JP2015148382A - Air conditioning system, and combination type air conditioning system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air conditioning system which can collect and arrange cooling space on one side of cooling object space and ventilation space even when performing air conditioning of the cooling object space of a heavy load, which improves work efficiency of maintenance inspection by an operator and which can elongate life of various apparatuses accommodated in the cooling space.SOLUTION: In an air conditioning system 1, in a cooling object chamber 2 including information processing apparatus, a ventilation chamber 3 arranged adjacent to the cooling object chamber 2 and a cooling chamber 4 for mutually communicating the cooling object chamber 2 and the ventilation chamber 3, an airflow circulating into the cooling chamber 4 from the cooling chamber 4 via the ventilation chamber 3 and the cooling object chamber 2 in this order is formed and cooling of the information processing apparatus is performed. The air conditioning system 1 includes: a blower fan 20 arranged in the cooling chamber 4 and forming an airflow; a cooling coil 10a for performing cooling of the air from the cooling object chamber 2 to the cooling chamber 4; and a cooling coil 10b for performing cooling of the air from the cooling chamber 4 to the ventilation chamber 3.

Description

  The present invention relates to an air conditioning system and a combined air conditioning system.

  2. Description of the Related Art Conventionally, an air conditioning system that cools information processing equipment in an information processing equipment room in which racks that contain information processing equipment are arranged has been proposed (for example, Patent Document 1). 4A and 4B are diagrams schematically illustrating an air conditioning system 100 according to the related art, in which FIG. 4A is a side view and FIG. 4B is a plan view. As described above, the conventional air conditioning system 100 has the maintenance floor 102 disposed below the information processing equipment room 101, the duct areas 103 are disposed on both sides of the information processing equipment room 101 and the maintenance floor 102, and one duct area is arranged. A UPS room 104 that houses an uninterruptible power supply (hereinafter referred to as UPS (Uninterruptible Power Systems)) is arranged outside 103. An air conditioner 110 that is integrally provided with cooling coils 120 a and 120 b and a blower fan 130 is installed at a position between the duct area 103 and the maintenance floor 102 on both sides. Here, in such a configuration, the air cooled by the air conditioner 110 is circulated to the maintenance floor 102 again sequentially through the maintenance floor 102, the information processing equipment room 101, and the duct area 103, so that the rack 105 The information processing equipment housed inside was cooled.

JP 2011-220877 A

  Here, in the above prior art, the duct areas 103 are arranged on both sides of the information processing equipment room 101 and the maintenance floor 102. Therefore, wiring for supplying power to the blower fan 130 and refrigerant supply means for supplying refrigerant to the cooling coils 120a and 120b (for example, the refrigerant supply pipe 140 for supplying cooling water as the refrigerant) are provided on both sides of the maintenance floor 102. Need to be distributed. In this case, since the lengths of these wirings and the refrigerant supply means are increased, the air conditioning system 100 may become complicated and the installation cost may increase. Further, when the duct areas 103 are arranged on both sides of the maintenance floor 102 as described above, the duct area 103 is interposed between the information processing equipment room 101 and the UPS room 104. In this case, since the wiring connecting the UPS and the information processing device passes through the duct area 103, the flow line of the electrical equipment manager and the flow line of the air conditioning equipment manager interfere with each other in the duct area 103. This is not preferable from the viewpoint of maintenance and inspection by each manager.

  Further, in the above-described conventional technology, it is necessary for an operator to access from the duct area 103 or the maintenance floor 102 in order to access the air conditioner 110 for maintenance and inspection of the air conditioner 110. However, the duct area 103 is a high-temperature (for example, 30 ° C.) space into which air including heat from the information processing device flows, and the maintenance floor 102 is a low-temperature (for example, 18 ° C.) into which air after cooling by the air conditioner 110 flows. Because they are spaces, neither of them was a space with excellent workability for workers.

  Further, in the above-described prior art, the duct area 103 is a high-temperature space as described above. Therefore, the failure rate of various devices arranged in the duct area 103 is greatly increased due to heat. Life could be shortened.

  In view of the problems associated with arranging the duct areas 103 on both sides of the information processing equipment room 101 (and the maintenance floor 102) as described above, the duct areas 103 are integrated on one side of the information processing equipment room 101. It is also possible to arrange and configure them. FIG. 5 is a plan view schematically showing an air conditioning system 200 in which a duct area 103 is arranged on one side of the information processing equipment room 101. Here, in such an information processing equipment room 101, in addition to the air conditioner 110 for processing heat generated from the information processing equipment, a spare air conditioner 110 is necessary, and the information processing equipment room 101 with a high load is required. Especially when air conditioning is performed, the installation space of the air conditioner 110 is excessive. Therefore, when it is attempted to arrange the necessary air conditioners 110 in the duct area 103 on one side in parallel, there is a possibility that not all of the air conditioners 110 will fit within the width of the duct area 103 as shown in FIG. In view of the above, there has been a demand for an air conditioning system that can arrange and arrange a duct area on one side of an information processing equipment room and a maintenance floor even when air conditioning a high load information processing equipment room.

  The present invention has been made in view of the above, and in the case of air conditioning a high load cooling target space (corresponding to the information processing equipment room 101 according to the prior art), the cooling space (the duct according to the prior art) An air conditioning system capable of concentrating and arranging the cooling target space (corresponding to the area 103) on one side of the cooling target space (corresponding to the information processing equipment room 101 according to the prior art) and the ventilation space (corresponding to the maintenance floor 102 according to the prior art) An air conditioning system capable of improving the work efficiency of maintenance and inspection by workers and extending the life of various devices housed in a cooling space (corresponding to the duct area 103 according to the prior art) is provided. For the purpose.

  In order to solve the above-described problems and achieve the object, the air conditioning system according to claim 1 is adjacent to a cooling target space including a device to be cooled along a predetermined direction with respect to the cooling target space. And the cooling space that is arranged so as to allow the space to be cooled and the ventilation space to communicate with each other and that cools the air. An air conditioning system that cools the equipment by forming a flow of air that circulates to the cooling space sequentially through the space and the space to be cooled, and is disposed in the cooling space to reduce the flow of air. A first cooling means arranged at a position between the air blowing means to be formed and the cooling target space and the cooling space, and cools the air from the cooling target space to the cooling space; A second cooling means disposed at a position between the cooling space and the ventilation space, the second cooling means for cooling the air from the cooling space to the ventilation space; Is provided.

