JP2014527151A - Built-in air conditioner - Google Patents

Abstract

A new built-in air conditioner having low cost and excellent heating and cooling effects is provided.
A built-in air conditioner includes an external heat exchanger, a four-way switching valve, a compressor, and fine pipes. The micropipe is a metal capillary, is fixed to the reinforcing bar 12, and is integrated with concrete. The micro tubes 9, 10, 11 have one end with a parallel opening connected to the opening on the right side of the four-way switching valve 3 and the other end with a parallel opening connected to the lower opening of the external heat exchanger 1 via the throttle member 5. Has been. The upper opening of the external heat exchanger 1 is connected to the left opening of the four-way switching valve 3. The common opening located at the center of the four-way switching valve 3 is connected to the return air port of the compressor 4. The inlet of the four-way switching valve 3 is connected to the outlet of the compressor. The external heat exchanger 1 is a heat exchanger using an air-cooled heat exchanger, a water-cooled heat exchanger, and a foundation pile.
[Selection] Figure 1

Description

  The present invention relates to a built-in air conditioner, and more particularly to a built-in air conditioner having a heating function and a cooling function.

Usually, the current air conditioner performs a heating or cooling function by an indoor unit. Since the specific heat of the air is small, the air conditioner transmits energy only by the convection method, the temperature difference is large, and the efficiency is low. In the hot water supply system of the air source, the minimum evaporation temperature is below 20 degrees below zero. When the condensing temperature is 50 degrees, whatever the refrigerant is used, the compression ratio is 7 or more, so it far exceeds the operating range of the current compressor and cannot be used as heating in the northern region. .
The present inventor has proposed a low-temperature heating patent using a fine water pipe or a geothermal water pipe. However, in the process of exchanging heat between air and water, a large energy loss occurs, resulting in a reduction in efficiency. Also, the total cost associated with laying the pump, heat exchanger, and capillary tube is much higher than the present invention. In winter, when use is stopped, it may break due to freezing.

JP 2000-329376 A

  The present invention has been made in view of the above problems, and an object thereof is to provide a new built-in air conditioner.

The heat radiation amount of the heating equipment is Q = SρC (S is the heat radiation area, ρ is the heat conduction coefficient, and C is the temperature). The expression for the thermal efficiency of the Carnot cycle is ε = Ta / Ta−T0 (Ta is the condensation temperature and T0 is the evaporation temperature). The present invention guarantees sufficient heating in the room by reducing the heat transfer resistance to the maximum, increasing the heat radiation area, reducing the condensation heat radiation temperature, and increasing the evaporation temperature based on the above two formulas. As a premise, the energy efficiency ratio is improved.
In the present invention, when the condensation temperature is 26 degrees, the room temperature is 18 degrees, and the surface heat dissipation of the concrete is 70 W / m ² or more, the transmission loss is small, so even if the outdoor temperature is below 20 degrees below zero, Can fulfill the function.

The present invention includes an external heat exchanger, a four-way switching valve, a compressor, and a fine pipe. The micropipe is a metal capillary, is fixed to the reinforcing bar (12), and is formed integrally with concrete. The fine tube has a parallel opening at one end connected to an opening on the right side of the four-way switching valve (3), and a parallel opening at the other end connected to a lower opening of the external heat exchanger (1) via a throttle member (5). It is connected. The upper opening of the external heat exchanger (1) is connected to the left opening of the four-way switching valve (3). The common opening located at the center of the four-way switching valve (3) is connected to the return air port of the compressor 4. The inlet of the four-way switching valve (3) is connected to the outlet of the compressor (4). The external heat exchanger is at least one of an air-cooled heat exchanger, a water-cooled heat exchanger, a heat exchanger using a foundation pile, and a solar panel heat exchanger.
Two or more compressors or compressors capable of changing the frequency are used.

