JP4422935B2 - Air conditioning system - Google Patents

Description

[0001]
[Technical fields used]
The present invention relates to an air conditioning system having an indoor unit provided with an outlet for blowing out cool air for each model and a heat source unit equipped with a capacity-controlled compressor.
[0002]
[Prior art]
Recently, the density of electronic devices has been increasing, and the devices themselves are becoming more compact. On the contrary, there is a phenomenon that the thermal load on the installation area is increasing.
[0003]
FIG. 9 is a configuration diagram of a conventional local air conditioning system that intensively cools only a high-density sensible heat load device in a room where a high-density sensible heat load device such as a computer is installed. In FIG. 9, arrows indicate the flow of circulating air.
In FIG. 9, the air conditioner includes an outdoor unit 100 having an outdoor heat exchanger that is a condenser, an indoor unit 200 having a compressor and an indoor heat exchanger that is an evaporator, and the outdoor unit 100 and the indoor unit. 200 is mainly composed of a liquid pipe 300 and a gas pipe 301 that are connected to 200. The upper surface of the indoor unit 200 has a suction port for sucking indoor air, and a discharge duct 201 for discharging cool air from the lower surface of the indoor unit 200 is fixed to the floor surface 302 and the floor surface 302. It protrudes into an in-floor space 304 formed by an access surface 303 made of a concrete plate arranged on a plurality of iron pipes. Note that the indoor unit 200 is usually placed in a corner of the equipment installation space.
[0004]
Reference numeral 305 denotes a high-density sensible heat load device such as a computer, which is installed on the access surface 303. Note that a portion of the access surface 303 located immediately below the high-density sensible heat load device 305 has a plurality of openings, and the cool air discharged into the floor space 304 passes through the openings of the access surface 303. The fan 305a, which is sent from the lower part of the high-density sensible heat load device 305 to the inside and rotates at the upper part, rotates to flow inside the high-density sensible heat load device 305 from the bottom to the top, thereby depriving the internal heat It will be.
[0005]
The air that has passed through the inside of the high-density sensible heat load device 305 is discharged into the device installation space 306 from an upper air outlet (not shown). The discharged air is again sucked from the suction port of the indoor unit 200, cooled, and then discharged from the discharge duct 201.
[0006]
Next, the detailed structure of an air conditioner is demonstrated based on the refrigerant circuit figure of FIG. In FIG. 10, solid arrows indicate the flow of the refrigerant.
In FIG. 10, the air conditioner has a two-system configuration of A and B having two units, an outdoor unit 100a and an outdoor unit 100b, and even if one of the outdoor units breaks down, the other outdoor unit remains Operation is continued and at least half of the cooling capacity can be exerted.
The outdoor unit 100a includes an outdoor heat exchanger 101a and an outdoor fan 102a. The outdoor heat exchanger 101a is connected to the liquid pipe 300a and the gas pipe 301a via internal pipes. . The outdoor unit 100b has the same configuration as the outdoor unit 100a.
[0007]
Moreover, the indoor unit 200 also has two systems, A and B. In the A system, the compressor 202a, the indoor heat exchanger 203a, and the expansion mechanism 204a are sequentially connected by piping, and the refrigerant discharge port of the compressor 202a is connected to the gas pipe 301a via the internal piping. The refrigerant suction port of the expansion mechanism 204a is connected to the liquid pipe 300a via an internal pipe. The first pipe temperature detector 205a is installed in the internal pipe connected to the suction port of the compressor 202a, and the second pipe temperature is set in the internal pipe connected to the suction port of the indoor heat exchanger 203a. A detector 206a is installed, and further, a first air temperature detector 207a and a second air temperature detector 208a are installed across the indoor heat exchanger 203a, and the first pipe temperature detection is performed. Temperature information detected by the container 205a, the second pipe temperature detector 206a, the first air temperature detector 207a, and the second air temperature detector 208a is sent to the indoor control device 209a. The indoor control device 209a adjusts the starting frequency of the compressor 202a and the opening degree of the expansion mechanism 204a based on this temperature information. The B system of the indoor unit 200 has the same configuration as the A system.