  An air conditioning system according to a second aspect is the air conditioning system according to the first aspect, wherein the first cooling means and the second cooling means are arranged at positions that overlap in the predetermined direction.

  The air conditioning system according to claim 3 is the air conditioning system according to claim 1 or 2, wherein a refrigerant for cooling the air is supplied to the second cooling means, and the second cooling means Refrigerant supply means for supplying the heat-exchanged and heated refrigerant to the first cooling means is provided.

  The air conditioning system according to claim 4 is the air conditioning system according to any one of claims 1 to 3, wherein the cooling space includes the first side surface that configures the cooling target space and the ventilation space. A device power supply space, which is a second side surface and is arranged so that the first side surface and the second side surface disposed flush with each other are in communication with each other and supplies power to the device, It arrange | positioned in the position facing the said cooling space on both sides of the space and the said ventilation space.

  The air conditioning system according to a fifth aspect is the air conditioning system according to any one of the first to fourth aspects, wherein the air blowing control means for controlling the air blowing means is arranged in the cooling space.

  An air conditioning system according to a sixth aspect is the air conditioning system according to any one of the first to fifth aspects, further comprising outside air introducing means for introducing outside air into the cooling space.

  An air conditioning system according to a seventh aspect includes a plurality of modules arranged in parallel with the air conditioning system according to any one of the first to sixth aspects as a single module.

  According to the air conditioning system of the first aspect, since the air conditioner is separated into the air blowing means, the first cooling means, and the second cooling means, restrictions on the installation space can be relaxed, and the high load cooling target space Even when air conditioning is performed, the cooling space can be concentrated and arranged on one side of the cooling target space and the ventilation space, and the first cooling means is disposed at a position between the cooling target space and the cooling space, By cooling the air from the space to be cooled to the cooling space by the first cooling means, the air containing the heat from the device arranged in the space to be cooled is cooled to the cooling space by the first cooling means. It is possible to improve the work efficiency of maintenance inspections and the like in the cooling space by workers, and to extend the life of various devices accommodated in the cooling space. Furthermore, since the blowing means and each cooling means are configured separately, it is possible to improve the degree of freedom of setting the respective equipment capacities as compared with the case where the blowing means and each cooling means are accommodated in the same housing. Become.

  According to the air conditioning system of the second aspect, since the first cooling means and the second cooling means are arranged at positions overlapping each other in the predetermined direction, the first cooling means and the second cooling in the cross section orthogonal to the predetermined direction. It is possible to reduce the cooling space by reducing the arrangement space of the means, and it is possible to configure a wider space to be cooled and install more devices in the space to be cooled.

  According to the air conditioning system of the third aspect, since the refrigerant heated by heat exchange with the air in the second cooling unit is diverted in the first cooling unit, the flow rate of the refrigerant is reduced as a whole. Therefore, it is possible to reduce the transport power and improve the energy saving performance.

  According to the air conditioning system of the fourth aspect, since the device power supply space is arranged at a position facing the cooling space with the cooling target space and the ventilation space interposed therebetween, the wiring of the air conditioning equipment and the wiring of the electrical equipment are cooled. It is not mixed in the space, and the flow line of the air conditioner manager and the flow line of the electrical equipment manager do not interfere with each other, further improving the work efficiency of maintenance and inspection by each manager Can be achieved.

  According to the air conditioning system of the fifth aspect, since the air blowing control means is arranged in the cooling space, it is possible to collect the flow line of the manager of the air conditioning equipment in the cooling space and improve the work efficiency of the maintenance inspection. Is possible. Further, the air blowing control means can be arranged in the space into which the air cooled by the first cooling means flows, and it is possible to extend the life of the air blowing control means and further improve the work efficiency of maintenance and inspection. Further, the air blowing control means can be arranged in the vicinity of the air blowing means, and it is possible to further improve the work efficiency of the maintenance inspection.

  According to the air conditioning system of claim 6, since the outside air is introduced into the cooling space by the outside air introduction means, the cooling load of the first cooling means and the second cooling means can be reduced, and the energy saving performance is improved. Is possible.

  According to the air conditioning system of claim 7, since the composite air conditioning system is configured by arranging a plurality of modules in parallel, the composite air conditioning system suitable for the number of devices to be cooled, the amount of heat generation, and the like Can be configured.

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows schematically the air conditioning system which concerns on embodiment of this invention, Comprising: Fig.1 (a) is a side view, FIG.1 (b) is a top view. It is a principal part enlarged view of Fig.1 (a). It is a top view which shows the composite type air conditioning system which concerns on a modification. It is a figure which shows schematically the air conditioning system which concerns on a prior art, Comprising: Fig.4 (a) is a side view, FIG.4 (b) is a top view. It is a top view which shows roughly the air-conditioning system which has arrange | positioned the duct area in the one side of information processing equipment room.

  Hereinafter, an embodiment of an air-conditioning system according to the present invention will be described in detail with reference to the drawings. However, the present invention is not limited by this embodiment.

[Basic concept of the embodiment]
First, the basic concept of this embodiment will be described. The present embodiment generally relates to an air conditioning system that cools equipment arranged in a space to be cooled. Here, “device” is a concept including various electric devices such as OA (Office Automation) devices and home appliances, but in the present embodiment, the description will be made assuming that the information processing device is a known computer. . In addition, although the use of the information processing device is arbitrary, the present embodiment will be described as being used as a device for processing various data in a large-scale information processing facility such as a data center. In addition, the number of devices installed in the information processing facility is arbitrary, and it is possible to configure the air conditioning system by providing at least one device. In this embodiment, a plurality of information processing devices are installed. Explain that it is.

[Specific contents of the embodiment]
Next, specific contents of the present embodiment will be described.

