JP2013047588A - Air conditioning structure of building construction - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air conditioning structure of a building construction, which improves assemblability and maintainability, is saved in energy and high in efficiency.SOLUTION: The building structure which defines an in-room space by an outer wall body 2 having a hollow inside comprises an air conditioner 1 which is constituted of: a compressor 24 which compresses a refrigerant into a semi-liquefied state; a condenser 17 which condenses the refrigerant compressed by the compressor 24 into a liquefied state; an evaporator 15 which evaporates the refrigerant condensed by the condenser 17; and an air blower 13 which makes air sucked from a room 3 pass through the evaporator 15 and sends the air into the room 3. A temperature in the room 3 is adjusted by the air conditioner 1, the outer wall body 2 has a ventilation part 39 which changes air in the room 3 and air outside a room 4, and the air conditioner 1 is vertically arranged at the outer wall body 2.

Description

  The present invention relates to an air conditioning structure of a building structure that adjusts the temperature of an indoor space with an air conditioner, and more specifically, the indoor space is defined by an outer wall body having a cavity inside, and air is placed above the outer wall body. The present invention relates to an air conditioning structure of a building structure having a ventilation system for indoor air in which an air conditioning case having a suction port and a discharge port is mounted and an air conditioner is installed on the outer wall body.

  Many building structures such as detached houses are equipped with an air conditioner that adjusts the temperature of the indoor space. As is well known, this air conditioner includes a compressor that compresses a refrigerant into a semi-liquefied state, a condenser that condenses the refrigerant compressed by the compressor into a liquefied state, and an evaporator that vaporizes the refrigerant condensed by the condenser. The air sucked from the indoor space is passed through the evaporator, cooled, etc., and blown back into the indoor space to adjust the room temperature of the indoor space.

  Here, in a building structure such as a detached house, in order to improve the indoor environment and save energy, a heat insulating material is installed on the wall surface of the building structure to reduce energy loss due to a temperature difference between indoor and outdoor. ing. In addition, a technique is known in which the wall of a building structure has a double structure, and air is circulated through the gap between the inner wall and the outer wall to increase the efficiency of air conditioning. There are various buildings having an air circulation structure in which such a building structure and an air conditioner are combined, and there is also a configuration in which an air conditioner is installed on an outer wall body having a cavity inside.

  For example, in patent document 1 (Unexamined-Japanese-Patent No. 2010-54167), in a tent of a double wall structure, air is circulated through a gap between an inner wall and an outer wall, and a part of an air conditioner is installed in the gap.

  Moreover, in patent document 2 (Unexamined-Japanese-Patent No. 08-334257), in the housing of a double wall structure, the air-conditioning structure of the structure which installed the air conditioner in the clearance gap between an inner wall and an outer wall so that it may not protrude to the indoor side or the outdoor side. It is.

JP 2010-54167 A Japanese Patent Laid-Open No. 08-334257

  However, in the air conditioning structure as in Patent Document 1, since these air conditioners have an indoor unit and an outdoor unit, a large installation space for the air conditioner is required, resulting in wasted space. In addition, there is a problem that the piping (refrigerant flow path) having a distance connecting the indoor unit and the outdoor unit increases the cost due to heat loss of the refrigerant and wasteful use of the piping member. And in the air-conditioning structure like patent document 2, since the cooling of the refrigerant | coolant in a condenser was performed with the high temperature external air using the condenser fan, the cooling efficiency of a refrigerant | coolant was bad and the use cost of a condenser fan was also carried out. There was also the problem that it took. In addition, while the airtightness of building structures such as detached houses is increased, the use of residential building materials that release chemical substances, and the reduction of ventilation due to the opening of windows due to the widespread use of air conditioners, etc. Therefore, it is indispensable to install equipment for ventilating indoor air in a building structure such as a detached house. Therefore, since the cooled indoor air is discharged to the outside by such a ventilation facility, a decrease in air conditioning efficiency is also a problem.

  Accordingly, an object of the present invention is to provide an air-conditioning structure for a building structure including an energy-saving and highly efficient air-conditioning apparatus.

