JP2010129779A - Air conditioning device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve a cooling efficiency by effectively utilizing a heat exchanger in a low air volume operation in an air conditioning device for cooling a space where a plurality of racks on which electronic equipment such as a server or the like is mounted are disposed. <P>SOLUTION: An air conditioning device (10) includes a casing (11) of which an air intake (11c) is formed on a rear surface (11b) and an air outlet (11d) is formed on a front surface (11a), and three blast fans (12) and a heat exchanger (14) are arranged in the casing (11). On the front side in the casing (11), three installation tables (21) for installing the three blast fans (12), respectively, are arranged in the vertical direction at a predetermined interval, and an opening (21a) communicating an upper space and a lower space partitioned by each of the installation tables (21) is formed in each of the installation tables (21). <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an air conditioner for cooling a space in which a plurality of racks on which electronic devices such as servers are mounted are arranged.

  Conventionally, various cooling systems that cool a peripheral space of a rack on which high-performance electronic devices such as servers that generate high heat during operation are mounted have been used (for example, see Patent Document 1 below).

  Patent Document 1 discloses an air conditioner in which a plurality of rack rows in which a plurality of racks on which electronic devices are mounted are arranged are formed, and an air conditioner is suspended from the ceiling above a space formed between the rack rows. A system is disclosed. In this air conditioning system, the air in the space formed between the rack rows is cooled by the air conditioner, and the cooled air is taken into the rack, thereby cooling the electronic devices in each rack.

  However, in the above air conditioning system, since an air conditioner is provided above the space formed between the rack rows, a certain amount of space must be secured above the rack, which is used in a server room or the like having a low ceiling height. There was a problem that I could not.

  Thus, a rack type air conditioner has been proposed. The air conditioner includes a casing that is substantially equal in height and depth to a rack on which electronic devices are mounted, and that has an air intake port and an air outlet, and the intake port is connected to the air outlet in the casing. A blower fan that circulates air over the motor, a motor that rotationally drives the blower fan, and a water-cooled heat exchanger that exchanges heat between the cooling water that flows through the air and the air are provided. And if a ventilation fan is driven, the air taken in in the casing from the inlet will be cooled in a heat exchanger, and will be discharged | emitted from a blower outlet.

When such an air conditioner is inserted into a rack row formed in the same manner as in Patent Document 1, the air in the space between the rack rows heated by exhaust heat from the electronic device is transferred to the air conditioner. The air is sucked and cooled, and the cooled air is discharged into the space between the rack rows. Thereby, the air in the space between the rack rows is cooled, and the cooled air is taken into the rack in which the electronic device is mounted, whereby the electronic device in the rack is cooled.
JP 2003-166729 A

  In the above air conditioner, in order to suppress an increase in the width, a plurality of relatively small blowing fans are used in a narrow casing, and these are arranged in the vertical direction. The plurality of blower fans are respectively installed on a plurality of installation tables that are spanned in the width direction and arranged in the vertical direction in the casing. The heat exchanger is formed from the upper part to the lower part in the casing so as to correspond to the blower fans arranged in the vertical direction.

  By the way, in the said air conditioning apparatus, the blowing of an air conditioning apparatus is carried out by stopping some ventilation fans among several ventilation fans, or reducing the rotational speed of some ventilation fans among several ventilation fans. Low air volume operation with reduced air volume may be performed.

  However, as described above, in the air conditioner, since the plurality of blower fans are arranged in the vertical direction, the inside of the casing is partitioned into a plurality of spaces in the vertical direction by the mounting base for installing each blower fan. End up. Therefore, for example, when a part of the blower fans is stopped to perform low airflow operation, air stays in the space where the stopped blower fans are provided, and the air is only directed toward the blower fan in operation in the casing. A flow will be formed. Thereby, since the air taken in in the casing passes only a part of the heat exchanger (the part corresponding to the blowing fan during operation), there is a problem that the heat exchanger cannot be used effectively.

  Also, if the rotational speed of some blower fans is reduced to perform low airflow operation, the air suction amount of the blower fans during low-speed rotation is reduced. The amount of air passing through the portion to be reduced is smaller than the amount of air passing through the portion corresponding to the blowing fan rotating at the rated speed. For this reason, the amount of air passing through the heat exchanger is not uniform and varies depending on the portion, and thus there is a problem that the heat exchanger cannot be effectively used.

  The present invention has been made in view of the above points, and an object of the present invention is to provide an air conditioner for cooling a space in which a plurality of racks on which electronic devices such as servers are mounted are provided, and a low air flow rate. It is to improve the cooling efficiency by effectively using a heat exchanger during operation.

  The first invention includes a casing (11) having an air inlet (11c) formed on the back surface (11b) and an air outlet (11d) formed on the front surface (11a). ), A plurality of blower fans (12) for circulating air from the intake port (11c) toward the blowout port (11d) in the casing (11), and upstream of the blower fan (12) An air conditioner provided with a heat exchanger (14) for cooling the air flowing through the casing (11) by the blower fan (12), wherein the casing (11) includes: A plurality of mounting tables (21) on which the plurality of blower fans (12) are respectively installed are arranged at predetermined intervals in the vertical direction, and each of the mounting tables (21) is arranged by the mounting table (21). An opening (21a) that connects the upper space and the lower space to be partitioned is formed.

  In the first invention, since the opening (21a) is formed in each mounting base (21), the space partitioned in the vertical direction by the mounting base (21) is communicated. Therefore, each blower fan (12) sucks air not only from the back surface (11b) side of the casing (11) but also from the upper and lower spaces through the opening (21a) of the mounting base (21). Can do. Therefore, even if the operation of some blower fans (12) is stopped to perform low airflow operation, the blower fan (12) in operation is only from the back (11b) side of the casing (11). In addition, the air blower fan (when the operation is stopped) is sucked through the opening (21a) of the mounting base (21) by sucking air from the space where the air blower fan (12) during the upper operation or lower operation stop is provided. Air is also drawn into the space provided with 12). Thereby, in the casing (11), the air flow is uniformly formed over the whole without being formed in a part in the vertical direction. Therefore, even when the operation of some of the blower fans (12) is stopped in order to perform the low air volume operation, the air can be uniformly distributed over the entire heat exchanger (14).