  Other modes for realizing the object of the present invention are as follows. The present invention includes an external heat exchanger, a four-way switching valve, a compressor, and a fine pipe. The micropipe is a metal, PB, PERT capillary, or a carbon nanotube fiber sheet, and is laid on the top of the floor slab or attached to the wall so that a plurality of pipes are arranged in parallel. The parallel opening at one end of the ceiling microtube (9) is connected to the parallel opening at one end of the wall microtube (10) by a capillary tube (19). The solenoid valve (20) is connected in parallel to both ends of the capillary tube (19). The parallel connection opening on the other side of the wall microtube (10) is connected to the lower opening of the external heat exchanger (1) by a throttle member (5). The upper opening of the external heat exchanger (1) is connected to the left opening of the four-way switching valve (3). The opening on the right side of the four-way switching valve (3) is connected to the opening of the parallel connection on the other side of the fine tube (10) on the ceiling. The common opening located in the center of the four-way switching valve (3) is connected to the return air port of the compressor (4).

  The reinforcing rib is installed in the above-mentioned fine pipe. A heat transfer layer (16) made of at least one of cement, sand, graphite and metal powder is installed between the pipes. A one-way inorganic super heat conductive material or a heat insulating layer (15) of foamed material is placed on top of the heat transfer layer (16). The opening at one end of the water-cooled heat exchanger (17) is connected in series between the inlet of the four-way switching valve (3) and the outlet of the compressor (4). The opening on the other side of the water-cooled heat exchanger (17) is connected by a pump (18) to an indoor conduit that requires hot water.

  Other modes for realizing the object of the present invention are as follows. The present invention includes an external heat exchanger, a four-way switching valve, a compressor, a check valve, a fine pipe, a ventilation dehumidifier, and a venturi pipe. The microtubule is at least one kind of capillary tube made of metal, PB, or PERT. The micropipe is affixed to the top of the ceiling so that a plurality of pipes are arranged in parallel, or is laid on the ground. The parallel opening at one end of the micropipe is connected to the opening on the right side of the four-way switching valve (3) by a check valve (8). The left opening of the four-way switching valve (3) is connected to the upper opening of the external heat exchanger (1). The lower opening of the external heat exchanger 1 is connected to a plurality of parallel connection openings on the other side of the micropipe by a throttle member. The common opening located in the center of the four-way switching valve (3) is connected to the return air port of the compressor (4). The inlet of the four-way switching valve (3) is connected to the outlet of the compressor (4). Both ends of the check valve (8) are connected in parallel to the ventilation dehumidifier (28). The venturi pipe (31) is installed on the outlet side of the check valve (8) connected to the ventilation dehumidifier (28).

  Other modes for realizing the object of the present invention are as follows. The present invention includes a heat exchanger using a foundation pile, a four-way switching valve, and a compression expander. The heat exchanger (32) using the foundation pile is formed by flowing concrete in a state where the fine pipe is fixed to the reinforcing bar (12), or formed by flowing concrete into the microporous reinforcing bar. ing. The opening at one end of the heat exchanger (32) using the foundation pile is connected to the opening on the left side of the four-way switching valve (3). The opening on the other side of the heat exchanger (32) using the foundation pile is connected to the parallel opening at one end of the fine pipe (9) of the floor slab by the compression expander (33). The opening on the right side of the four-way switching valve (3) is connected to the parallel opening at the other end of the fine pipe (9) of the floor slab. The common opening located in the center of the four-way switching valve (3) is connected to the return air port of the compression / expansion machine (33). The inlet of the four-way switching valve (3) is connected to the outlet of the compression expander (33).

  Other modes for realizing the object of the present invention are as follows. The present invention includes an external heat exchanger and a compressor. The fine pipe fixed to the reinforcing bar (12) or the microporous reinforcing bar instead of the reinforcing bar is integrated with the concrete. The parallel opening at one end of the micropipe or the microporous reinforcing bar is connected to the opening at one end of the compressor. The plurality of parallel connection openings on the other side of the micropipe or the microporous reinforcing bar are connected to the lower opening of the external heat exchanger (1) by the throttle member (5). The upper opening of the external heat exchanger (1) is connected to the opening on the other side of the compressor. The external heat exchanger (1) is at least one of an air-cooled heat exchanger, a water-cooled heat exchanger, a heat exchanger using a foundation pile, and a solar panel heat exchanger.