(Constitution)
Initially, the structure of the air conditioning system 1 which concerns on this Embodiment is demonstrated. FIG. 1 is a diagram schematically showing an air conditioning system 1 according to the present embodiment, in which FIG. 1 (a) is a side view and FIG. 1 (b) is a plan view. FIG. 2 is an enlarged view of a main part of FIG. As shown in FIGS. 1 and 2, the air conditioning system 1 includes cooling coils 10 a and 10 b, a blower fan 20, an air conditioning power panel 30, an outside air introduction fan 40, a heat exchanger 50, a refrigerator 60, and a cushion tank 70. It is prepared for. In the following description, the X direction shown in FIGS. 1 and 2 is referred to as “depth direction”, the Y direction as “width direction”, and the Z direction as “height direction” as necessary. Moreover, in FIG.1 and FIG.2, the flow of air is shown by the arrow.

(Configuration-Information processing facility)
Here, first, an information processing facility in which the air conditioning system 1 is provided will be described. 1 and 2 show only a part of the information processing facility. As shown in FIGS. 1 and 2, the information processing facility includes a cooling target chamber 2, a ventilation chamber 3, and a cooling chamber 4. , UPS room 5, machine room 6, and seismic isolation layer 7 are provided. Note that these rooms are partitioned by floor materials, inner walls, and the like, but the configuration of each room is well known, and detailed description thereof is omitted. In FIG. 1, the UPS room 5, the machine room 6, and the seismic isolation layer 7 are omitted.

  The cooling target chamber 2 is a cooling target space in which a plurality of racks 8 that accommodate information processing devices are arranged. The specific shape of the rack 8 is arbitrary, but in the present embodiment, the rack 8 has a housing formed as a hollow rectangular parallelepiped shape, and a plurality of information processing devices are accommodated inside the housing. The description will be made assuming that the rack 8 is used. Here, each rack 8 is devised for cooling the information processing equipment accommodated therein. Specifically, first, mesh-like ventilation holes are provided on one side surface of the housing of the rack 8 and the other side surface provided at a position facing the one side surface. A cooling fan for blowing air is provided at any position inside the rack 8. By operating the cooling fan in the rack 8 configured as described above, the air in the space outside the rack 8 (hereinafter referred to as the first space) is changed to a ventilation hole provided on one side of the rack 8 housing, the rack The air is blown into the space on the opposite side (hereinafter referred to as the second space) outside the rack 8 through the inside of 8 and the ventilation holes provided on the other side surface of the rack 8 in order. Here, in the following description, one side of the above-described rack 8 housing is referred to as “suction surface” and the other side is referred to as “blowing surface” as necessary.

  A plurality of racks 8 in the room are arranged in parallel along a specific direction (the depth direction in the present embodiment) to form a row of racks 8 (hereinafter referred to as a rack row). Each rack 8 constituting the rack row is arranged such that the direction of the suction surface and the direction of the blowing surface are aligned. In addition, a plurality of such rack rows (four rows in the present embodiment) are arranged in parallel along a direction (in the present embodiment, the width direction) orthogonal to the specific direction. The plurality of rack rows are arranged so that the respective suction surfaces and the blow-out surfaces face each other, and the space thus provided on the suction surface side of the rack rows is referred to as “cold aisle”. The space provided on the blowing surface side of the row is referred to as “hot aisle” and will be described below. Further, a capping material may be provided from the upper end of each rack row to the ceiling material 2b of the cooling target chamber 2, and the air of the cold aisle flows into the hot aisle without passing through the inside of the rack 8 by this capping material. And the cooling efficiency of the information processing device can be improved.

  Here, a connection hole (not shown) for connecting the cold aisle and the ventilation chamber 3 is formed in the floor material of the chamber 2 to be cooled, and the air in the ventilation chamber 3 is passed through the connection hole to the cold aisle. It is configured to be flowable. Further, as shown in FIG. 2, the cooling target chamber 2 has a ceiling material 2b below the ceiling slab 2a, and a space between the ceiling slab 2a and the ceiling material 2b is used as a ceiling chamber 2c. It is formed with a heavy ceiling structure. In addition, about a concrete means for forming such a double ceiling structure, since a well-known means can be used, it abbreviate | omits.

  The ventilation chamber 3 is a ventilation space arranged so as to be adjacent to the cooling target chamber 2 along a predetermined direction (the height direction in the present embodiment), and is cooled in the cooling chamber 4. This is a space for allowing air to flow to the cooling target chamber 2 through the ventilation chamber 3. For example, the ventilation chamber 3 may be used as a space for performing maintenance and inspection of the information processing device disposed in the cooling target chamber 2.

  The cooling chamber 4 is a cooling space that cools the air by the cooling coils 10a and 10b, and is disposed so that the cooling target chamber 2 and the ventilation chamber 3 communicate with each other. The cooling chamber 4 is divided into an upper layer and a lower layer by a flooring 4a formed near the center in the height direction. The flooring 4a has a plurality of through holes (not shown) penetrating in the vertical direction (six in this embodiment), and a blower fan 20 is fitted in each through hole. In the embedded state, it is fixed by a known method such as screwing. A plurality (three in the present embodiment) of openings 11a are provided along the width direction on the inner wall that partitions the ceiling chamber 2c of the cooling target chamber 2 and the upper layer of the cooling chamber 4, The opening 11a is fixed by a known method such as screwing in a state where the cooling coil 10a is fitted. In such a configuration, the air flowing from the cooling target chamber 2 to the cooling chamber 4 is cooled by the cooling coil 10a. In addition, the inner wall that partitions the lower layer of the cooling chamber 4 and the ventilation chamber 3 is provided with a plurality of (three in this embodiment) openings 11b along the width direction. In a state where the cooling coil 10b is fitted, it is fixed by a known method such as screwing. In such a configuration, the air flowing from the cooling chamber 4 to the ventilation chamber 3 is cooled by the cooling coil 10b.