  In addition, if the rotational speed of some blower fans (12) is reduced to perform low airflow operation, the amount of suction of the blower fan (12) during low-speed rotation will decrease, but it will be operating at the rated speed. The blower fan (12) is rotating not only from the back surface (11b) side of the casing (11) but also through the opening (21a) of the mounting base (21) at the lower or upper rotational speed. By sucking air from the provided spaces, air is uniformly drawn into each space. Thereby, in the casing (11), the flow of air is uniformly formed over the entire vertical direction. Therefore, even when the rotational speed of some of the blower fans (12) is reduced in order to perform the low air volume operation, the air can be uniformly distributed throughout the heat exchanger (14).

  According to a second invention, in the first invention, each of the blower fans (12) is constituted by a double-suction sirocco fan in which suction ports (22) are formed on both end surfaces in the axial direction. (23) is arranged so as to face the front surface (11a) of the casing (11), and a motor (13) for rotationally driving the blower fan (12) is provided on the side of each of the blower fans (12). Has been placed.

  In the second invention, a double-suction sirocco fan is used as the blower fan (12). Thus, when a double-suction type sirocco fan is used as the blower fan (12), both the suction ports (22) are laterally directed so that the air outlet (23) faces the front surface (11a) of the casing (11). Placed in. Therefore, the blower fan (12) and the motor (13) must be arranged side by side in the width direction in the narrow casing (11), and the side of the blower fan (12) (around the inlet (22)) A large space cannot be secured. As a result, the suction efficiency of the blower fan (12) may be reduced. However, each mounting base (21) is formed with an opening (21a) that communicates the upper space and the lower space partitioned by the mounting base (21). Thereby, the space around the suction port (22) of the blower fan (12) is substantially expanded, and the blower fan (12) easily sucks air.

  In a third aspect based on the second aspect, the opening (21a) of each mounting base (21) is formed from below the blower fan (12) to below the motor (13). .

  In 3rd invention, since the opening part (21a) of the installation base (21) is large formed from the downward direction of a ventilation fan (12) to the downward direction of a motor (13), this installation base (21) Air becomes easier to circulate between the upper space and the lower space. As a result, the air in one of the spaces arranged in the vertical direction of the mounting base (21) is easily sucked into the blower fan (12) installed in the other space.

  According to a fourth invention, in the second or third invention, each of the blower fans (12) is installed on the installation table (21) together with the motor (13) via a support table (18), and the support table In (18), an opening (19) is formed at a position corresponding to the opening (21a) of the mounting base (21).

  In 4th invention, a ventilation fan (12) is installed in an installation stand (21) with a motor (13) via a support stand (18). In addition, since the opening (19) is formed in the support base (18) at a position corresponding to the opening (21a) of the mounting base (21), the mounting base (21) is formed by the support base (18). The opening (21a) is not blocked.

  According to a fifth aspect of the present invention, in any one of the first to fourth aspects, the three blower fans (12) are provided, and the air volume reducing means (81) for reducing the air volume of the air blown from the casing (11). The air volume reducing means (81) operates the blower fan (12) disposed on the upper and lower sides of the three blower fans (12), while the blower fan (12) disposed in the middle ( 12) The first operation number control unit (82) for stopping the operation and the blower fan (12) arranged in the middle of the three blower fans (12) are operated, while the upper and lower sides are operated. A second operation number control unit (83) for stopping the operation of the arranged blower fan (12).

  In the fifth invention, the air volume reducing means (81) reduces the air volume of the air blown out from the casing (11) by reducing the number of operating units of the three blower fans (12). The air volume reducing means (81) includes a first operating number control unit (82) and a second operating number control unit (83), and the blowing fan (12) during operation and the blowing fan (12) during operation stop. ) Are alternately arranged in the vertical direction, the number of operating units of the three blower fans (12) is reduced.

  According to a sixth aspect of the present invention, in any one of the first to fourth aspects, three air blowing fans (12) are provided, and an air volume reducing means (81) for reducing the air volume of the air blown out from the casing (11). The air volume reducing means (81) is arranged in the middle while rotating the blower fan (12) disposed on the upper side and the lower side of the three blower fans (12) at a rated speed. The first rotational speed control unit (84) for reducing the rotational speed of the blower fan (12) and the blower fan (12) arranged in the middle of the three blower fans (12) are rotated at the rated speed. On the other hand, the 2nd rotational speed control part (85) which reduces the rotational speed of the ventilation fan (12) arrange | positioned at the upper side and the lower side is provided.

  In the sixth invention, the air volume reducing means (81) reduces the air volume of the air blown from the casing (11) by reducing the rotational speed of the three blower fans (12). The air volume reducing means (81) includes a first rotation speed control unit (84) and a second rotation speed control unit (85), and a blower fan (12) rotating at a rated speed and a blower fan rotating at a low speed. The rotational speed of each blower fan (12) is reduced so that (12) and are alternately arranged in the vertical direction.

  According to the present invention, when the operation of some of the blower fans (12) is stopped in order to perform the low air flow operation by forming the opening (21a) in each mounting base (21), When the air blower fan (12) sucks air from the space where the air blower fan (12) is stopped, and the rotational speed of some of the fan fans (12) is reduced to perform low airflow operation The air blowing fan (12) rotating at the rated speed sucks air from the space provided with the air blowing fan (12) whose rotational speed is reduced. As a result, the pressure in each space partitioned by the plurality of installation bases (21) can be made uniform so that air can flow uniformly into each space. Therefore, the air flow can be uniformly formed in the casing (11) in the vertical direction, and the air can be uniformly circulated throughout the heat exchanger (14). Therefore, according to the present invention, the heat exchanger (14) can be used effectively when performing low airflow operation, and the cooling efficiency can be improved.

  Further, according to the present invention, when the operation of some of the blower fans (12) is stopped in order to perform the low air flow operation, the suction efficiency of the blower fans (12) during operation can be improved, When the rotational speed of some of the blower fans (12) is reduced in order to perform the low air volume operation, the suction efficiency of the blower fans (12) rotating at the rated speed can be improved.