  Other modes for realizing the object of the present invention are as follows. The present invention includes an external heat exchanger, a four-way switching valve, a compressor, and a microporous reinforcing bar. The microporous reinforcing bar is formed into a mesh-like flow path heat exchanger by welding, and is integrated with the concrete by flowing in the concrete. The parallel opening at one end of the microporous reinforcing bar is connected to the opening on the right side of the four-way switching valve (3). The plurality of parallel connection openings on the other side of the microporous reinforcing bar are connected to the lower opening of the external heat exchanger (1) by a throttle member (5). The upper opening of the external heat exchanger (1) is connected to the left opening of the four-way switching valve (3). The common opening located in the center of the four-way switching valve (3) is connected to the return air port of the compressor (4). The inlet of the four-way switching valve (3) is connected to the outlet of the compressor (4).

  Other modes for realizing the object of the present invention are as follows. The present invention includes an external heat exchanger, a four-way switching valve, a compressor, and a metal radiation plate. Two relatively disposed metal radiating plates have relative concave grooves or draft tubes. The metal radiation plate is integrated by heat pressure and is laid on the ground or attached to a wall and a ceiling. The inlet of the metal radiation plate is connected to the left opening of the four-way switching valve (3). The outlet of the metal radiation plate is connected to the lower opening of the external heat exchanger (1) by a throttle member (5). The upper opening of the external heat exchanger (1) is connected to the right opening of the four-way switching valve (3). The inlet of the four-way switching valve (3) is connected to the outlet of the compressor (4). The common opening located in the center of the four-way switching valve (3) is connected to the return air port of the compressor (4). The external heat exchanger is a kind of heat exchanger using at least an air-cooled heat exchanger, a water-cooled heat exchanger, and a foundation pile.

  Other modes for realizing the object of the present invention are as follows. The present invention includes an external heat exchanger, a four-way switching valve, a compressor, and a fine pipe. The microtubule is at least a kind of metal capillary, PERT, or PB capillary. The micropipe is affixed to the ceiling such that a plurality of pipes are arranged in parallel, or is laid on the ground. The parallel opening at one end of the micropipe is connected to the opening on the right side of the four-way switching valve (3). The left opening of the four-way switching valve (3) is connected to the upper opening of the external heat exchanger 1. The lower opening of the external heat exchanger (1) is connected by a throttle member (5) to a plurality of parallel connection openings on the other side of the micropipe. The common opening located in the center of the four-way switching valve (3) is connected to the return air port of the compressor (4). The inlet of the four-way switching valve (3) is connected to the outlet of the compressor (4).

The advantages of the present invention are as follows.
1. In the present invention, the condensation micropipe is integrated with concrete, and heat is radiated or cooled by utilizing the heat transfer coefficient of concrete which is 60 times that of air and the area of the building body. Since the heat transfer resistance is small between the main engine and the heat radiating end, and the design has a low volume ratio, the current air conditioner technology can fully function.
2. Stainless steel or carbon steel has high tensile strength and can be laid closely. Moreover, a part of reinforcing bars can be substituted, and the strength of the building body can be increased.
3. The cost per unit area is low and lower than the cost of heating facilities and air conditioners under current living conditions. Further, since there are no moving parts such as a fan and a pump at the heat radiating end, the life is long, there is no noise, and no maintenance is required.
4). The present invention has low carbon dioxide emissions and low costs for heating and cooling. In the Beijing region, the average energy efficiency ratio during the heating period is 4.5 or more, which corresponds to saving two thirds of the heating cost. In addition, it is possible to save 70% of the electricity bill for summer air conditioners.
5. In the present invention, a steel fine tube having a wall thickness of 0.6 mm and an outer diameter of 2.4 mm is used, so that it can withstand a pressure of 30 MPa, and the strength is further enhanced by an integral structure with concrete. The present invention is not only capable of using environmentally friendly refrigerants at normal and high pressures, but also can be directly connected to the carbon dioxide unit and is highly efficient.
6). The present invention has already been used in buildings. Not only steel fine tubes, but also copper tubes, aluminum tubes, PB, PE, and carbon nanotube fiber sheets can be used. The production process is simple, the cost is low, and the construction is environmentally friendly. Also, when the water-cooled capillary tube stops heating, there is no disadvantage that freezes and breaks.
7). The present invention not only increases the strength by wrapping the fine pipe in the foundation pile of the building body, but can utilize the enormous energy accumulated in the soil. It can be used for summer cooling and has the same life as a building. When connected to the air-cooled coil tube in series or in parallel in the room, it can be heated quickly in winter, dehumidified in summer, and can be cooled quickly.
8). In the present invention, one home may use one or two small units, or all buildings may use one or two large air-cooled heat pump units with variable capacity. The present invention is correctly laid and can operate smoothly without failure for more than a decade when connected to an existing unit with variable frequency and capacity as long as there is no leakage.
9. In the present invention, one internal switching compressor is configured. The present invention allows the maximum efficiency of the configuration to be reached by cooling, heating and bi-directional flow of the two openings, eliminating the existing four-way switching valve, reducing failure and reducing heat loss. Can do.
10. A microhole is formed in an existing reinforcing bar, a net is formed by welding, integrated with concrete, and an access opening is connected to an outdoor unit. Thereby, it has reliability and durability, and can reduce cost more.