[0008]
Moreover, the indoor side air blower 210 is arrange | positioned in the vicinity of the indoor side heat exchanger 203a, 203b, and the air which passed the indoor side heat exchanger 203a, 203b is discharged from the discharge duct 201 by operating.
[0009]
Next, the operation of the air conditioner shown in FIG. 10 will be described.
The high-temperature and high-pressure gas refrigerant compressed and discharged by the compressor 202a flows into the outdoor heat exchanger 101a through the gas pipe 301a. Here, the liquid refrigerant cooled and liquefied by the air blown by the outdoor fan 102a flows into the expansion mechanism 204a through the liquid pipe 300a, where it is expanded and decompressed to a low-temperature / low-pressure gas-liquid two-phase state. Later, it is sent to the indoor heat exchanger 203a. In the indoor heat exchanger 203a, the gas-liquid two-phase refrigerant is heated by the air conveyed by the indoor blower 210 to become a low-pressure gas refrigerant, and returns to the compressor 202a.
[0010]
[Problems to be solved by the present invention]
In the above-described air conditioning system, cold air is once discharged into the in-floor space 304, and the high-density sensible heat load device 305 sucks the cold air. Even so, there is a problem that individual adjustments such as sending a large amount of cold air to a device with a large amount of exhaust heat and sending a small amount of cold air to a device with a small amount of heat exhaust are difficult.
[0011]
In recent years, there are many devices that generate relatively large heat even though the housing is small. A plurality of such devices are arranged side by side on a shelf or the like. However, since there is no fan like the high-density sensible heat load device 305, in the cold air discharged from the underfloor space 304, the device located at the top is sufficient. There was a problem that it was not cooled.
Furthermore, there is a problem that the installation space for other devices is reduced by the amount of installation of the indoor unit on the access surface.
[0012]
In JP 2000-18663 A, a cooling coil unit that circulates and sends cooling water from outside to the system ceiling space through a cold water pipe and a fan filter unit are arranged in combination. A local air-conditioning system is described in which cold air is sent to an internal manufacturing apparatus to process a sensible heat load, and warmed air is sent to the under-floor space under free access and the system ceiling space via a return shaft. Also, here, even if the layout of the production equipment in the clean room is changed, the cooling coil unit and the fan filter unit are connected by a flexible duct so that the layout change and expansion of the production line can be handled easily. Without changing the arrangement of the cooling coil unit, the arrangement of the fan filter unit, the routing of the flexible duct, and the connection can be changed.
[0013]
However, in such a method using cooling water, there is a problem that a water circuit has to be drawn up to the cooling coil unit in the space behind the ceiling, which may cause problems such as water leakage.
In addition, it is only possible to control the flow rate of the chilled water flowing through the cooling coil unit based on the temperature detected by the temperature sensor arranged in the vicinity of the discharge port of the fan filter unit. There was a problem that could not.
[0014]
Also, changing the water piping requires a large load and basically the movement of the cooling coil unit body is not possible, so in order to cope with layout line changes and expansion, Forcible routing of the flexible duct occurs, and it is necessary to change the connection, which increases the cost and requires that the air conditioning in the room be stopped for a long time. And the forcible routing of the duct leads to an increase in blowing power due to an increase in pressure loss, which impedes energy saving.
[0015]
This invention has been made to solve the above-mentioned problems, and the amount and direction of the cool air to be sent can be adjusted according to the position and model of the high-density sensible heat load device, etc., and the amount of heat to be discharged, and efficient local cooling is achieved. It aims to provide an air conditioning system that can be used.
