system is maximally directed rightward in front view. It shows a state of turning. As in the first embodiment, the first slat 16A senses the temperature of the electronic equipment storage rack 21 that faces the cooling passage 2 with the infrared sensor 19, so that the first wing plate 16A performs between the left direction and the right direction when viewed from the front. To come.

  In this figure, there are three electronic device storage racks to be shared, the electronic device storage rack on the left side as viewed from the cooling device 1 has the largest amount of heat generation, and the electronic device storage rack on the right side is the second. The first first slat 16A is drawn assuming a large amount of heat generation, and one of the first slats 16A releases more cool air toward the leftmost electronic device storage rack. The remaining cool air is also discharged toward the rightmost electronic device storage rack.

  If the electronic equipment storage rack at the center of the three electronic equipment storage racks has the largest amount of heat, the first slat 16A of one system will release cool air straight toward the front. Become.

DESCRIPTION OF SYMBOLS 1 Cooling device 2 Cold air passage 3 Warm air passage 10 Cold air blowing opening 11 Warm air suction opening 12 Front door 13 Rear door 14 Fan 15 Heat exchanger 151 Radiator 16 First blade 161 Release direction control unit, flap control unit, suction direction Control unit 17 Second slat 18 Flap 19 Infrared sensor 20 Electronic equipment storage rack group 21 Electronic equipment storage rack 30 Computer room 31 Floor 32 Floor opening 33 Underfloor space 34 Air conditioning system 35 Water cooling pipe 40 Air flow 41 Cool air 42 Warm air r1 to r8 Area shared by the cooling device

Claims (7)

A plurality of electronic device storage racks having electronic devices therein are installed in a plurality of rows, and a passage formed between the rows of the electronic device storage racks facing each other is alternately a cold air passage and a warm air passage. A cooling device for cooling a group of electronic equipment storage racks arranged to form,
The cooling device is disposed between the electronic device storage racks or at the end of the row,
A fan that creates an air flow from the warm air passage to the cold air passage;
A heat exchanger that cools the warm air in the warm air passage;
A first slat facing the cold air passage and defining a discharge direction of the cold air discharged into the cold air passage;
An infrared sensor for monitoring the temperature of at least one of the electronic equipment storage racks facing the cold air passage;
Based on the temperature obtained from the infrared sensor, a discharge direction control unit that controls the direction of the first slats, and
The discharge direction control unit controls the direction of the first slat so as to discharge the cold air toward a specific electronic device storage rack in the electronic device storage rack monitored by the infrared sensor. A cooling device characterized. The specific electronic device storage rack is an electronic device storage rack having the highest temperature among the monitored electronic device storage racks,
2. The cooling according to claim 1, wherein the discharge direction control unit controls the direction of the first slat so as to discharge the cold air toward the electronic equipment storage rack having the highest temperature. apparatus. The specific electronic device storage rack is an electronic device storage rack having the highest temperature among the monitored electronic device storage racks and an electronic device storage rack having the second highest temperature.
The discharge direction control unit has two systems, the first slat of one system is in the direction of the electronic equipment storage rack having the highest temperature, and the first slat of the other system is second. Controlling the direction of the first slats to release the cold air toward the electronic device storage rack having the high temperature,
Furthermore, a partition plate provided with a flap that distributes the air flow from the fan to the first slat of the one system and the first slat of the other system, and a flap control unit that controls the direction of the flap of the partition plate Prepared,
2. The flap control unit according to claim 1, wherein a majority of the amount of air discharged from the fan is distributed to the first slats of the one system, and the rest is distributed to the first slats of the other system. The cooling device as described. Furthermore, a power sensor or a current sensor for the electronic equipment storage rack next to the cooling device,
A second slat that faces the warm air passage and defines a suction direction of the warm air;
A suction direction control unit that controls the direction of the second slats based on the power value or current value obtained from the power sensor or current sensor, and
The suction direction control unit is configured so that the second slats are sucked so as to suck the warm air from an electronic equipment storage rack having a higher power value or current value among electronic equipment storage racks adjacent to the cooling device. The cooling device according to claim 1, wherein the cooling device is controlled.   The cooling device according to any one of claims 1 to 4, further comprising an air volume control unit that controls an air volume of the fan. A system for cooling electronic equipment storage rack groups on both sides of a cold air passage using the cooling device according to claim 1,
The one cooling device is the electronic equipment storage rack facing the cold air passage monitored by the one cooling device, and the cool air discharged by the cooling device is directed to the first slat of the cooling device. The electronic equipment storage rack in the area reached by the change of
The electronic device storage rack, wherein the cooling device is arranged in the electronic device storage rack row on both sides of the cold air passage so that the region does not overlap in the cold air passage and there is no gap. A system to cool the group. A method for cooling an electronic device storage rack group on both sides of a cold air passage using the cooling device according to claim 1,
The one cooling device is the electronic equipment storage rack facing the cold air passage monitored by the one cooling device, and the cool air discharged by the cooling device is directed to the first slat of the cooling device. The electronic equipment storage rack in the area reached by the change of
The cooling device is arranged in the electronic equipment storage rack row on both sides of the cold air passage so that the region does not overlap and there is no gap in the cold air passage,
The cooling device releases the cool air toward a specific electronic device storage rack in the electronic device storage rack monitored by the cooling device, and cools the electronic device storage rack to be monitored. A method of cooling the equipment storage rack group.