It is a schematic diagram which shows the built-in air conditioner by 1st embodiment of this invention. It is a top view which shows the connection and welding of the built-in air conditioner by 1st embodiment of this invention. A is a U-type connection, B is a saddle type connection, and C is a connection of a rebar fine tube winding type. It is a schematic diagram which shows the domestic hot water and plate type dehumidification heater of the built-in air conditioner by 2nd embodiment of this invention. It is sectional drawing which shows the metal radiation plate and porous microtubule of the built-in air conditioner by 2nd embodiment of this invention. A is a cross-sectional view of a fine tube having a reinforcing rib, B, C, and D are cross-sectional views of a metal radiation plate, and E is a metal fine tube having a wing-like piece. It is a schematic diagram which shows installation of the carbon nanotube fiber end of the built-in air conditioner by 3rd embodiment of this invention. It is a schematic diagram which shows the system of the air-cooling dehumidifier of the built-in air conditioner by 4th embodiment of this invention. It is a schematic diagram which shows the foundation pile heat exchange carbon dioxide unit of the built-in air conditioner by 5th embodiment of this invention. It is a schematic diagram which shows the positive / reverse switching unit inside the compressor of the built-in air conditioner by 6th embodiment of this invention.

(First embodiment)
As shown in FIG. 1, in a single plate-type building having a width of 16 m, the wall thickness is 0.6 mm, the outer diameter is 2.4 mm, and it can withstand a pressure of 30 MPa. The length of the book is 30 m, and a fine tube 9 with a ceiling of 8 cm is used. Both ends of the fine tube 9 on the ceiling are welded to the guide tube and are folded to 15 m. A pipe network with a pipe distance of 4 cm is formed by fixing the intermediate part with a clip.

As shown in FIG. 2-A (the planar method of FIGS. 2-B and C may be adopted), the fine tube is laid on the site, fixed to the reinforcing bar 12, and poured into the concrete to be integrated with the concrete. Become. On a 100 m ² floor slab, a 2500 meter fine tube is laid. The heat exchange surface area is 18.8 m ² , the total cross sectional area is 2 cm ² and the internal volume is 2.8 L. An outdoor unit in which the digital frequency of carbon dioxide 3.5 to 10 kw is variable is adopted. When connected to an outdoor unit using an R410 type refrigerant, pressure can be withstood if the length of the pipe is 5 to 30 m and the wall thickness is 0.3 to 0.5 mm. When used as heating, the value of the evaporation temperature is set about 2-3 degrees lower than the outdoor temperature on average. The condensation temperature is 24 to 30 degrees depending on the indoor heat load. The heat exchanger 1 of the outdoor unit is attached so as to face sunlight. When it is not cold, when heating is used, it can operate at half the efficiency by using a half-night electricity charge. Since the external heat exchanger 1 has a small temperature difference, it does not form frost. At the coldest time, it accumulates heat as efficiently as possible in the daytime when sunlight is sufficient and the temperature is highest. At this time, since the humidity of the air is very low and the evaporative heat exchange temperature difference is small, it is usually possible to defrost without using electricity. Since the volume ratio of all the fine tubes is smaller than that of the conventional air conditioner having the same power, the refrigerant has a higher flow rate and better circulation. Moreover, the heat transfer coefficient of reinforced concrete is 1.74 w / m ° C., and the room temperature usually varies between 19 and 21 degrees. Because the main heat dissipation form is infrared, the body feel is very comfortable.