[0016]
[Means for Solving the Problems]
The air conditioning system according to the present invention includes a plurality of indoor units including an indoor heat exchanger, an expansion mechanism, and an indoor fan, a compressor, and an outdoor heat exchanger, and includes the indoor unit, liquid pipe, and gas. The indoor unit is arranged in the indoor ceiling space divided from the top into the ceiling space, the equipment installation space, and the floor space from above, and the equipment installation space, equipment position and equipment Wind direction setting means for setting the relationship with the type of the wind, and wind direction control for automatically controlling the optimum wind direction of the indoor unit according to the position and type of the equipment placed in the equipment installation space received from the wind direction setting means Means.
[0017]
Furthermore, the space in the ceiling and the space in the floor are connected by a duct having a blower.
[0018]
Further, the air intake means for taking in air from the outside is arranged in the ceiling space, and the air discharge means for discharging air to the outside is arranged in the floor space.
[0019]
In the case where the installed device is a high-density sensible heat load device having an air discharge device at the lower part, the wind direction control means sends cold air to the upper part of the high-density sensible heat load device, and has the air discharge device at the upper part. In the case of high-density sensible heat load equipment, the direction of the wind is controlled so that cold air is sent to the lower part of the high-density sensible heat load equipment.
[0020]
Further, the wind direction control means changes the direction of the wind direction according to whether or not the installed equipment has an air discharge device that exhausts air into the floor space.
[0021]
Furthermore, the indoor unit is configured to detect at least an opening degree of the expansion valve of the indoor unit or the number of rotations of the indoor fan according to the detection means that detects the internal temperature of the device arranged in the device installation space. And indoor unit control means for controlling one of them.
[0022]
Further, the indoor unit has at least a detection means for detecting the ambient temperature of the device arranged in the device installation space, and at least the opening degree of the expansion valve of the indoor unit or the rotation speed of the indoor fan according to the detected ambient temperature. And indoor unit control means for controlling one of them.
[0023]
An air conditioning system according to the present invention includes an indoor unit including an indoor heat exchanger, an expansion mechanism, and an indoor fan, a compressor, and an outdoor heat exchanger, and includes the indoor unit, liquid pipe, and gas. The indoor unit is arranged in an indoor floor space divided from above into an equipment installation space and an in-floor space.
[0024]
DETAILED DESCRIPTION OF THE INVENTION
Embodiment 1 FIG.
1 is a configuration diagram of an air conditioning system according to Embodiment 1 of the present invention. In FIG. 1, arrows indicate the flow of circulating air.
In FIG. 1, the room has an equipment installation space 1, an upper concrete ceiling surface 2, and a ceiling surface 3 installed so as to be suspended from the concrete ceiling surface 2 by a metal member fixed to the concrete ceiling surface 2. In the floor formed by the space 4 in the ceiling formed from the above, the lower floor surface 5, and the access surface 6 made of a concrete plate arranged on a plurality of metal members fixed to the floor surface 5 It is divided into a space 7. In addition, a hole is formed in a part along the wall of the access surface 6, and a hole is also formed in the ceiling surface 3 facing the hole, and a blower 8 is provided between the two holes. A duct 9 is installed.
[0025]
In addition, two indoor units 20a and 20b are installed on the ceiling surface 3 so that the air blowing ports face the inside of the device installation space, and are connected to the outdoor unit 50 arranged outside by a liquid pipe 80 and a gas pipe 81. Has been. The specific connection state is as shown in FIG. Further, a plurality of high-density sensible heat load devices 83 having an air discharge device 82 having an air suction port (not shown) at the upper portion and a fan for discharging air into the floor space 7 at the lower portion are provided on the access surface 6. Is installed.
[0026]
Next, details of the air conditioner mainly composed of the indoor units 20a and 20b, the outdoor unit 50, the liquid pipe 80, and the gas pipe 81 will be described with reference to FIG. In FIG. 3, the arrows indicate the flow of the refrigerant.