  Further, according to the second invention, when a double-suction type sirocco fan is used as the blower fan (12), a large space cannot be secured on the side of the suction port (22) of the sirocco fan due to arrangement restrictions. There exists a possibility that the suction efficiency of a ventilation fan (12) may fall. However, as described above, by forming the opening (21a) in each mounting base (21), the upper space partitioned by the mounting base (21) communicates with the lower space. The space around the inlet (22) of the blower fan (12) is expanded. Thereby, the pressure loss of the air in both suction inlets (22) is reduced, and the amount of suction can be increased. Therefore, even if a double-suction type sirocco fan is used as the blower fan (12), the blowing efficiency of the blower fan (12) can be improved by forming the opening (21a) in each mounting base (21). Can be improved.

  According to the third invention, the opening (21a) of each mounting base (21) extends from below the blower fan (12) installed on the mounting base (21) to below the motor (13). Therefore, the pressure loss of the air flowing through the opening (21a) is reduced, and the air can easily flow between the upper space and the lower space of the mounting base (21). As a result, when performing low airflow operation, the pressure in each space partitioned by the plurality of mounting bases (21) can be further uniformed to effectively use the heat exchanger (14), thereby improving the cooling efficiency. be able to.

  According to the fourth aspect of the invention, the support base (18) for integrally installing the blower fan (12) and the motor (13) on the installation base (21) is provided, and the support base (18) By forming the opening (19a) corresponding to the opening (21a) of the mounting base (21), the blower fan can be easily and once performed without closing the opening (21a) of the mounting base (21). (12) and the motor (13) can be installed on the installation base (21).

  Further, according to the fifth aspect, the air volume reducing means (81) is configured so that the blowing fan (12) during operation and the blowing fan (12) during operation are alternately arranged in the vertical direction. It is comprised so that the driving | operation of any one or two ventilation fans (12) of the ventilation fans (12) of a stand may be stopped. As a result, during the low airflow operation, the blowing fan (12) that is in operation and the blowing fan (12) that is not operating are arranged in the adjacent space, so the blowing fan (12) that is not operating is arranged. The air in the generated space is easily sucked by the blowing fan (12) during operation. Therefore, when the number of operating fans (12) is reduced and low airflow operation is performed, the pressure in each space partitioned by the mounting base (21) can be made more uniform, further improving the cooling efficiency. Can be planned.

  According to the sixth invention, the air volume reducing means (81) is arranged such that the blower fan (12) rotating at the rated speed and the blower fan (12) rotating at the low speed are alternately arranged in the vertical direction. By configuring the blower fan (12) to operate at a low air flow rate by reducing the rotational speed, the blower fan (12) rotating at the rated speed opens the opening (21a) of the mounting base (21). It becomes easier to suck air from the space provided with the blower fan (12) rotating at low speed. Therefore, when reducing the rotational speed of the blower fan (12) and performing low airflow operation, the pressure in each space partitioned by the mounting base (21) can be made more uniform, further improving the cooling efficiency. Can be planned.

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

Embodiment 1 of the Invention
FIG. 1 is a schematic plan view of a server room (1) in which an air conditioner (10) according to the present invention is installed. As shown in FIG. 1, a plurality of racks (2) on which electronic devices such as servers are mounted are provided in the server room (1). The front surface (2a) of each rack (2) is formed with an intake port for taking air into the interior, and the rear surface (2b) is formed with an air outlet for discharging the air.

  The plurality of racks (2) are arranged in a row in the width direction to form a rack row (3). The rack row (3) is formed in a plurality of rows (six rows in FIG. 1) in the server room (1). The plurality of rack rows (3) are arranged so that the front surfaces (2a) or the back surfaces (2b) of the racks (2) face each other. With this arrangement, a front space (A) facing the front surface (2a) of each rack is formed in front of each rack (2), and each rack (2) is positioned behind each rack (2). A rear space (B) facing the back surface (2b) of 2) is formed.

  The air conditioner (10) is inserted between the racks (2) in the rack row (3). The air conditioner (10) is provided so that the front surface (11a) of the casing (11) faces the front space (A), and the back surface (11b) faces the rear space (B). Note that a plurality of air conditioners (10) are provided in the server room (1), and in this embodiment, provided for every five racks (2) in the rack row (3).

  As shown in FIG. 2, the air conditioner (10) includes a casing (11), a blower fan (12), a motor (13) that rotationally drives the blower fan (12), and a heat exchanger (14). And. The blower fan (12), the motor (13), and the heat exchanger (14) are provided in the casing (11). The blower fan (12) and the motor (13) are assembled to form a fan unit (15).

  In the present embodiment, the casing (11) is formed in a bowl-like body having substantially the same depth length and height as the rack (2). The back surface (11b) of the casing (11) is formed with an intake port (11c) for taking air into the interior, and the front surface (11a) is formed with an air outlet (11d) for exhausting the air inside. Has been. Further, the front plate (11g) of the casing (11) is formed with an opening (26) over most of the portion other than the outer edge portion, and a front door that can be opened and closed is attached. On the back plate (11h) of the casing (11), an opening (27) extending over most of the portion other than the outer edge portion is formed, and a freely openable back door is attached. The front surface (11a) of the casing (11) is formed by the front door, and the air outlet (11d) of the casing (11) has a plurality of holes in a plate-like mesh member fitted in the opening of the front door. Is formed by. On the other hand, the back surface (11b) of the casing (11) is formed by the back door, and the intake port (11c) of the casing (11) has a plurality of holes in a plate-like mesh member fitted in the opening of the back door. Is formed by.

  An installation base (21) for installing the fan unit (15) is attached to the front side of the casing (11). In the present embodiment, since three fan units (15) are provided, three installation bases (21) are also provided. As shown in FIG. 3, the three mounting bases (21) are arranged in parallel at a predetermined interval in the vertical direction in front of the casing (11). Each installation base (21) has a rectangular opening (21a). Therefore, the space in front of the casing (11) is divided into four spaces in the vertical direction by the three mounting bases (21), and each mounting base (21a) is separated by the opening (21a) of the mounting base (21). 21) The space above and the space below are communicated.