  The UPS chamber 5 is a device power supply space in which a UPS (not shown) that supplies power to each information processing device arranged in the cooling target chamber 2 via wiring is arranged. In addition, how to arrange | position wiring is arbitrary, For example, you may connect with respect to the information processing apparatus of the chamber 2 to be cooled through the ventilation chamber 3 from UPS. Here, in the prior art shown in FIG. 4, since the duct area 103 is arranged between the UPS room 104 and the information processing equipment room 101, the UPS in the UPS room 104 and the information in the information processing equipment room 101 are displayed. The wiring connecting the processing equipment needs to be arranged through the duct area 103. Therefore, the flow line of the manager of the air conditioner 110 (ie, the manager of the air conditioning equipment) and the flow line of the UPS manager (ie, the manager of the electrical equipment) are mixed in the duct area 103, and The work efficiency of maintenance and inspection by the administrator is reduced. On the other hand, as in the present embodiment shown in FIG. 1, the UPS chamber 5 is disposed at a position facing the cooling space with the cooling target chamber 2 and the ventilation chamber 3 interposed therebetween, and the UPS chamber 5 and the cooling target chamber 2 are separated from each other. By configuring so as to be adjacent to each other, the wiring that connects the UPS of the UPS room 5 and the information processing device of the cooling target room 2 can be arranged without passing through the cooling room 4. Therefore, the flow lines of the managers of the cooling coils 10a and 10b and the blower fan 20 (that is, the manager of the air conditioning equipment) and the flow lines of the UPS manager (that is, the manager of the electrical equipment) are in the cooling chamber 4. It is possible to improve the work efficiency of maintenance inspection by each manager without mixing them.

  The machine room 6 is a well-known machine room in which, for example, a boiler or the like is installed. Although the specific position of this machine room 6 is arbitrary, in this Embodiment, it demonstrates as what is arrange | positioned at the lowest floor of an information processing facility.

  The seismic isolation layer 7 is a space in which known seismic isolation devices such as isolators and dampers are arranged, and is a space formed between the building and the foundation of the information processing facility. In the present embodiment, the seismic isolation layer 7 is directly connected to the space outside the building, and the air in the space outside the building will be described as being taken into the seismic isolation layer 7. Moreover, since the formation method of this seismic isolation layer 7 is well-known, the detailed description is abbreviate | omitted.

(Configuration-air conditioning system)
Then, each component which comprises the air conditioning system 1 is demonstrated.

(Configuration-Air conditioning system-Cooling coil)
The cooling coils 10a and 10b are cooling means for cooling the air, and the cooling coils 10a and 10b are similarly configured except for the positions where they are installed. The cooling coil 10 a is a first cooling unit that cools the air from the cooling target chamber 2 to the cooling chamber 4, and is disposed at a position between the cooling target chamber 2 and the cooling chamber 4. Here, “the position between the cooling target chamber 2 and the cooling chamber 4” is specifically a position where the air cooled by the cooling coil 10 a can be blown to the cooling chamber 4. Any position is acceptable as long as it is present. For example, in the present embodiment, the cooling coil 10a is fitted into an opening 11a formed in an inner wall provided between the upper layer of the cooling chamber 4 and the ceiling chamber 2c of the cooling target chamber 2. Will be described as being fixed by a known method such as screwing. The number of cooling coils 10a installed may vary depending on the size of the cooling target chamber 2 and the amount of heat generated by the information processing device, but in the present embodiment, three are arranged in parallel along the width direction. It will be explained as a thing.

  The cooling coil 10 b is a second cooling means for cooling the air from the cooling chamber 4 to the ventilation chamber 3, and is disposed at a position between the cooling chamber 4 and the ventilation chamber 3. Here, the “position between the cooling chamber 4 and the ventilation chamber 3” is specifically a position where the air cooled by the cooling coil 10 b can be blown to the ventilation chamber 3. Any position is acceptable. For example, in this embodiment, the cooling coil 10b is screwed in a state in which the cooling coil 10b is fitted in an opening 11b formed in an inner wall provided between the lower layer of the cooling chamber 4 and the ventilation chamber 3. It is assumed that it is fixed by this method. The number of cooling coils 10b installed may vary depending on the size of the cooling target chamber 2 and the amount of heat generated by the information processing device, but in the present embodiment, three are arranged in parallel along the width direction. It will be explained as a thing. Moreover, the cooling coil 10a and the cooling coil 10b are arrange | positioned in the position which overlaps in a height direction, and, thereby, arrangement | positioning of the cooling coil 10a and the cooling coil 10b in the cross section (namely, horizontal cross section) orthogonal to a height direction. The cooling space can be reduced by reducing the space.

  Here, the specific configuration of the cooling coils 10a and 10b is arbitrary, but in the present embodiment, a known refrigerant coil that cools air using the refrigerant supplied through the refrigerant supply pipe 12 is used. It is assumed that The refrigerant supply pipe 12 is a refrigerant supply means for supplying the refrigerant to the cooling coils 10a and 10b, and is configured as a hollow annular body made of metal, resin, or the like. In addition, although the specific kind of refrigerant | coolant is arbitrary and can also use a vapor | steam and gas, for example, in this Embodiment, a refrigerant | coolant is demonstrated as what is cooling water. The refrigerant supply pipe 12 is configured to circulate the refrigerant to the heat exchanger 50 through the heat exchanger 50, the cooling tower 13b, the refrigerator 60, the cushion tank 70, the cooling coil 10b, and the cooling coil 10a in this order. The cold energy is collected and used in each of the devices connected in this way. The specific function of the refrigerant supply pipe 12 will be described later.

  Here, in the prior art shown in FIG. 4, in order to disperse and arrange the air conditioners 110 in the duct areas 103 located on both sides of the maintenance floor 102, refrigerant is supplied to the cooling coils 120a and 120b of each air conditioner 110. In order to do this, it is necessary to extend the refrigerant supply pipe 140 to both sides of the maintenance floor 102. On the other hand, in the present embodiment shown in FIG. 1, the cooling coils are collectively arranged in the cooling chamber 4 located on one side of the ventilation chamber 3, so that the refrigerant supply pipes 12 are extended in one place. Therefore, the length of the refrigerant supply pipe 12 can be made shorter than that of the prior art.

(Configuration-Air conditioning system-Blower fan)
The blower fan 20 is a blower unit that forms a flow of air, and the number of the blower fans 20 is arbitrary. In the present embodiment, a total of six blower fans 20 are juxtaposed along the width direction. Explain that it is. In the following description, it is assumed that one of these is used as a spare blower fan 20 and is used when another blower fan 20 fails. Here, although the specific installation method of each blower fan 20 is arbitrary, for example, in the flooring 4a of the cooling chamber 4, a through-hole that vertically penetrates the flooring 4a extends along the width direction. A plurality (6 in the present embodiment) corresponding to the number of the blower fans 20 are provided, and the blower fan 20 has the suction surface facing upward and the blowout surface downward with respect to each of these through holes. In the state of being fitted so as to face, it is assumed that it is fixed by a known method such as screwing. In the blower fans 20 thus formed, each blower fan 20 sucks the air in the upper layer of the cooling chamber 4 and blows it out toward the lower layer to form an air flow.