For this reason, the invention according to claim 1 includes an air conditioner that defines an indoor space by an outer wall body having a cavity inside and adjusts the temperature of the indoor space, and the air conditioner is in a semi-liquefied state of the refrigerant A compressor that compresses the refrigerant compressed in the compressor into a liquefied state, an evaporator that vaporizes the refrigerant condensed in the condenser, and the evaporator sucked from the room In an air conditioning structure of a building constituted by a blower that allows air to pass through and blows into the room, an air suction port and a discharge port, and the blower and the evaporator are provided above the outer wall body. A temperature control unit, the outer wall body is attached with the compressor, the temperature control unit is provided below the outer wall body, the condenser is installed in the outer wall body, The outer wall body includes the outer wall body. Passing, it established a suction opening of indoor air, characterized in that installed ventilation fan to the suction port.

  According to a second aspect of the present invention, in the air-conditioning structure for a building structure according to the first aspect, the outer wall body has a discharge port for discharging the air in the indoor space sucked by the ventilation fan to the outside and the outside air. In addition, a ventilating portion having a suction port for sucking air into the indoor space is provided, a suction fan is attached in the vicinity of the suction port, and the ventilation portion includes a heat exchanging portion.

  According to the first aspect of the present invention, the air conditioner includes the air conditioner that defines the indoor space by adjusting the temperature of the indoor space by the outer wall body having a cavity inside, and the air conditioner compresses the refrigerant into a semi-liquefied state. A compressor, a condenser that condenses the refrigerant compressed by the compressor into a liquefied state, an evaporator that vaporizes the refrigerant condensed by the condenser, and air that is sucked from the room through the evaporator, In the air conditioning structure of a building composed of a blower for blowing air indoors, the upper part of the outer wall body is provided with a temperature adjusting unit provided with an air suction port and a discharge port, a blower and an evaporator, and the outer wall body has A compressor is installed and a temperature control unit is provided below the outer wall body, a condenser is installed in the outer wall body, and the outer wall body communicates with the outer wall body. And a ventilation fan at the suction port Since, omitting the space of the outdoor unit installation, by eliminating the need for piping connecting the outdoor unit, while preventing heat loss of the refrigerant, the number of parts can be reduced. In addition, since the outdoor unit is abolished, the distance between the evaporator and the compressor can be shortened and the compressor can be installed on the outer wall body, so that the compressor can be miniaturized.

  According to the second aspect of the present invention, the outer wall body is provided with a ventilation portion formed with a discharge port for discharging the air in the indoor space sucked by the ventilation fan to the outside and a suction port for sucking the outside air into the indoor space. At the same time, a suction fan is installed near the suction port, and the ventilation section is equipped with a heat exchanging section.Therefore, when the indoor cooled air is discharged to the outside through the outer wall body, a condenser installed on the outer wall body is used. By guiding and using the cooling air for the refrigerant in the condenser, the refrigerant in the condenser can be efficiently cooled without requiring a separate condenser fan as in the prior art. Therefore, it is possible to provide an energy-saving and highly efficient air-conditioning structure for a building structure. In addition, the water vapor generated when the condensed water generated by the evaporator is dropped on the refrigerant passage piping surface of the condenser to efficiently cool the refrigerant in the pipe can be effectively discharged outward from the discharge port. Water vapor from condensed water does not adversely affect the air conditioner in the outer wall. Furthermore, when taking in high-temperature outside air for ventilation of the air in the indoor space, it is possible to take in outside air that has been cooled to some extent by heat exchange with the indoor cooling air, and cool the room without reducing cooling efficiency. Can do. Therefore, it is possible to provide an energy-saving and highly efficient air-conditioning structure for a building structure.

It is a side surface schematic diagram of the air-conditioning structure of a building structure which shows an example of this invention. It is a perspective view from the indoor side which illustrates attachment of an air conditioner. It is a perspective view of the outer wall body which illustrates one side consisting of an outer wall body and a panel. It is a side surface enlarged schematic diagram of the air-conditioning structure of a building structure which shows an example of this invention. It is a perspective view of an evaporator, a condenser, a compressor, and a drain pan. It is a perspective view of an evaporator, a condenser, and a drain pan. It is a side surface schematic diagram which shows the other structural example of an air conditioner. It is a perspective view which shows the structural example of a heat exchange part. It is a perspective view of a condenser upper drain pan.