  As shown in FIG. 4, the fan unit (15) includes the blower fan (12) and the motor (13), and a support base (18) that supports the blower fan (12) and the motor (13). Has been.

  The blower fan (12) is constituted by a sirocco fan provided with an impeller constituted by a plurality of blades in a housing. The blower fan (12) is a double-suction sirocco fan, and suction ports (22) are formed on both end surfaces in the rotation axis direction.

  The motor (13) has a smaller diameter than the blower fan (12). The motor shaft (13a) of the motor (13) is connected to the rotating shaft of the impeller of the blower fan (12). The motor (13) is supported by a motor base (17) installed on the support base (18).

  The motor base (17) is formed to raise the motor (13) so that a motor (13) smaller than the blower fan (12) is arranged coaxially with the blower fan (12). Specifically, it is composed of a rectangular mounting plate (17a) on which the motor (13) is installed, and support legs (17b) that support the mounting plate (17a). The support leg (17b) is constituted by four plate-like bodies extending downward from each side of the mounting plate (17a), and the four plate-like bodies constituting the support leg (17b) have openings (17c) respectively. Is formed. That is, the motor base (17) is formed so that air can freely flow below the mounting plate (17a).

  The support base (18) includes a rectangular bottom plate (18a) and four side plates (18b) extending upward from each side of the bottom plate (18a). An opening (19) is formed in the bottom plate (18a). In the present embodiment, the opening (19) is formed in a rectangular shape and is formed over most of the bottom plate (18a) other than the outer edge portion. The blower fan (12) is provided so as to span between two opposing side plates (18b) of the four side plates (18b), while the motor base (17) has a support leg (17b) having the bottom plate It is provided so as to be installed at the outer edge of (18a). The opening (19) of the bottom plate (18a) is formed from below the blower fan (12) to below the motor base (17) and corresponds to the opening (21a) of the installation base (21). (See FIG. 3).

  With such a configuration, the support base (18) and the motor base (17) are configured so that the opening (21a) of the mounting base (21) on which the fan unit (15) is installed and the blower fan (15) of the fan unit (15) ( Air is circulated between the motor (13) side suction port (22) of 12). That is, the air in the lower space of the installation base (21) that has passed through the opening (21a) of the installation base (21) passes through the opening (19) formed in the support base (18), and then the blower fan ( 12) flows into the space between the motor (13), or passes through the space below the blower fan (12) or below the mounting plate (17a) of the motor base (17) and the motor (12) It flows into the space between and 13) and is sucked into the suction port (22) on the motor (13) side.

  As shown in FIG. 2, each fan unit (15) has both suction ports (22) of each blower fan (12) opening toward the side of the casing (11) and a blower outlet (23). It arrange | positions so that it may open toward the front. In addition, each fan unit (15) is provided with each blower fan (12) in order to reduce the pressure loss of air in the suction port (22) facing the right side plate (11e) of the casing (11) of each blower fan (12). 12) and a lateral distance between the right side plate (11e) of the casing (11) are installed at a predetermined installation position where a predetermined installation distance d is maintained.

  As shown in FIG. 3, the opening (26) of the front plate (11g) of the casing (11) is divided into four in the vertical direction by three mounting bases (21), and is closed by four closing plates (25). Has been. And between the front door of the casing (21), the front plate (11g) and the closing plate (25) and the front door of the casing (11), from the blower outlet (23) of each blower fan (12) A blowing space (24) for merging the blown air is defined.

  Of the four closing plates (25), the closing plate (25) provided in front of the three blower fans (12) is substantially the same size as the outlet (23) of each blower fan (12). An equal opening (25a) is formed. Each blower fan (12) is provided such that the front end portion where the air outlet (23) is formed is engaged with the opening (25a) of each closing plate (25). Thereby, the blowing space (24) is configured so that only the air blown from the blower fan (12) flows.

  As shown in FIG. 2, the heat exchanger (14) is constituted by a so-called fin-and-tube heat exchanger having a plurality of flat fins (14a) and a plurality of heat transfer tubes (14b). Yes. The plurality of fins (14a) are provided so as to extend in the vertical direction, and are arranged in parallel in the horizontal direction at predetermined intervals. On the other hand, the plurality of heat transfer tubes (14b) extend in the arrangement direction (horizontal direction) of the plurality of fins (14a) and are provided so as to penetrate the plurality of fins (14a). In the present embodiment, the heat transfer tube (14b) is connected to a refrigerant circuit (50) described later (see FIG. 6).

  The heat exchanger (14) is disposed such that each heat transfer tube (14b) is inclined with respect to the width direction of the casing (11) and is spaced from the blower fan (12). ing. Specifically, the end of the heat exchanger (14) on the motor (13) side (left end in FIG. 2) is positioned in front of the end on the blower fan (12) side (right end in FIG. 2). By arranging so, a space is provided between the heat exchanger (14) and the blower fan (12).

  The plurality of fins (14a) are arranged so as to extend toward the blower fan (12) and are inclined with respect to the front-rear direction of the casing (11). In the present embodiment, the fin (14a) is provided so as to extend in a direction orthogonal to each heat transfer tube (14b). Therefore, by arranging the heat exchanger (14) as described above, the end (the left end in FIG. 2) of each heat transfer tube (14b) on the motor (13) side is the end on the blower fan (12) side. The plurality of fins (14a) arranged in front of the section (right end in FIG. 2) and extending in a direction orthogonal to the heat transfer tubes (14b) are arranged to extend toward the blower fan (12). It becomes.

  Furthermore, as shown in FIG. 3, the heat exchanger (14) extends from the upper part to the lower part in the casing (11) so as to correspond to the three blower fans (12) arranged in the vertical direction. Is formed. Specifically, the heat exchanger (14) is formed to have a portion facing the three blower fans (12). That is, in the heat exchanger (14), the upper end portion is located above the lower end portion of the uppermost blower fan (12), while the lower end portion is lower than the upper end portion of the lowermost blower fan (12). It is formed so that it may be located in.