(Configuration-Air conditioning system-Air conditioning power panel)
The air conditioning power panel 30 is a blowing control unit that is connected to each blowing fan 20 via wiring and controls each blowing fan 20. The installation position of the air conditioning power panel 30 is arbitrary. For example, it can be installed in the upper layer of the ventilation chamber 3 or the cooling chamber 4, but in this embodiment, it is arranged in the lower layer of the cooling chamber 4. Explain that it is. Thus, by arranging the air conditioning power panel 30 at a position in the vicinity of the blower fan 20, the length of the wiring connecting the blower fan 20 and the air conditioning power panel 30 can be reduced, and more space-saving air conditioning can be achieved. The system 1 can be configured. In addition, since the specific structure of this air-conditioning power panel 30 is well-known, the detailed description is abbreviate | omitted.

(Configuration-Air conditioning system-Outside air introduction fan)
The outside air introduction fan 40 is outside air introduction means for introducing outside air into the cooling chamber 4. The outside air introduction fan 40 is configured as a well-known fan disposed in the vicinity of an outside air port that connects the room and the outside of the information processing facility, and the temperature of the outside air can be used for cooling the room 2 to be cooled. By operating in such a case (for example, in winter), it is possible to reduce the processing load on the refrigerator 60 and the cooling coils 10a and 10b by taking outside air into the cooling chamber 4. In order to reduce the processing load of the refrigerator 60 and the cooling coil, the temperature of the outside air taken in by the outside air introduction fan 40 is preferably as low as possible. However, in this embodiment, the temperature of the cooling chamber 4 (in this embodiment) Is assumed to be the same temperature as 24 ° C.).

(Configuration-Air conditioning system-Heat exchanger)
The heat exchanger 50 is a heat exchange means for cooling the refrigerant flowing in the refrigerant supply pipe 12, and specifically, the inside of the pipe 14 connecting the cooling tower 13 a and the heat exchanger 50. The heat exchanger is configured as a known heat exchanger that exchanges heat between the flowing cooling water and the refrigerant flowing in the refrigerant supply pipe 12. Here, the cooling tower 13a is a known cooling tower that cools the cooling water inside the pipe 14 by bringing the cooling water inside the pipe 14 into direct or indirect contact with the atmosphere to exchange heat. In addition, since the concrete structure of these refrigerant | coolant supply pipe | tubes 12 and the cooling tower 13a is well-known, the detailed description is abbreviate | omitted.

(Configuration-Air conditioning system-Refrigerator)
The refrigerator 60 is a refrigeration means for cooling the refrigerant flowing in the refrigerant supply pipe 12, and is configured as a known vapor compression refrigerator, an absorption refrigerator, an adsorption refrigerator, or the like. . A cooling tower 13b is connected to the refrigerant supply pipe 12 on the inlet side of the refrigerator 60. The cooling tower 13b is configured in the same manner as the cooling tower 13a, and the cooling water in the pipe 14 is cooled by the cooling tower 13b and then supplied to the refrigerator 60, thereby reducing the processing load of the refrigerator 60. Things are possible.

(Configuration-Air conditioning system-Cushion tank)
The cushion tank 70 is water storage means for temporarily storing the refrigerant cooled by the refrigerator 60. Note that the refrigerant stored in the cushion tank 70 is appropriately supplied to the cooling coils 10a and 10b according to the cooling load of the cooling coils 10a and 10b. In addition, since the specific structure of this cushion tank 70 is well-known, the detailed description is abbreviate | omitted.

(Air conditioning treatment)
Next, an air conditioning process executed by the air conditioning system 1 configured as described above will be described.

  First, a process for circulating the refrigerant inside the refrigerant supply pipe 12 and a process for circulating the cooling water inside the pipe 14 will be described. First, by operating a pump (not shown) provided in the path of the refrigerant supply pipe 12, the heat exchanger 50, the cooling tower 13b, the refrigerator 60, the cushion tank 70, the cooling coil 10b, and the cooling coil 10a are moved. The refrigerant is circulated in the refrigerant supply pipe 12 so that the refrigerant reaches the heat exchanger 50 again sequentially. Similarly, by operating a pump (not shown) provided in the pipe 14, the cooling water reaches the heat exchanger 50 again from the heat exchanger 50 through the cooling tower 13 a. Circulate cooling water inside.

  Here, the cooling water circulating inside the pipe 14 is cooled by exchanging heat with the atmosphere in the cooling tower 13 a, supplied to the heat exchanger 50 by the action of the pump, and supplied with refrigerant by the heat exchanger 50. The refrigerant is cooled by heat exchange with a refrigerant flowing in the pipe 12 (hereinafter simply referred to as “refrigerant”). The refrigerant thus cooled in the heat exchanger 50 flows to the cooling tower 13b, and is further cooled by exchanging heat with the atmosphere in the cooling tower 13b. In this way, by cooling the refrigerant by directly or indirectly exchanging heat with the atmosphere, it is possible to improve the energy saving performance while suppressing the consumption of power required for cooling the refrigerant.

  Next, the refrigerant flows through the inside of the refrigerant supply pipe 12 and is taken into the refrigerator 60, and is further cooled by the refrigerator 60. In the case where the refrigerant can be cooled to a necessary temperature only by the heat exchanger 50 and the cooling tower 13b without cooling by the refrigerator 60, the refrigerator 60 does not have to be operated. good. The refrigerant thus cooled by the refrigerator 60 is taken into the cushion tank 70 and stored.

  Here, a valve (not shown) for adjusting the flow rate of the refrigerant is provided on the flow path between the cushion tank 70 and the cooling coil 10b in the refrigerant supply pipe 12, and by operating the valve, The refrigerant stored in the cushion tank 70 is appropriately taken into the cooling coil 10b. The operation of the valve may be performed manually by the user, or may be automatically controlled based on the temperature of the refrigerant measured by a predetermined measuring means (not shown), the temperature of each room, or the like.