  Hereinafter, the best mode for carrying out the present invention will be described in detail with reference to the drawings. FIG. 1 is a schematic side view of an air conditioning structure of a building structure, showing an example of the present invention, FIG. 2 is a perspective view from the indoor side illustrating the mounting of an air conditioner, and FIG. 3 is a side view including an outer wall body and a panel. 4 is a perspective view of the side wall of the air conditioning structure of a building structure, FIG. 5 is a perspective view of an evaporator, a condenser, a compressor, and a drain pan, and FIG. FIG. 7 is a schematic side view showing another configuration example of the air conditioner, FIG. 8 is a perspective view showing a configuration example of the heat exchange unit, and FIG. 9 is a perspective view of the upper drain pan of the condenser. FIG.

  The building structure includes a detached house, an apartment house, an office, a warehouse, etc. (not limited) made of wood or reinforcing steel. The air-conditioning structure of the building structure is, for example, as shown in FIG. The indoor side wall 6 and the outdoor side wall 7 define the indoor space 3 by the outer wall body 2 having a cavity inside, and the air conditioner 1 for adjusting the temperature of the indoor space 3 is provided. Further, the indoor side wall 6 and the outdoor side wall 7 are raised from the ground 5 by using pillars or beams, and have a ceiling 8 formed on the upper indoor side of the wall to define a closed indoor space 3. doing.

  As shown in FIGS. 1 to 4, the outer wall 2 is provided with a ventilation suction port 29 on the indoor side wall 6 and an exhaust discharge port 34 on the outdoor side wall 7 for discharging air from the indoor 3 to the outdoor 4. The indoor fan can be discharged through the cavity inside the outer wall body 2 by the ventilation fan 31 in front of the ventilation suction port. Further, an intake suction port 35 for sucking air from the outdoor 4 to the room 3 is provided on the outdoor side wall 7, and an intake discharge port 36 is provided on the indoor side wall 6. They are connected by a ventilation duct 38. A ventilation unit 39 is configured by the ventilation suction port 29, the exhaust discharge port 34, the ventilation fan 31, the intake discharge port 36, and the like. Such a configuration allows ventilation of room air. A fan may be installed in front of the intake / exhaust port 36 to suck outdoor air, so that indoor air can be discharged through the internal cavity of the outer wall body 2 and outdoor air can be taken into the room. For example, the structure of the ventilation part 39 which ventilates room air is not limited to the above, It can design arbitrarily.

  As shown in FIG. 1, the air conditioner 1 includes an indoor side wall 6 of the outer wall body 2, an air conditioning unit 10 attached to the inner space of the outer wall body 2, and a compressor unit 11 attached to the outdoor side wall 7.

  The air conditioning unit 10 includes a blower 13, a duct 14, an evaporator 15, an evaporator lower drain pan 16, a condenser upper drain pan 18, a condenser 17 and a condenser lower drain pan 19 in order from the top. The air blower 13, the duct 14, and the evaporator 15 in the air conditioning case 12 can be integrally attached to the indoor side wall 6 with a fastener such as a bolt, and the drain pan 18 on the condenser 17, the condenser 17 and the condenser 17 are condensed. The drain pan 19 at the lower part of the vessel 17 can be attached to the internal space of the outer wall body 2 with a fastener such as a bolt, and the air conditioning units 10 are arranged in tandem. If the air conditioning unit 10 has a thin shape so that the condensed water generated from the evaporator 15 can flow to the lower condenser 17 and is installed in the internal space of the outer wall body 2, the air conditioner 1 can be used. The order of installation of each device to be configured is not limited to the above, and can be arbitrarily designed.

  The blower 13 is attached to the indoor side wall 6 side of the discharge port 23, sucks the air in the indoor space 3 through the suction port 22, guides the inside of the duct 14 toward the evaporator 15, and discharges the air from the evaporator 15. 23 is blown out into the indoor space 3 through a well-known cross-flow type. Note that the blower 13 is internally provided in the duct 14.