<Condensate water treatment equipment>
In addition, as shown in FIG. 3, a dew condensation water treatment device (70) is provided in the casing (11) to collect and discharge dew condensation water when dew condensation occurs on the surface of the heat exchanger (14). It has been. The dew condensation water treatment device (70) includes a drain pan (71) provided below the heat exchanger (14), a sub-drain pan (72) provided further below the drain pan (71), and a drain pan (71) And a drainage pump (73) for discharging the condensed water collected inside to the outside of the apparatus.

  The drain pan (71) is formed by a bowl-shaped body having an open upper surface, is formed so as to surround the lower end portion of the heat exchanger (14), and the lower surface is inclined downward toward the front. On the front surface of the drain pan (71), a discharge part (71a) for discharging the internal dew condensation water is formed. In addition, a cutout portion (71b) is formed on the front surface of the drain pan (71) for overflowing toward the sub-drain pan (72) when the water level in the drain pan (71) exceeds a predetermined level. .

  The sub-drain pan (72) is formed by a rod-shaped body having a larger internal volume than the drain pan (71), the rear surface is located behind the front surface of the drain pan (71), and the front surface is forward of the front surface of the drain pan (71). It is arranged to be located in.

  A suction hose (74) connected to the discharge part (71a) of the drain pan (71) is connected to the drain pump (73), and a drain hose (75) extending to the outside of the apparatus is connected.

  With this configuration, in the unlikely event that condensation occurs on the surface of the heat exchanger (14), the condensed water is first recovered by the drain pan (71), and then the suction hose (74) and drain hose by the drain pump (73). (75) to be discharged outside the apparatus. Also, if the water level in the drain pan (71) rises for some reason, the condensation water overflows from the notch (71b) formed on the front surface of the drain pan (71). Water can be collected in the sub-drain pan (72).

<controller>
The air conditioner (10) includes a controller (100). The controller (100) includes a normal operation means (80) for performing a normal cooling operation (normal operation), which will be described later, and an air volume for reducing the amount of air blown (air volume) of the cooling air from the air conditioner (10). Reducing means (81).

  The normal operation means (80) drives the three blower fans (12) to rotate and drives the circulation pump (51) of the pump unit (55).

  The air volume reducing means (81) includes a first operation number control unit (82) and a second operation number control unit (83), and a part of the three blower fans (12) (12 ) Is stopped to reduce the blowout air volume.

  Specifically, the first operating number control unit (82) operates the blower fan (12) disposed on the upper side and the lower side of the three blower fans (12), and is disposed in the middle. The first operation number control for stopping the operation of the blower fan (12) is performed. On the other hand, the second number-of-operations control unit (83) operates the blower fan (12) arranged in the middle of the three blower fans (12), while the blower fans ( Perform the second operation number control to stop the operation of 12).

  That is, the air volume reducing means (81) is configured so that the blowing fan (12) in operation and the blowing fan (12) in operation stop are alternately arranged in the vertical direction. It is comprised so that the driving | operation of any one or two ventilation fans (12) may be stopped.

<Refrigerant circuit>
As shown in FIG. 6, the refrigerant circuit (50) includes a heat exchanger (14), a circulation pump (51), a second heat exchanger (52), and a receiver tank (53) of the air conditioner (10). ) And a refrigerant pipe connecting them. The circulation pump (51), the second heat exchanger (52), and the receiver tank (53) constitute a pump unit (55), and the pump unit (55) is provided in the server room (1). It is provided in a place separated from the rack row (3).

  The circulation pump (51) pumps the sucked refrigerant to circulate the refrigerant in the refrigerant circuit (50).

  The second heat exchanger (52) has a first flow path (52a) and a second flow path (52b) formed therein, and the first flow path (52a) is connected to the refrigerant circuit (50), The second channel (52b) is connected to a cooling water circuit (60) through which cooling water flows. The second heat exchanger (52) is configured to perform heat exchange between the refrigerant flowing through the first flow path (52a) and the cooling water flowing through the second flow path (52b).

  The receiver tank (53) temporarily stores the refrigerant therein and adjusts the refrigerant circulation amount in the refrigerant circuit (50).

-Cooling operation in the rack by the air conditioner-
As described above, the air conditioner (10) is inserted into the rack row (3) in which the racks (2) on which electronic devices such as servers are mounted are arranged, as shown in FIG.

  By the way, an electronic device usually has a heat generating component. For this reason, the air in the rack (2) on which electronic devices such as servers are mounted is heated by the heat-generating parts and the temperature rises, which may adversely affect other parts.

  Therefore, in the present embodiment, an air inlet is formed in the front surface (2a) of the rack (2), while an air outlet is formed in the rear surface (2b), and the air heated inside is in the front space (A ) And is discharged to the rear space (B) by riding on the air flow introduced (see the broken line arrow in FIG. 1). By treating the exhaust heat in this way, the temperature in each rack (2) is prevented from rising abnormally.

  However, if the exhaust heat treatment is performed as described above, the air heated by the heat generating component is discharged into the rear space (B), and the temperature rises. Therefore, in the present embodiment, as described above, the air conditioner (10) is arranged in the rack row (3) to cool the air around the rack row (3).

  Specifically, the air conditioner (10) takes air of relatively high temperature in the rear space (B) into the casing (11) through an operation described later, cools the casing (11), and then blows the air. Discharge from the outlet (11d) to the front space (A). Thereby, while the temperature rise of the air of back space (B) is suppressed, the air of front space (A) is cooled. Therefore, the air cooled in the front space (A) is introduced into each rack (2) on which electronic devices such as servers are mounted, and the air inside is cooled by the air. In other words, by providing the air conditioner (10) in the rack row (3) in this way, the rack (2) in which electronic devices such as servers are efficiently mounted without cooling the entire interior of the server room (1) The inside can be cooled.

-Operation of air conditioner-
<Normal operation>
In the air conditioner (10), the normal operation means (80) of the controller (100) performs normal operation (cooling operation) in which air outside the device is taken in and cooled, and the cooling air is supplied to the outside of the device. Is called. Specifically, the normal operation means (80) drives all of the three motors (13) to operate all of the three blower fans (12), and the circulation pump ( 51) is driven.

  When each motor (13) is driven by the normal operation means (80), all of the three blower fans (12) are driven to rotate, and the air in the casing (11) is supplied to the two blower fans (12). The air is sucked into the suction port (22), and outside air is taken into the casing (11) through the intake port (11c) formed on the back surface (11b). Thereby, an air flow is formed in the casing (11) from the rear to the front.