In FIG. 3, the outdoor unit 50 includes a compressor 51 that is driven by an inverter with a variable frequency, an outdoor heat exchanger 52, and an outdoor fan 53, and the compressor 51 is further connected via an inlet side pipe. The outdoor heat exchanger 52 is connected to the liquid pipe 80 via the outlet side pipe.
Further, a bypass pipe 55 having a throttle device 54 is connected between the inlet side pipe connecting the compressor 51 and the gas pipe 81 and the outlet side pipe connecting the outdoor heat exchanger 52 and the liquid pipe 80. A refrigeration effect increasing heat exchanger 56 is installed to exchange heat between the outlet side pipe of the outdoor heat exchanger 52 and the downstream side of the expansion device 54 of the bypass pipe 55.
Further, an evaporating pressure detector 57 for detecting the refrigerant pressure is installed in the inlet side pipe of the compressor 51, and pressure information detected by the evaporating pressure detector 57 is sent to the outdoor control device 58. The outdoor side control device 58 controls the frequency of the compressor 51 and further sends pressure information to the indoor unit via the outdoor side transmission device 59.
[0027]
Further, in the indoor unit 20a, a liquid branch pipe 21a branched from the liquid pipe 80, an expansion mechanism 22a connected to the liquid branch pipe 21a, an indoor heat exchanger 23a connected to the expansion mechanism 22a, A gas branch pipe 24a connected to the indoor side heat exchanger 23a and an indoor blower 25a for sending cool air cooled by the indoor side heat exchanger 23a in the equipment installation space. The gas pipe 81 is connected.
[0028]
The first piping temperature detector 26a is installed in the internal piping connecting the expansion mechanism 22a and the indoor heat exchanger 23a, and the internal piping connected to the discharge port of the indoor heat exchanger 23a is the first. 2 pipe temperature detectors 27a are installed, and further, a first air temperature detector 28a and a second air temperature detector 29a are installed across the indoor heat exchanger 23a. Temperature information detected by the temperature detector 26a, the second pipe temperature detector 27a, the first air temperature detector 28a, and the second air temperature detector 29a is sent to the indoor control device 30a. The indoor control device 30a includes a first pipe temperature detector 26a, a second pipe temperature detector 27a, a first air temperature detector 28a, a second air temperature detector 29a, and a high-density microscope. The temperature of the expansion mechanism 22a and the number of rotations of the indoor blower 25a are received by receiving temperature information from the device temperature detector 31a that detects the temperature of the device through a temperature detector installed in or near the thermal load device 83. Further, temperature information is sent to the outdoor unit via the indoor transmission device 32a.
The indoor unit 20b has the same configuration as the indoor unit 20a.
Further, the air direction control of the air conditioners such as the indoor fans 25a and 25b is comprehensively controlled by the air direction control device.
[0029]
Next, the wind direction control of each indoor unit will be described with reference to the configuration diagram of the wind direction control system in FIG. Air conditioning in the installation space where high-density sensible heat load equipment, etc. is installed is local air conditioning that concentrates only on high-density sensible heat load equipment, etc. and sends cold air. If this is set, efficient control cannot be performed. Therefore, the wind direction control system of FIG. 4 realizes optimal wind direction control according to the arrangement and properties of the devices in the device installation space.
[0030]
In FIG. 4, the wind direction control device 33 and the wind direction setting device 34 are connected by a communication line 35. The wind direction setting device 34 includes a display 34a and a mouse 34b. In the wind direction control system having such a configuration, first, a room manager (a so-called system manager in the case of a computer room) uses a mouse 34b on a plan view of a room displayed on the display 34a to Is associated with the type of the device and written in, for example, the device range 36 in FIG. The types of equipment include, for example, a high-density sensible heat load device having an air discharge device in the lower portion, a high-density sensible heat load device having an air discharge device in the upper portion, or a plurality of small sensible heat load devices. It is a group of high-density sensible heat load devices arranged on a shelf. This information from the wind direction setting device 34 is sent to the wind direction control device 33.