  Next, the evaporator 15 installed in the lower part of the duct 14 and on the indoor side wall 6 side of the discharge port 23 is a well-known one that evaporates the refrigerant condensed in the condenser 17 as shown in FIG. The refrigerant passage pipe 15a is arranged in a meandering manner in the case of the evaporator 15, for example (not limited), and the air passing through the duct 14 contacts the passage pipe 15a of the evaporator 15 as described above. In doing so, the air is cooled by removing heat from the air as the refrigerant evaporates. The evaporator 15 is installed in the duct 14.

  Next, the drain pan 16 below the evaporator 15 installed below the evaporator 15 is larger than the width of the evaporator 15 and is connected via a drain 20 to a drain pan 18 installed above the condenser 17. Reference numeral 18 denotes a rectangular parallelepiped stainless steel container having a width substantially equal to the width of the condenser and having a top surface opened and a plurality of holes h formed on the bottom surface as shown in FIG. The condensed water generated from the evaporator 15 is dropped on the lower condenser 17.

  The condenser 17 installed below the drain pan 18 is a well-known condenser that condenses the refrigerant compressed by the compressor unit 11 into a liquefied state. In the condenser 17 of the present invention, the condenser 17 is connected to the outer wall body 2. It can be made into a long shape in the up-down direction. For this reason, it becomes possible to meanderly arrange | position the refrigerant | coolant passage pipe | tube 17a in the up-down direction 1 row in the case of the condenser 17, and the size of the condenser 17 can be made small by reducing the size of the depth of the condenser 17. It is a thing.

  The drain pan 19 installed below the condenser 17 is a rectangular parallelepiped stainless steel container having a width substantially equal to the width of the condenser 17 and having a top surface opened. The drain pan 19 is dropped from the condenser 17 directly above. To collect condensed water.

  Next, the compressor unit 11 includes a compressor 24 that compresses the refrigerant into a semi-liquefied state and a receiver 27 that removes moisture and impurities in the refrigerant. The compressor unit 11 is provided on the outdoor wall 7 via a stay 28 and the like. It can be attached with fasteners such as bolts. It is not limited to the above as long as it is fixed so as not to come off due to vibration, and absorbs the operation sound and vibration of the compressor unit, and can be arbitrarily designed. For example, it is installation in the internal space of the outer wall body 2 or the space above the ceiling.

  The compressor 24 is connected to the passage pipe 17a of the condenser 17 via the receiver 27 by a pipe 25, and the passage pipe 17a of the condenser 17 is connected to the passage pipe 15a of the evaporator 15, and this passage The pipe 15 a is connected to the pipe 26 of the compressor 24.

  Furthermore, in the air conditioning unit 10 of the present invention, a drain 21 that drains condensed water from the drain pan 19 to the outside is connected.

  In addition, a removable outdoor panel 9 is installed on the outdoor wall 7 so as to cover the air conditioning unit 10 installed in the outer wall 2.

  With this configuration, the air conditioning unit 10 can be easily attached to the outer wall body 2 and the degree of freedom of the air conditioning unit 10 installation position on the outer wall body 2 can be increased. In particular, most of the devices constituting the air conditioning unit 10 are provided in the internal space of the outer wall body 2, and by installing the removable outdoor panel 9 on the outdoor wall 7, the air conditioner maintenance of the air conditioning unit 10 is performed. For example, the work can be easily performed. Therefore, it is possible to provide an air conditioning structure for a building structure with improved assemblability and maintainability. The detachable panel may be set on the indoor side wall 6 or on both sides of the outdoor side wall 7 and the indoor side wall 6.

  Here, when the indoor warm air is cooled (temperature adjustment), as shown in FIGS. 4 to 5, the air blower 13 sucks the air in the room 3 through the suction port 22 and the inside of the duct 14. The air is guided toward the evaporator 15, and this air is brought into contact with the passage pipe 15 a of the evaporator 15. In the evaporator 15, when the condensed liquid refrigerant flowing through the passage pipe 15 a is vaporized, the air passed by the latent heat of vaporization of the refrigerant is cooled, and the cooled air is blown indoors through the discharge port 23 by the blower 13. Returned to 3.