  Then, the refrigerant taken into the cooling coil 10b from the cushion tank 70 cools the air from the cooling chamber 4 to the ventilation chamber 3 by being used for heat exchange with air in the cooling coil 10b. In this way, the temperature of the refrigerant rises by being used in the cooling coil 10b, and then the refrigerant is taken into the cooling coil 10a via the refrigerant supply pipe 12. The refrigerant thus introduced from the cooling coil 10b to the cooling coil 10a is used for heat exchange with the air in the cooling coil 10a, thereby cooling the air from the cooling target chamber 2 to the cooling chamber 4. In this way, the temperature of the refrigerant is further increased by being used in the cooling coil 10 a, and then the refrigerant is introduced into the heat exchanger 50 through the refrigerant supply pipe 12. Thereafter, similarly, the refrigerant circulates in the refrigerant supply pipe 12, and heat exchange is performed in each component of the air conditioning system 1 as described above. Thus, since the refrigerant used in the cooling coil 10b is cascaded in the cooling coil 10a, the flow rate of the refrigerant can be reduced as compared with the case where the refrigerant is separately supplied to each cooling coil. It becomes possible to reduce the conveyance power of the refrigerant by the pump.

  Next, a process for circulating air in each room of the information processing facility will be described. First, the blower fan 20 provided in the cooling chamber 4 sucks air from the upper layer of the cooling chamber 4 and blows out air to the lower layer of the cooling chamber 4. Thus, as shown in FIG. 2, the cold aisle, the inside of the rack 8, the hot aisle, the ceiling chamber 2 c, the upper layer of the cooling chamber 4, the lower layer of the cooling chamber 4, and the ventilation chamber 3 are sequentially passed to the cold aisle. And air circulates.

  Here, first, the air taken into the cold aisle cools the information processing device by passing through the inside of the rack 8, and is heated by the heat generated by the information processing device at this time to a high temperature (for example, 30 ° C.). And is taken into the ceiling chamber 2c. The air taken into the ceiling chamber 2c is taken into the upper layer of the cooling chamber 4 through the opening 11a. At this time, the air passing through the opening 11a is cooled by the cooling coil 10a and has a medium temperature (for example, 24 ° C.). It becomes.

  As described above, in the present embodiment, among the plurality of cooling coils 10 a and 10 b, any one of the plurality of cooling coils 10 a is disposed upstream of the cooling chamber 4, and the remaining plurality of cooling coils 10 b are disposed in the cooling chamber 4. Since it arrange | positions downstream, the air of the chamber 2 to be cooled is not taken directly into the cooling chamber 4 but is cooled and taken up to an intermediate temperature (for example, 24 ° C.). Therefore, it is possible to improve the working environment of the cooling chamber 4 by the worker as compared with the case where the cooling chamber 4 is a high temperature (for example, 30 ° C.) space or a low temperature (for example, 18 ° C.) space. In addition, since various devices (for example, the blower fan 20 and the air conditioning power panel 30) disposed in the cooling chamber 4 are not disposed in a high-temperature environment, it is possible to extend the life of these various devices. .

  The air taken into the upper layer of the cooling chamber 4 is taken into the lower layer of the cooling chamber 4 through the blower fan 20 and mixed with the air taken into the lower layer of the cooling chamber 4 by the outside air introduction fan 40. Air is taken into the ventilation chamber 3 through the opening 11b. At this time, the air passing through the opening 11b is cooled by the cooling coil 10b and becomes a low temperature (for example, 18 ° C.). The air taken into the ventilation chamber 3 in this way is taken into the cold aisle through a connection hole provided in the floor of the cooling target chamber 2 and again taken into the inside of the rack 8 to operate the information processing device. Cooling. Thereafter, similarly, as described above, the information processing device is cooled by the air flowing in the rooms of the information processing facility. This is the end of the description of the air conditioning process by the air conditioning system 1.

(Effect of embodiment)
Thus, according to this Embodiment, since an air conditioner is separated and comprised in the ventilation fan 20, the cooling coil 10a, and the cooling coil 10b, the restrictions on installation space can be relieve | moderated and the cooling target chamber 2 of high load can be reduced. Even in the case of air conditioning, the cooling chamber 4 can be concentrated and arranged on one side of the cooling target chamber 2 and the ventilation chamber 3, and the cooling coil is positioned between the cooling target chamber 2 and the cooling chamber 4. 10a is disposed, and the cooling coil 10a cools the air from the cooling target chamber 2 to the cooling chamber 4, thereby cooling the air including the heat from the device disposed in the cooling target chamber 2 with the cooling coil 10a. In addition, it can be taken into the cooling chamber 4 to improve the work efficiency of maintenance inspections and the like in the cooling chamber 4 by workers and to extend the life of various devices accommodated in the cooling chamber 4. That. Furthermore, since the blower fan 20, the cooling coil 10a, and the cooling coil 10b are configured separately, setting of the respective equipment capacities as compared with the case where the blower fan 20, the cooling coil 10a, and the cooling coil 10b are accommodated in the same casing. The degree of freedom can be improved.

  Further, since the cooling coil 10a and the cooling coil 10b are arranged at positions that overlap each other in a predetermined direction, the arrangement space of the cooling coil 10a and the cooling coil 10b is reduced in the cross section orthogonal to the predetermined direction, and the cooling chamber 4 is reduced. Therefore, the cooling target chamber 2 can be configured to be wider and more devices can be installed in the cooling target chamber 2.

  Further, since the refrigerant heated by the heat exchange with the air in the cooling coil 10b is diverted in the cooling coil 10a, the refrigerant flow rate can be reduced as a whole, and the conveyance power of the refrigerant can be reduced. It becomes possible to improve.

  In addition, since the UPS chamber 5 is disposed at a position facing the cooling chamber 4 with the cooling target chamber 2 and the ventilation chamber 3 interposed therebetween, the wiring of the air conditioning equipment and the wiring of the electrical equipment are not mixed in the cooling chamber 4, and the air conditioning The flow line of the facility manager and the flow line of the electrical facility manager do not interfere with each other, and it is possible to further improve the efficiency of maintenance and inspection by each manager. .