[0031]
In the wind direction control device 33, cold air is sent from the nearest indoor unit by associating the equipment with the indoor unit closest to the equipment from the installation position of the equipment in the equipment installation space. The direction of wind in the indoor unit is determined from the distance between the device and the indoor unit and the type of the device. For example, in the case of a high-density sensible heat load device having an air discharge device in the lower part, so as to send cold air intensively to the upper part of the high-density sensible heat load device (there is an air discharge device, In the case of a high-density sensible heat load device having an air discharge device on the upper part), the cold air is intensively sent to the lower part of the high-density sensible heat load device. In the case of a group, cool air is sent around the front or rear of the equipment (because it is installed on the shelf, even if cool air is sent to the top, cold air does not reach the bottom).
[0032]
Next, the operation of the air conditioning system shown in FIGS.
In addition, since the indoor unit 20a and the indoor unit 20b perform the same operation | movement, suppose that a suffix is abbreviate | omitted and demonstrated.
First, the high-temperature and high-pressure gas refrigerant compressed and discharged by the compressor 51 flows into the outdoor heat exchanger 52. Here, the frequency of the compressor 51 is calculated based on the temperature information in each indoor unit sent from the outdoor control device 58 via the evaporation pressure detector 57 and the outdoor transmission device 59.
Further, heat exchange with the air blown by the outdoor fan 53 cools the refrigerant to become liquid refrigerant, which flows into the expansion mechanism 23 via the liquid pipe 80 and the liquid branch pipe 21, where the low temperature and low pressure Is expanded and decompressed to a gas-liquid two-phase state.
[0033]
The gas-liquid two-phase refrigerant expanded and depressurized by the expansion mechanism 23 is evaporated by exchanging heat with the air conveyed by the indoor fan 25 in the indoor heat exchanger 23 to become a low-pressure gas refrigerant. .
The opening degree of the expansion mechanism 23 is calculated and determined based on the temperature information received by the indoor side control device 30 from each temperature detector and the pressure information of the outdoor unit received via the indoor side transmission device 32. Is done. In addition, the rotation speed of the indoor fan 25 is also controlled by the indoor controller 30.
[0034]
The cool air cooled by the indoor heat exchanger 23 is sent into the device installation space 1 from the air outlet, but the air direction control device 33 causes the air direction of the air outlet to be directed above the high-density sensible heat load device 83. The cold air is directly blown out toward the high-density sensible heat load device 83. Further, the air heated by passing through the inside of the high-density sensible heat load device 83 is discharged to the underfloor space 7 by the air discharge device 82. The exhaled warm air is sent to the ceiling space 4 through the underfloor space 7 and the duct 9 by operating the blower 8 to send air from below to above, and the indoor side heat of the indoor unit 20 is again transmitted. It is cooled by the exchanger 23.
[0035]
The gas refrigerant evaporated in the indoor heat exchanger 23 returns to the compressor 51 through the gas branch pipe 24 and the gas pipe 81. Part of the liquid refrigerant that has exited the outdoor heat exchanger 52 flows to the bypass pipe 55 and is depressurized by the expansion device 54 to lower the temperature, resulting in a low-temperature / low-pressure gas-liquid two-phase state, thereby increasing the refrigeration effect. Heat is exchanged with the liquid refrigerant exiting the outdoor heat exchanger 52 and gasified in the chamber 55, and merges with the flow that has passed through the indoor unit on the suction side of the compressor 51.
[0036]
In FIG. 2, the high-density sensible heat load device 83 having the air discharge device 82 is installed in the lower portion. However, in the case of the high-density sensible heat load device 84 having the air discharge device in the upper portion as shown in FIG. In the case of a high-density sensible heat load device group 87 in which a plurality of sensible heat load devices 86 are arranged on a shelf 85 as shown in FIG. Cold air is sent around the front or rear of each device.