  At this time, in the passage pipe 15a of the evaporator 15, condensed water is generated as the liquid refrigerant is vaporized. Therefore, the condensed water dripped from the passage pipe 15a is collected in a drain pan 16 installed below the evaporator 15. Is done.

  On the other hand, the refrigerant evaporated in the evaporator 15 is introduced into the compressor 24 through the pipe 26 and is compressed by the compressor 24 to be in a high-temperature and high-pressure semi-liquid state, and the condenser is connected through the receiver 27 and the pipe 25. 17 is introduced.

  In the condenser 17, as shown in FIG. 9, it flows in the passage pipe 17a by the dew condensation water that is uniformly dispersed and dropped in the length direction of the passage pipe 17a from a plurality of holes h formed over the entire bottom of the upper drain pan 18. The above-described semi-liquid refrigerant is cooled, and further liquefaction of the refrigerant proceeds, and this liquid refrigerant is introduced into the evaporator 15 through the passage pipe 15a.

  In the air conditioning structure of the present application, the above-mentioned condensed water is used for cooling the refrigerant in the passage pipe 17a in the condenser 17, and the air in the indoor space 3 sucked into the outer wall body 2 by the ventilation fan 31 is also used. . As shown in FIG. 4, the air in the indoor space 3 sucked into the outer wall body 2 through the ventilation filter 32 detachable by the ventilation fan 31 blows into the condenser 17. By bringing the water into contact with the passage pipe 17a together with the dew condensation water, the refrigerant in the passage pipe 17a can be cooled more efficiently. The ventilation filter may be installed on the front surface of the ventilation fan 31 or around the side surface of the condenser 17.

  Therefore, it is not necessary to install a condenser fan on the front surface of the condenser 17 as in the prior art, the number of parts can be reduced, and the condenser can be made thin as described above, and the outer wall 2 of the condenser 17 can be reduced. Installation in the internal space is possible.

  Condensed water dropped on the passage pipe 17a of the condenser 17 and cooling the refrigerant in the passage pipe 17a is further dropped downward and collected in the drain pan 19, and these condensed water is collected in the drain pan. Drained from the interior 19 to the outdoor 4 via the drain 21.

  With such a configuration, the dew condensation water generated in the evaporator 15 is dropped on the surface of the refrigerant passage tube of the condenser 17 located below the evaporator 15 via the drain pan 18 to be inside the passage tube 17a. It is possible to efficiently cool the refrigerant.

  In the above-described example, the condensed water collected in the drain pan 19 is drained to the outdoor 4 via the drain 21. These condensed water is connected to the drain pan 18 from the drain pan 19 by a pump (not shown). You may circulate and convey in the drain pan 18 through the pipe | tube which was made.

  In addition, since a plurality of holes h are formed at the bottom of the drain pan 18, the condensed water dropped from the evaporator 15 and collected in the drain pan 16 installed below the evaporator 15 is passed through the drain pan 18. In addition, the refrigerant in the passage 17a can be uniformly dispersed and dropped in the length direction of the passage 17a to cool the refrigerant in the passage 17a efficiently.

  That is, the condensed water used for cooling the refrigerant in the condenser 17 partially evaporates and is drained from the drain pan 19 to the outdoor 4 via the drain 21, so that the amount of condensed water in the drain pan 19 is reduced. Without increasing, it is possible to prevent the dew condensation water from flowing out from the drain pan 19, to prevent the air conditioner 1 from being broken, and to prevent the corrosion of the building structure.

  Furthermore, since the condenser 17 has the passage pipes 17a arranged in one line in the vertical direction, the depth of the condenser 17 can be reduced and the condenser 17 can be attached to the internal space of the outer wall body 2, and the ventilation wall 31 can be used to attach the outer wall body 2 to the condenser 17. Thus, the air in the indoor space 3 sucked in can be surely passed through the gap between the passage pipes 17a, and the refrigerant can be efficiently cooled.

  In the above example, a plurality of holes h for dripping dew condensation water are formed at the bottom of the drain pan 18. However, the present invention is not limited to the formation of these holes h. For example, a spray nozzle (not shown) is installed. Thus, the condensed water can be evenly dispersed in the condenser 17 to efficiently cool the refrigerant in the condenser 17.