  Further, since the air conditioning power panel 30 is arranged in the cooling chamber 4, the flow line of the manager of the air conditioning equipment can be concentrated in the cooling chamber 4, and the work efficiency of maintenance inspection can be improved. In addition, the air conditioning power panel 30 can be disposed in a space into which air cooled by the cooling coil 10a flows, so that the life of the air conditioning power panel 30 can be extended and the work efficiency of maintenance and inspection can be further improved. . In addition, the air conditioning power panel 30 can be disposed in the vicinity of the blower fan 20, and the work efficiency of maintenance and inspection can be further improved.

[Modifications to Embodiment]
Although the embodiments of the present invention have been described above, the specific configuration and means of the present invention can be arbitrarily modified and improved within the scope of the technical idea of each invention described in the claims. Can do. Hereinafter, such a modification will be described.

(About problems to be solved and effects of the invention)
First, the problems to be solved by the invention and the effects of the invention are not limited to the above contents, and may vary depending on the implementation environment and details of the configuration of the invention. May be solved, or only some of the effects described above may be achieved. For example, when the air conditioning process of the air conditioning system 1 according to the present embodiment cannot improve the worker's work efficiency than before, or when the various devices accommodated in the cooling space cannot have a longer life than before. Even in such a case, when the air-conditioning process can be achieved by a technique different from the conventional technique, the problem of the present invention is solved.

(About dimensions and materials)
The dimensions, shapes, ratios, and the like of each part of the air conditioning system 1 described in the detailed description of the invention and the drawings are merely examples, and may be any other dimensions, shapes, ratios, and the like.

(About the arrangement of each room that constitutes the information processing facility)
Further, the arrangement of each room is not limited to the arrangement described above. For example, in the present embodiment, the ventilation chamber 3 has been described as being disposed so as to be adjacent to the cooling target chamber 2 along the height direction. However, the present invention is not limited thereto, and for example, along the width direction. You may arrange | position so that it may adjoin. Further, in the present embodiment, the UPS chamber 5 has been described as being disposed at a position facing the cooling chamber 4 with the cooling target chamber 2 and the ventilation chamber 3 interposed therebetween. However, the present invention is not limited to this. 3 may be arranged on the lower floor of 3 or on the upper floor of the room 2 to be cooled, or may be arranged so as to be adjacent to the room 2 to be cooled along the width direction.

(About air conditioning system modules)
In the above description, only the air conditioning system 1 and a part of the room where the air conditioning system 1 is provided have been described. System 80 may be formed. FIG. 3 is a plan view showing a composite air conditioning system 80 according to the modification. In addition, although the number of the modules 81 is arbitrary, in this modification, the composite type air conditioning system 80 in which six modules 81 are arranged is illustrated. Here, it is desirable that each module 81 is devised so that the UPS manager and the flow line of the fan fan 20 and the cooling coil manager do not intersect by integrating the UPS room 5 and the cooling room 4. . Specifically, as shown in FIG. 3, the modules 81 are arranged side by side in the same direction along the width direction, and are arranged side by side in the symmetrical direction along the depth direction, thereby collecting the UPS chambers 5 of the modules 81. In addition, by forming a passage between the machine rooms 6, it is possible to collect the flow lines of the manager. Thus, by forming the composite air conditioning system 80 by arranging a plurality of modules 81 side by side, the composite air conditioning system 80 suitable for the number of information processing devices to be cooled, the amount of heat generation, and the like is configured. It becomes possible to do. In the modification, a passage 82 for an administrator to access the UPS room 5 is provided at a position between the UPS rooms 5 constituting the plurality of modules 81.

(About the blower fan)
In this Embodiment, although demonstrated as what arrange | positions the ventilation fan 20 only in the cooling chamber 4, it is not limited to this. For example, a ventilation fan 20 that blows air toward the cold aisle may be added inside the ventilation chamber 3 to increase the power of blowing as a whole.

(About the first cooling means and the second cooling means)
In the present embodiment, the refrigerant that has been introduced into the cooling coil 10b and subjected to heat exchange has been described as being subsequently introduced into the cooling coil 10a and subjected to heat exchange. However, the present invention is not limited thereto. For example, the cooling coil 10a and the cooling coil 10b may be configured independently of each other so that only one of the cooling coil 10a or the cooling coil 10b can exchange heat with the refrigerant. In this case, when one side cannot perform heat exchange due to the circulation of the refrigerant for maintenance or the like, heat exchange can be performed only by the other side, so that the reliability of the air conditioning system 1 can be improved. In this state, a spare cooling coil can be added on the other side, and the air conditioning system 1 can be continuously operated even during maintenance. Furthermore, the piping system and heat source connected to the cooling coil 10a and the piping system and heat source connected to the cooling coil 10b are also provided in parallel, whereby the reliability of the air conditioning system 1 can be further improved.

(Appendix)
The air conditioning system according to appendix 1 includes a cooling target space including a device to be cooled, a ventilation space arranged to be adjacent to the cooling target space along a predetermined direction, the cooling target space, and the cooling target space. A cooling space arranged to communicate the ventilation space with each other, wherein the cooling space is configured to cool the air from the cooling space to the cooling space sequentially through the ventilation space and the space to be cooled. An air conditioning system that cools the device by forming a circulating air flow, the blower unit that is disposed in the cooling space to form the air flow, the cooling target space, and the cooling space, A first cooling means arranged at a position between the first cooling means for cooling air from the cooling target space to the cooling space, and the cooling space and the ventilation space. A second cooling means disposed at the position of 互間, and a second cooling means for cooling the air leading to the ventilation space from the cooling space.

  The air conditioning system according to appendix 2 is the air conditioning system according to appendix 1, wherein the first cooling means and the second cooling means are arranged at positions that overlap in the predetermined direction.

  The air conditioning system according to attachment 3 is the air conditioning system according to attachment 1 or 2, wherein a refrigerant for cooling the air is supplied to the second cooling means, and heat exchange with the air is performed by the second cooling means. And a refrigerant supply means for supplying the heated refrigerant to the first cooling means.

  The air conditioning system according to appendix 4 is the air conditioning system according to any one of appendices 1 to 3, wherein the cooling space includes a first side surface that constitutes the cooling target space, and a second that constitutes the ventilation space. A first side surface and a second side surface disposed flush with each other, the device power supply space for supplying power to the device, the cooling target space and It arrange | positioned in the position facing the said cooling space on both sides of the said ventilation space.