  Specifically, the air flowing into the interior from the intake port (11c) of the back surface (11b) of the casing (11) flows forward and flows between the plurality of fins (14a) of the heat exchanger (14). pass. At that time, the air is cooled by exchanging heat with the refrigerant flowing through the heat transfer tube (14b).

  As described above, the plurality of fins (14a) of the heat exchanger (14) are provided to be inclined with respect to the front-rear direction of the casing (11) so as to extend toward the blower fan (12). . Therefore, when the air passes between the plurality of fins (14a), the flow direction is changed by the fins (14a) and flows toward the blower fan (12). Moreover, the air which passed between each fin (14a) merges in the space formed between the heat exchanger (14) and the ventilation fan (12). Thereby, the pressure distribution of the air around the blower fan (12) is made uniform.

  Further, as described above, the heat exchanger (14) is formed from the upper part to the lower part in the casing (11) so as to correspond to the three blower fans (12) arranged in the vertical direction. Yes. During normal operation, all of the three blower fans (12) are rotationally driven by the normal operation means (80). Therefore, in the casing (11), the air flow is uniformly formed over the whole without being formed in a part in the vertical direction, and the air uniformly passes through the entire heat exchanger (14). To do.

  Air cooled by passing through the heat exchanger (14) (cooling air) reaches around the three blower fans (12) and is sucked from the two suction ports (22) of each blower fan (12). . Then, the cooling air sucked into each blower fan (12) is blown out from each blowout outlet (23) to the blowout space (24) and merges in the blowout space (24), and then the front surface of the casing (11) ( It is discharged to the outside from the air outlet (11d) formed in 11a).

  On the other hand, when the circulation pump (51) is driven by the normal operation means (80), the refrigerant circulates in the refrigerant circuit (50). In the refrigerant circuit (50), the refrigerant first undergoes heat exchange with the cooling water in the second heat exchanger (52) and changes in phase from gas to liquid. Specifically, the refrigerant that has flowed into the first flow path (52a) of the second heat exchanger (52) releases latent heat together with sensible heat into the cooling water flowing through the second flow path (52b) and condenses. . And the condensed refrigerant | coolant flows out out of a 2nd heat exchanger (52), and is pumped by the heat exchanger (14) side by the circulation pump (51).

  And the said refrigerant | coolant flows in into the heat exchanger tube (14b) of a heat exchanger (14), heat-exchanges with the air which passes between some fins (14a), and changes a phase from a liquid to gas. Specifically, the refrigerant that has flowed into the heat transfer tube (14b) evaporates by absorbing latent heat together with sensible heat from the air passing between the fins (14a) in the heat transfer tube (14b). Thereby, the air which passes between several fins (14a) is cooled by the refrigerant | coolant which distribute | circulates the inside of a heat exchanger tube (14b).

  Thus, when normal operation is started, when the air taken into the casing (11) passes through the heat exchanger (14), it exchanges heat with the refrigerant circulating in the refrigerant circuit (50). And is blown out of the casing (11). Thereby, the air around the air conditioner (10) (the space spreading forward) is cooled.

<Low air flow operation>
Further, in the air conditioner (10), when the cooling capacity of the air conditioner (10) is excessive (for example, the difference between the temperature of the air around the air conditioner (10) and the target temperature is less than a predetermined value. The air volume reducing means (81) of the controller (100) reduces the cooling air blowing volume (air volume) and performs the low air volume operation.

  Specifically, as shown in FIG. 7, first, the air volume reduction means (81) is arranged on the upper side and the lower side of the three blower fans (12) by the first operating number control unit (82). While the operated blower fan (12) is operated, control is performed to stop the operation of the blower fan (12) disposed in the middle. Thereby, the blowing amount (air volume) of cooling air is reduced.

  At this time, the middle blower fan (12) does not suck air. However, as described above, each space partitioned vertically by each mounting base (21) has an opening (21a) of each mounting base (21) and an opening (19) of each support base (18). It is communicated through. As a result, the upper and lower blower fans (12) are opened not only from the back surface (11b) side of the casing (11) but also from the opening (21a) of the mounting base (21) and the opening of the support base (18). Air can also be sucked in from the space provided with the middle blower fan (12) through the section (19). Therefore, even if the operation of the middle blower fan (12) is stopped, air is drawn into the space where the middle blower fan (12) is provided. As a result, in the casing (11), the air flow is not uniformly formed in a part in the vertical direction, but is uniformly formed throughout the heat exchanger (14). Can be distributed.

  Next, when the cooling capacity of the air conditioner (10) is further surplus, as shown in FIG. 8, the air volume reducing means (81) is supplied by the second operating number control unit (83) to the three blower fans. While controlling the ventilation fan (12) arrange | positioned in the middle of (12), control which stops the driving | operation of the ventilation fan (12) arrange | positioned at the upper side and the lower side is performed. Thereby, the blowing amount (air volume) of the cooling air is further reduced.

  At this time, the upper and lower blower fans (12) do not suck air. However, as described above, each space partitioned vertically by each mounting base (21) has an opening (21a) of each mounting base (21) and an opening (19) of each support base (18). It is communicated through. Thereby, the middle blower fan (12) is not only from the back surface (11b) side of the casing (11), but also the opening (21a) of the mounting base (21) and the opening (19) of the support base (18). ) Through the space where the upper and lower blower fans (12) are provided. Therefore, even if the operation of the upper and lower blower fans (12) is stopped, air is drawn into the space where the upper and lower blower fans (12) are provided. As a result, in the casing (11), the air flow is not uniformly formed in a part in the vertical direction, but is uniformly formed throughout the heat exchanger (14). Can be distributed.