  In the above-described example, the air conditioning unit 10 is installed in the internal space of the planar outer wall 2, but the panel of the air conditioning unit 10 and the indoor side wall 6 or the panel of the outdoor side wall 7 (not shown) is not limited to this position. It can also be attached to the internal space of the outer wall 2 corner. In this case, the air blower 13, the duct 14, the evaporator 15, the drain pan 16, the condenser 17, the drain pan 18, and the drain pan 19 that constitute the air conditioning unit 10 are respectively adjusted to match the outer wall 2 corner angle (substantially right angle). Just bend. Furthermore, you may arrange | position the air-conditioning unit 10 mentioned above centering around a corner angle.

  In the above example, the compressor unit 11 is separated from the air conditioning unit 10 and installed on the outdoor side wall 7 via the stay 28 or the like. However, the compressor unit 11 is not limited to this position. For example, the compressor unit 11 is installed in a space on the ground or ceiling. Alternatively, it may be attached to the internal space of the outer wall 2 together with the air conditioning unit 10.

Next, as shown in FIG. 7, all the components of the air conditioning unit 10 can be installed on the outer wall body 2. Specifically, the blower 13, the duct 14, and the evaporator 15 may be installed in the outer wall body 2. By adopting such a configuration, the air conditioner 1 does not protrude into the indoor space 3 and the appearance of the room can be improved.

  Moreover, the structure of the air blower 13, the duct 14, the evaporator 15, the suction port 22, and the discharge port 23 in the air conditioning case 12 can also be changed. For example, in the duct, the above-described cross-flow type blower may be installed at a position slightly away from the front surface of the suction port, and an evaporator may be installed immediately below the blower and in front of the discharge port.

  In the duct, an evaporator is installed in front of the discharge port, and a blower such as an axial fan is installed in front of the evaporator. In this case, the suction port and the discharge port are vertically adjacent to each other, and in order to prevent a short circuit of room air, the suction port louver should be installed upward and the discharge port louver should be directed downward. Is preferred.

  Further, in the duct, a blower such as an axial fan may be installed on the front surface of the suction port, and an evaporator may be installed on the front surface of the air outlet.

  As shown in FIG. 4, the ventilation section 39 has a ventilation suction port 29 on the indoor side wall 6 of the outer wall body 2 above the condenser 17, and an exhaust discharge on the outdoor side wall 7 of the outer wall body 2 below the condenser 17. Although the outlets 34 are respectively installed, the position is not limited to this position as long as the air in the indoor space 3 passes through the condenser 17 and cools the refrigerant in the passage pipe 17a. A plurality of openings may be provided in a shape having openings in the vertical direction or the horizontal direction on the entire surface. The ventilation fan 31 is installed in front of the ventilation suction port 29, but may be installed in front of the exhaust discharge port 34 or on both sides. In addition, as shown in FIG. 3, a ventilation fan may be installed in front of the intake suction port 35 and / or in front of the intake discharge port 36 for sucking air from the outdoor 4 to the indoor 3. Good. Accordingly, the installation position of the ventilation unit 39 can be designed as appropriate. Further, a plurality of components of the ventilation unit 39 may be set.

  Moreover, in the air-conditioning structure of this application, the ventilation part 39 is provided with the heat exchange part 37, and when taking in high temperature outside air, air with a temperature lower than outside air is taken in into the room 3 by heat exchange with the cooled air in the room 3 It is possible to cool the room without reducing the cooling efficiency. For example, as shown in FIG. 8, the heat exchanging portion 37 has a position where an exhaust portion that exhausts air in the outer wall 2 (indoor 3) to the outdoor 4 and an intake portion that takes air in the outdoor 4 into the indoor 3 are adjacent to each other. Install in. The air in the room 3 passes through the heat exchange unit 37 from the exhaust suction port 33 and is exhausted from the exhaust discharge port 34 to the outdoor 4.