  The air conditioning system according to appendix 5 is the air conditioning system according to any one of appendices 1 to 4, wherein air blowing control means for controlling the air blowing means is arranged in the cooling space.

  The air conditioning system according to appendix 6 is the air conditioning system according to any one of appendices 1 to 5, further comprising outside air introduction means for introducing outside air into the cooling space.

  The air conditioning system according to appendix 7 has a plurality of modules arranged in parallel, with the air conditioning system according to any one of appendices 1 to 6 as a single module.

(Additional effects)
According to the air conditioning system described in appendix 1, the air conditioner is configured to be separated into the air blowing means, the first cooling means, and the second cooling means, so that the restrictions on the installation space can be relaxed, and the high load cooling target space Even in the case of air conditioning, the cooling space can be concentrated and arranged on one side of the cooling target space and the ventilation space, and the first cooling means is disposed at a position between the cooling target space and the cooling space. By cooling the air from the cooling target space to the cooling space by the first cooling means, the air containing heat from the equipment arranged in the cooling target space is cooled by the first cooling means and then into the cooling space. This makes it possible to improve the work efficiency of maintenance inspections and the like in the cooling space by workers, and to extend the life of various devices accommodated in the cooling space. Furthermore, since the blowing means and each cooling means are configured separately, it is possible to improve the degree of freedom of setting the respective equipment capacities as compared with the case where the blowing means and each cooling means are accommodated in the same housing. Become.

  According to the air conditioning system of appendix 2, since the first cooling means and the second cooling means are arranged at positions that overlap in a predetermined direction, the first cooling means and the second cooling means in a cross section orthogonal to the predetermined direction. It is possible to reduce the cooling space by reducing the arrangement space, and it is possible to configure a wider space to be cooled and install more devices in the space to be cooled.

  According to the air conditioning system described in appendix 3, since the refrigerant that has been heated and exchanged with air in the second cooling unit is used in the first cooling unit, the flow rate of the refrigerant is reduced as a whole. The conveyance power can be reduced, and the energy saving performance can be improved.

  According to the air conditioning system described in appendix 4, since the device power supply space is arranged at a position facing the cooling space with the cooling target space and the ventilation space interposed therebetween, the wiring of the air conditioning facility and the wiring of the electrical facility are connected to the cooling space. The flow line of the air conditioner manager and the flow line of the electric equipment manager do not interfere with each other, further improving the work efficiency of maintenance and inspection by each manager. It becomes possible to plan.

  According to the air conditioning system described in appendix 5, since the air blowing control means is arranged in the cooling space, it is possible to concentrate the flow line of the manager of the air conditioning equipment in the cooling space and improve the work efficiency of the maintenance inspection. It becomes possible. Further, the air blowing control means can be arranged in the space into which the air cooled by the first cooling means flows, and it is possible to extend the life of the air blowing control means and further improve the work efficiency of maintenance and inspection. Further, the air blowing control means can be arranged in the vicinity of the air blowing means, and it is possible to further improve the work efficiency of the maintenance inspection.

  According to the air conditioning system described in appendix 6, since the outside air is introduced into the cooling space by the outside air introduction unit, the cooling load of the first cooling unit and the second cooling unit can be reduced, and the energy saving performance can be improved. It becomes possible.

  According to the air conditioning system described in appendix 7, since a composite air conditioning system is configured by arranging a plurality of modules in parallel, a composite air conditioning system suitable for the number of devices to be cooled, the amount of heat generation, and the like. It becomes possible to configure.

DESCRIPTION OF SYMBOLS 1 Air conditioning system 2 Cooling target room 2a Ceiling slab 2b Ceiling material 2c Ceiling chamber 3 Ventilation room 4 Cooling room 4a Flooring material 5 UPS room 6 Machine room 7 Seismic isolation layer 8 Racks 10a and 10b Cooling coils 11a and 11b Opening part 12 Refrigerant supply Pipes 13a and 13b Cooling tower 14 Piping 20 Blower fan 30 Air conditioning power panel 40 Outside air introduction fan 50 Heat exchanger 60 Refrigerator 70 Cushion tank 80 Combined air conditioning system 81 Module 82 Passage 100 Air conditioning system 101 Information processing equipment room 102 Maintenance floor 103 Duct area 104 UPS room 105 Rack 110 Air conditioners 120a and 120b Cooling coil 130 Blower fan 140 Refrigerant supply pipe 200 Air conditioning system

Claims (7)

A cooling target space including a device to be cooled, a ventilation space arranged adjacent to the cooling target space along a predetermined direction, and the cooling target space and the ventilation space communicate with each other. Forming a flow of air that circulates from the cooling space to the cooling space through the ventilation space and the cooling target space in order in the cooling space that is disposed and that cools the air; By the air conditioning system for cooling the equipment,
A blowing means arranged in the cooling space to form the air flow;
A first cooling means arranged at a position between the cooling target space and the cooling space, the first cooling means for cooling the air from the cooling target space to the cooling space;
Second cooling means disposed at a position between the cooling space and the ventilation space, the second cooling means for cooling the air from the cooling space to the ventilation space,
Air conditioning system. The first cooling means and the second cooling means are arranged at positions overlapping in the predetermined direction,
The air conditioning system according to claim 1. Refrigerant supply for supplying refrigerant for cooling air to the second cooling means and supplying refrigerant heated by heat exchange with air in the second cooling means to the first cooling means With means,
The air conditioning system according to claim 1 or 2. In the cooling space, a first side surface that constitutes the space to be cooled and a second side surface that constitutes the ventilation space, the second side surface disposed flush with the first side surface, communicate with each other. And place
A device power supply space for supplying power to the device is disposed at a position facing the cooling space across the cooling target space and the ventilation space.
The air conditioning system according to any one of claims 1 to 3. The air blowing control means for controlling the air blowing means is disposed in the cooling space.
The air conditioning system according to any one of claims 1 to 4. Comprising outside air introduction means for introducing outside air into the cooling space;
The air conditioning system according to any one of claims 1 to 5. A combined air conditioning system in which the air conditioning system according to any one of claims 1 to 6 is used as a single module and a plurality of modules are arranged in parallel.

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