[0037]
As described above, since the optimum wind direction is automatically set according to the arrangement and type of the device, the cooling efficiency is improved.
In contrast to interpersonal air conditioners, inflatable air conditioners intended only for sensible heat treatment do not require the removal of the latent heat load, so there is no possibility of condensation due to lowering of the blowout temperature, and water leakage There is no need to consider the occurrence of rust caused by water regardless of where indoor units are placed. Furthermore, since the refrigerant piping in the immediate vicinity of the indoor unit is relatively easy to deform (bend, etc.), it is easy to move the indoor unit even if it is not possible to transfer the air-conditioned equipment even if the air direction of the indoor unit is changed. Energy-saving air-conditioning with reduced blast power can be performed in the immediate vicinity of the air-conditioned equipment without using any other means.
[0038]
In addition, the refrigerant flowing to the indoor unit 20 decreases by the amount flowing to the bypass pipe 55, but the temperature of the liquid refrigerant decreases by that amount, and the refrigeration effect (refrigerant outlet enthalpy when evaporating in the indoor unit 20). And the difference in inlet enthalpy) and there is no loss in heat energy. That is, in the calculation formula of evaporation capacity = refrigerant flow rate (kg / h) × refrigeration effect (kW / kg), the refrigerant flow rate decreases, but the refrigeration effect increases and the multiplication results in the same result. Therefore, by providing the bypass pipe, the flow rate of the refrigerant flowing to the indoor unit 20 is reduced, and the friction loss in the liquid pipe 80 can be remarkably reduced.
[0039]
Furthermore, since the opening degree of the expansion mechanism and the rotational speed of the indoor fan can be adjusted for each indoor unit, it can be adjusted individually according to the value obtained from the temperature detector provided for each device, and the high-density sensible heat load device Cooling air control according to the amount of exhaust heat is possible.
[0040]
In this example, the wind direction setting system controls the wind direction only by the installation location and model of the device. For example, the wind direction setting device designates the surface to be cooled and the air intake port of the device. The indoor unit that blows air and the wind direction may be controlled according to the above.
[0041]
Embodiment 2. FIG.
In the air-conditioning system shown in FIG. 1, the warm air discharged into the underfloor space 7 is sent to the ceiling space 4, cooled by the indoor unit, and then sent to the equipment installation space. As shown in FIG. 2, the air discharged into the in-floor space 7 is discharged outside by the conveying means 10 that is an air discharging means, and the outside air is taken into the ceiling space 4 by the external air conditioner 11 that is the air intake means. You may comprise as follows. In this way, it is not necessary to provide a duct in the equipment installation space, and the space for placing the equipment can be further increased.
[0042]
Embodiment 3 FIG.
Even if the indoor unit is not provided in the ceiling space, the individual air conditioning according to the load of the device is possible even in the configuration in which the indoor unit is provided in the lower space of each device in the floor space.
FIG. 8 is a configuration diagram showing the configuration of the air conditioning system in the third embodiment.
In FIG. 8, an indoor unit 41 having an air outlet at the upper part is installed in the floor space 12 at the lower part of the high-density sensible heat load device 86 having the air discharge device 85 at the upper part. In addition, a duct having a blower 12 is arranged at a corner of the equipment installation space, and warm air accumulated in the upper part of the room is sent to the floor space 7 by operating the blower 12.
Even with such a configuration, individual cooling processing according to the thermal load of the device can be performed.
[0043]
【The invention's effect】
As described above, according to the present invention, the optimum cooling process can be performed according to the position and model of the high-density sensible heat load device or the like and the amount of heat to be discharged.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of an air conditioning system in a first embodiment.
FIG. 2 is a schematic view of an air conditioner.
FIG. 3 is a refrigerant circuit diagram of the air conditioner in the first embodiment.
FIG. 4 is a configuration diagram of a wind direction control system.
5 is a configuration diagram of an air conditioning system in Embodiment 1. FIG.