-Effect of Embodiment 1-
As described above, according to the air conditioner (10), since the opening (21a) is formed in each mounting base (21), the space partitioned in the vertical direction by the mounting base (21) is communicated. . Therefore, each blower fan (12) sucks air not only from the back surface (11b) side of the casing (11) but also from the upper and lower spaces through the opening (21a) of the mounting base (21). Can do. Therefore, even when the operation of some of the blower fans (12) is stopped in order to reduce the amount of air blown out from the casing (11), the blower fan (12) in operation is stopped. By sucking air from the space provided with (12), the pressure in each space partitioned by the plurality of installation bases (21) can be made uniform, and the air can be made to uniformly flow into each space. Therefore, the air flow can be uniformly formed in the casing (11) in the vertical direction, and the air can be uniformly circulated throughout the heat exchanger (14). Therefore, the heat exchanger (14) can be used effectively when performing low airflow operation, and the cooling efficiency can be improved.

  Further, according to the air conditioner (10), when the operation of some of the blower fans (12) is stopped in order to perform the low air flow operation, the suction efficiency of the blower fans (12) during operation is improved. be able to.

  By the way, in this air conditioning apparatus (10), a double suction type sirocco fan is used as the blower fan (12). When a double-suction sirocco fan is used as the blower fan (12), the suction port (22) is arranged in the lateral direction so that the blower outlet (23) faces the front surface (11a) of the casing (11). Therefore, the blower fan (12) and the motor (13) must be arranged side by side in the width direction in the narrow casing (11), and the side of the blower fan (12) (around the inlet (22)) A large space cannot be secured. As a result, the suction efficiency of the blower fan (12) may be reduced.

  However, in the air conditioner (10), as described above, the upper space and the lower space partitioned by the mounting base (21) are formed by forming the opening (21a) in each mounting base (21). Are communicated with each other, the space around the suction port (22) of the blower fan (12) is substantially expanded. Thereby, the pressure loss of the air in both suction inlets (22) is reduced, and the amount of suction can be increased. Accordingly, even when a double suction sirocco fan is used as the blower fan (12), the blower efficiency of the blower fan (12) can be improved.

  In this air conditioner (10), the opening (21a) of each installation base (21) extends from below the blower fan (12) installed on the installation base (21) to below the motor (13). Largely formed. Thereby, air becomes easy to distribute | circulate between the upper space and lower space of a mounting base (21). Therefore, when performing low airflow operation, the heat exchanger (14) can be used more effectively by making the pressure in each space partitioned by the plurality of mounting bases (21) more uniform, thereby improving the cooling efficiency. Can do.

  In the air conditioner (10), each blower fan (12) is installed on the installation base (21) together with the motor (13) via the support base (18), and the installation base on the support base (18). The opening (19) corresponding to the opening (21a) of (21) was formed. Thus, the blower fan (12) and the motor (13) can be easily and once installed on the installation base (21) without closing the opening (21a) of the installation base (21).

  Further, in the air conditioner (10), the air volume reduction means (81) is arranged so that the blowing fan (12) during operation and the blowing fan (12) during operation are alternately arranged in the vertical direction. It is comprised so that the driving | operation of any one or two ventilation fans (12) among three ventilation fans (12) may be stopped. As a result, during the low airflow operation, the blowing fan (12) that is in operation and the blowing fan (12) that is not operating are arranged in the adjacent space, so the blowing fan (12) that is not operating is arranged. The air in the generated space is easily sucked by the blowing fan (12) during operation. Therefore, when the number of operating fans (12) is reduced and low airflow operation is performed, the pressure in each space partitioned by the mounting base (21) can be made more uniform, further improving the cooling efficiency. Can be planned.

<< Embodiment 2 of the Invention >>
The air conditioner (10) according to the second embodiment is obtained by changing the configuration of the air volume reducing means (81) of the controller (100).

  As shown in FIG. 9, the air volume reducing means (81) includes a first rotation speed control unit (84) and a second rotation speed control unit (85), and is one of the three blower fans (12). The blower air volume is configured to be reduced by reducing the rotational speed of the blower fan (12).

  Specifically, the first rotation speed control unit (84) rotates the upper and lower blowing fans (12) of the three blowing fans (12) at the rated speed, while the middle blowing fan ( 12) Reduce the rotation speed. On the other hand, the second rotational speed control unit (85) rotates the middle blower fan (12) of the three blower fans (12) at the rated speed, while the upper and lower blower fans (12). Reduce the rotation speed.

  That is, in Embodiment 2, the air volume reducing means (81) is configured so that the blower fan (12) rotating at the rated speed and the blower fan (12) rotating at a low speed are alternately arranged in the vertical direction. It is comprised so that the rotational speed of any one or two ventilation fans (12) of the base ventilation fans (12) may be reduced.

  Since the other configuration, the cooling operation in the rack (2) by the air conditioner (10) and the normal operation of the air conditioner (10) are the same as those in the first embodiment, the description thereof is omitted. Hereinafter, the control of the low air volume operation of the air conditioner (10) different from the first embodiment will be described.

<Low air flow operation>
Also in the second embodiment, when the air conditioning apparatus (10) has a sufficient cooling capacity, the air conditioning apparatus (10) is blown out by the air volume reducing means (81) of the controller (100). (Air volume) is reduced and low air volume operation is performed.

  Specifically, first, as shown in FIG. 9, the first rotational speed control unit (84) causes the blower fans (12) disposed on the upper side and the lower side of the three blower fans (12). While rotating at the rated speed, the first rotation speed control is performed to reduce the rotation speed of the blower fan (12) arranged in the middle. Thereby, the blowing amount (air volume) of cooling air is reduced.

  At this time, the suction amount of the middle blower fan (12) during low-speed rotation is reduced, but the upper and lower blower fans (12) operating at the rated speed are connected to the rear face (11b) of the casing (11). ) Not only from the side but also through the opening (21a) of the mounting base (21) through the space where the middle low-speed rotating fan (12) is provided. Air will be drawn in like way. Thereby, in the casing (11), the flow of air is uniformly formed over the entire vertical direction. Therefore, even if the rotational speed of the middle blower fan (12) is reduced, the air can be distributed uniformly throughout the heat exchanger (14).

  Next, when the cooling capacity of the air conditioner (10) is further surplus, as shown in FIG. 10, the second rotational speed control unit (85) causes the middle of the three blower fans (12) to enter the middle. While rotating the ventilation fan (12) arrange | positioned at a rated speed, 2nd rotational speed control which reduces the rotation speed of the ventilation fan (12) arrange | positioned at the upper side and the lower side is performed. Thereby, the blowing amount (air volume) of the cooling air is further reduced.