  The air in the outdoor 4 passes through the heat exchange unit 37 from the intake suction port 35 and is sucked into the room 3 from the intake discharge port 36. Since the air in the room 3 exhausted to the outdoor 4 is cooled from the air in the outdoor 4 by the air conditioner, the air in the outdoor 4 is brought into contact with the air in the room 3 by this heat exchanging unit 37 to exchange heat. After cooling, the air is taken into the room 3. Accordingly, the room can be cooled without reducing the cooling efficiency. In addition, the said heat exchange part 37 can use a static type total heat exchanger, a rotation type total heat exchanger, etc. which are well-known things.

  Even if it is the above structure, while being able to acquire the effect similar to the above-mentioned, while improving assembly property and maintainability, the air-conditioning structure of a building structure which is energy-saving and highly efficient can be provided.

  In addition, although the example which cools indoor air was demonstrated in the above-mentioned air conditioner, since this air conditioner can also warm indoor air, since it is a known technique, the description is abbreviate | omitted.

  As described above in detail, the air conditioning structure of a building structure according to the present invention defines an indoor space by the outer wall body 2 having a cavity inside, and compresses the refrigerant into a semi-liquefied state, and the compressor. The condenser 17 that condenses the refrigerant compressed in 24 into a liquefied state, the evaporator 15 that vaporizes the refrigerant condensed in the condenser 17, and the air sucked from the room 3 through the evaporator 15 3 is provided with an air conditioner 1 including a blower 13 that blows air. The air conditioner 1 adjusts the room temperature of the room 3, and the outer wall 2 has a ventilation unit 39 that exchanges the air in the room 3 and the air in the room 4. The air conditioner 1 is arranged in tandem on the outer wall body 2.

  The present invention can be applied to an air conditioning structure of any building structure including the air conditioner 1. In addition, the air-conditioning structure of this building structure is not limited to the building structure in which it resides, and may be a warehouse that stores articles, food, and the like.

DESCRIPTION OF SYMBOLS 1 Air conditioner 2 Outer wall 3 Indoor 4 Outdoor 5 Ground 6 Indoor side wall 7 Outdoor side wall 8 Ceiling 9 Outdoor side panel 10 Air conditioning unit 11 Compressor unit 12 Air conditioning case 13 Blower 14 Duct 15 Evaporator 15a Passage pipe (evaporator)
16 Drain pan (lower part of evaporator)
17 Condenser 17a Passage tube (condenser)
18 Drain pan (top of condenser)
19 Drain pan (lower part of condenser)
20 Drain 21 Drain 22 Suction port 23 Discharge port 24 Compressor 25 Piping 26 Piping 27 Receiver 28 Stay 29 Ventilation suction port 30 Ventilation discharge port 31 Ventilation fan 32 Ventilation filter 33 Exhaust suction port 34 Exhaust discharge port 35 Intake suction port 36 Intake exhaust Outlet 37 Heat exchange part 38 Ventilation duct 39 Ventilation part h hole

Claims (2)

An interior space is defined by an outer wall body having a cavity inside, and an air conditioner for adjusting the temperature of the interior space is provided,
The air conditioner includes a compressor that compresses the refrigerant into a semi-liquefied state;
A condenser for condensing the refrigerant compressed by the compressor into a liquefied state;
An evaporator for vaporizing the refrigerant condensed in the condenser;
In the air-conditioning structure of the building, which is constituted by a blower that passes the air sucked from the room through the evaporator and blows the air into the room,
The upper part of the outer wall body includes a temperature adjusting unit provided with an air suction port and a discharge port, the blower and the evaporator,
The compressor is attached to the outer wall body,
The lower wall of the outer wall body provided with the temperature adjusting unit, the condenser is installed in the outer wall body,
Further, an air conditioning structure for a building structure, wherein a suction port for indoor air communicating with the outer wall body is installed in the outer wall body, and a ventilation fan is installed in the suction port. The outer wall body is provided with a ventilation portion in which a discharge port for discharging the air in the indoor space sucked by the ventilation fan to the outside and a suction port for sucking outside air into the indoor space are formed, and in the vicinity of the suction port Attach a suction fan to the
The air-conditioning structure for a building structure according to claim 1, wherein the ventilation unit includes a heat exchange unit.

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