6 is a configuration diagram of an air conditioning system according to Embodiment 1. FIG.
FIG. 7 is a configuration diagram of an air conditioning system in a second embodiment.
FIG. 8 is a configuration diagram of an air conditioning system in a third embodiment.
FIG. 9 is a configuration diagram of a conventional air conditioning system.
FIG. 10 is a refrigerant circuit diagram of a conventional air conditioner.
[Explanation of symbols]
1 equipment installation space, 2 concrete ceiling surface, 3 ceiling surface,
4 ceiling space, 5 floor surface, 6 access surface, 7 floor space,
8 Blower, 9 Duct, 10 Conveying means, 11 External air conditioner,
12 Blower,
20 indoor units, 21 liquid branch pipe, 22 expansion mechanism,
23 indoor heat exchanger, 24 gas branch pipe, 25 indoor fan,
26 first piping temperature detector, 27 second piping temperature detector,
28 first air temperature detector, 29 second air temperature detector,
30 indoor control device, 31 device temperature detector, 32 indoor transmission device,
33 wind direction control device, 34 wind direction setting device, 34a display,
34b mouse, 35 communication line, 36 equipment location,
41 indoor units, 50 outdoor units, 51 compressors, 52 outdoor heat exchangers,
53 outdoor fan, 54 throttle device, 55 bypass pipe,
56 Heat exchanger with increased cooling effect, 57 Evaporation pressure detector,
58 outdoor control device, 59 outdoor transmission device,
81 gas pipe, 82 air discharge device, 83 high-density sensible heat load equipment,
84 High-density sensible heat load equipment, 85 shelves, 86 Sensible heat load equipment,
87 High-density sensible heat load equipment group, 88 fans,
89 High-density sensible heat load equipment.

Claims (7)

An outdoor unit that includes a plurality of indoor units including an indoor heat exchanger, an expansion mechanism, and an indoor fan, a compressor, and an outdoor heat exchanger, and is connected to the indoor unit by a liquid pipe and a gas pipe. Machine
The indoor unit is arranged in the ceiling space in the room divided into a ceiling space, equipment installation space, floor space from above,
A wind direction setting means for setting a relationship between the device installation space, the position of the device, and the type of the device;
An air conditioning system comprising air direction control means for automatically controlling the optimum wind direction of the indoor unit according to the position and type of equipment disposed in the equipment installation space received from the wind direction setting means. .   The air conditioning system according to claim 1, wherein the ceiling space and the floor space are connected by a duct having a blower.   The air conditioning system according to claim 1, wherein air intake means for taking in air from outside is arranged in the ceiling space, and air discharge means for discharging air to the outside is arranged in the floor space. .   2. The air conditioning system according to claim 1, wherein the wind direction control unit changes the direction of the wind direction according to whether or not the installed device has an air discharge device that exhausts air to the in-floor space.   In the case where the installed device is a high-density sensible heat load device having an air discharge device in the lower part, the wind direction control means sends cold air to the upper part of the high-density sensible heat load device, and the air discharge device in the upper part 2. The air conditioning system according to claim 1, wherein in the case of a high-density sensible heat load device having an air flow, the air direction is controlled so as to send cold air to a lower portion of the high-density sensible heat load device.   The indoor unit has at least one of a detection means for detecting the internal temperature of the device arranged in the device installation space, and the opening degree of the expansion valve of the indoor unit or the rotational speed of the indoor fan according to the detected internal temperature. The air conditioning system according to any one of claims 1 to 4, further comprising an indoor unit control means for controlling the air conditioner.   The indoor unit has at least one of a detection means for detecting the ambient temperature of the device arranged in the device installation space, and the opening degree of the expansion valve of the indoor unit or the rotational speed of the indoor fan according to the detected ambient temperature. The air conditioning system according to any one of claims 1 to 4, further comprising an indoor unit control means for controlling the air conditioner.

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