  At this time, the suction amount of the upper and lower blower fans (12) during low-speed rotation is reduced, but the middle blower fan (12) operating at the rated speed is connected to the rear face (11b) of the casing (11). ) Not only from the side but also through the opening (21a) of the mounting base (21), by sucking air from the space provided with the upper and lower blowing fans (12) during low-speed rotation, Air is uniformly drawn into the. Thereby, in the casing (11), the flow of air is uniformly formed over the entire vertical direction. Therefore, even if the rotational speeds of the upper and lower blower fans (12) are reduced, the air can be distributed uniformly throughout the heat exchanger (14).

  As described above, in the second embodiment, the air volume reducing means (81) is arranged so that the blowing fan (12) rotating at the rated speed and the blowing fan (12) rotating at a low speed are alternately arranged in the vertical direction. It is comprised so that the rotational speed of any one or two ventilation fans (12) of three ventilation fans (12) may be reduced. As a result, during the low airflow operation, the blower fan (12) rotating at the rated speed and the blower fan (12) rotating at the low speed are arranged in the adjacent space. ) Is easily sucked by the blowing fan (12) rotating at the rated speed. Therefore, when performing low airflow operation by reducing the rotational speed of the blower fan (12), the pressure in each space partitioned by the mounting base (21) can be made more uniform, further improving the cooling efficiency. Can be planned.

<< Other Embodiments >>
In each said embodiment, the ventilation fan (12) and the motor (13) were installed in the installation base (21) integrally via the support stand (18) in which the opening part (19) was formed. However, the air conditioning apparatus according to the present invention may not include the support base (18).

  Further, the refrigerant circuit (50) is not limited to those in each of the above embodiments, and any form can be used as long as it can cool the air flowing through the heat exchanger (14) using the phase change of the refrigerant. Good.

  In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

  As described above, the present invention is useful for an air conditioner for cooling a space in which a plurality of racks on which electronic devices such as servers are mounted are arranged.

FIG. 1 is a schematic plan view of a server room in which the air conditioner of Embodiment 1 is installed. FIG. 2 is a schematic plan view of the air conditioning apparatus according to the first embodiment. FIG. 3 is a cross-sectional view taken along the line AA of FIG. FIG. 4 is a perspective view of the fan unit according to the first embodiment as viewed from below. FIG. 5 is a perspective view of the mounting base of Embodiment 1 as viewed from above. FIG. 6 is a refrigerant circuit diagram to which the heat exchanger of the air conditioner of Embodiment 1 is connected. FIG. 7 is a diagram illustrating an air flow during the first operation number control of the air-conditioning apparatus according to the first embodiment. FIG. 8 is a diagram illustrating an air flow during the second operation number control of the air-conditioning apparatus according to the first embodiment. FIG. 9 is a diagram illustrating the air flow during the first rotation speed control of the air-conditioning apparatus according to the second embodiment. FIG. 10 is a diagram illustrating an air flow during the first rotation speed control of the air-conditioning apparatus according to the second embodiment.

Explanation of symbols

2 racks
3 rack rows
10 Air conditioner
11 Casing
11a front
11b back
11c Intake
11d outlet
12 Blower fan
13 Motor
14 Heat exchanger
18 Support stand
19 opening
21 Installation table
21a opening
22 Suction port
80 Normal operation means
81 Air volume reduction means
82 First operation number controller
83 Second operation number controller
84 1st rotation speed control part
85 Second rotation speed controller

Claims (6)

A casing (11) having an air inlet (11c) formed on the back surface (11b) and an air outlet (11d) formed on the front surface (11a) is provided, and the casing (11) includes the casing. (11) A plurality of blower fans (12) for circulating air from the intake port (11c) toward the blowout port (11d), and the blower fan provided on the upstream side of the blower fan (12) An air conditioner in which a heat exchanger (14) for cooling air circulating in the casing (11) is disposed by (12),
In the casing (11), a plurality of mounting bases (21) on which the plurality of blower fans (12) are respectively installed are arranged at predetermined intervals in the vertical direction,
Each of the mounting bases (21) is formed with an opening (21a) that connects the upper space and the lower space partitioned by the mounting base (21). In claim 1,
Each blower fan (12) is constituted by a double-suction sirocco fan having suction ports (22) formed on both end surfaces in the axial direction, and the blower port (23) is connected to the front surface of the casing (11) ( 11a)
An air conditioner, wherein a motor (13) for rotating the blower fan (12) is disposed on a side of each of the blower fans (12). In claim 2,
The air conditioner characterized in that the opening (21a) of each mounting base (21) is formed from below the blower fan (12) to below the motor (13). In claim 2 or 3,
Each of the blower fans (12) is installed on the mounting base (21) together with the motor (13) via a support base (18),
The air conditioner characterized in that an opening (19) is formed in the support base (18) at a position corresponding to the opening (21a) of the mounting base (21). In any one of Claims 1 thru | or 4,
There are three fan fans (12),
An air volume reducing means (81) for reducing the air volume of air blown out of the casing (11),
The air volume reducing means (81)
First operation number control for operating the blower fan (12) disposed on the upper side and the lower side of the three blower fans (12) while stopping the operation of the blower fan (12) disposed in the middle. Part (82),
Second operation number control for operating the blower fan (12) disposed in the middle of the three blower fans (12) while stopping the blower fan (12) disposed on the upper side and the lower side. And an air conditioner (83). In any one of Claims 1 thru | or 4,
There are three fan fans (12),
An air volume reducing means (81) for reducing the air volume of air blown out of the casing (11),
The air volume reducing means (81)
The first fan that rotates the blower fan (12) disposed above and below the three blower fans (12) at the rated speed while reducing the rotational speed of the blower fan (12) disposed in the middle. 1 rotation speed control unit (84),
The first fan that rotates the blower fan (12) arranged in the middle of the three blower fans (12) at the rated speed while reducing the rotation speed of the blower fans (12) arranged on the upper side and the lower side. An air conditioner comprising a two-rotation speed control unit (85).

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