In the coldest conditions in the north region of China, the daytime temperature is higher than 15 degrees below zero and the condensation temperature is 26 degrees. When the room temperature is 20 degrees and the ground surface temperature is 24 degrees, the heat radiation of only the ground floor slab 13 reaches 45 w / m ² , and the amount of heat radiated downward by the upper floor slab 13 reaches 40 w / m ² . Since the actual COP is about 4.0, the unit can supply the heat needed for one day after 12 hours of operation and does not require operation at lower temperatures at night. Winter heating costs and carbon dioxide emissions are one third of traditional intensive heating. When the output pressure of the compressor is reduced to 30 degrees or less, the noise can be reduced by 30%.

  When cooling in summer, if the evaporation temperature in the wall microtube 10 is 15-20 degrees, the floor slab 13 is cooled to 23 degrees and the room temperature is lower than 26 degrees. Since the cold storage amount of reinforced concrete is very large, the outdoor unit 7 may operate at midnight. Since the air temperature in this time zone is the lowest during the day, the compressor 4 has a sufficient cooling effect even when operating at half the load. The actual energy efficiency ratio reaches 8.0. Moreover, since the electricity charge is half price, the electricity charge when adopting the present invention is 1/6 of the electricity charge when using a conventional air conditioner. When cooling on a summer night, the temperature in the north region is about 20 degrees, so the external heat exchanger 1 can perform sufficient exhaust heat when the condensation evaporation temperature is 30 degrees. When the evaporation temperature is 12 ° C. or higher, the output power of the compressor 4 is increased by a factor of approximately 1. Therefore, when operating at a single machine or at a power of 50%, the output power is the same as that of a conventional air conditioner. This corresponds to the output power when.

  In order to use the present reinforcing bar 12 in place of the fine pipe, it is processed so as to have a microhole inside, and is directly welded and integrally formed with concrete as shown in FIG. This rebar has a higher pressure to withstand and a larger surface area. Since the surface area of the reinforcing bar 12 is much larger than that of the fine pipe, the surface area of the reinforcing bar 12 of one building is surprisingly large. When a 1.2 mm hole is formed in the reinforcing bar 12 having an outer diameter of 25 mm, the wall thickness is 14 mm, it can withstand a pressure of several hundred MPa, and a supercritical carbon dioxide unit can be arranged. This reinforcing bar is hard to be clogged and leaked by welding, and the change in temperature difference is very small. By increasing the number, the strength of the building can be increased. As shown in FIG. 7, the connection method and the operating principle are the same as in FIG.

In the northern region, where heating is the main function, it is better to lay a large area and densely on the ground, ceiling, or wall of the room in order to increase the heat radiation.
In regions surrounded by the sea, air humidity is high, so it is better to perform dehumidification and ventilation dehumidification.
In hot regions, a combination of laying on ceilings and floor slabs and indoor air cooling is recommended.

(Second embodiment)
As shown in FIGS. 3 and 4, a plurality of micro tubes having an inner diameter of PERT or PB of 0.5 to 1 mm, a wall thickness of 1 to 1.5 mm, and a pipe distance of 2 to 3 mm are arranged in parallel. Welded to the connection. The microtubules are affixed with cement gel below the floor slab or perpendicular to the wall surface. A water tank 23 is installed underneath, and cement, sand and graphite are laid on the ground.

  Since this micro tube has a low pressure that can be tolerated, it is applied to a unit that uses a medium or low pressure refrigerant such as R22, R134A, or R404. In the summer, when storing cold, the pressure may be controlled step by step. The electromagnetic valve 20 is closed, the throttle member 5 is adjusted, and the cooling evaporation temperature of the wall surface pipe line 22 is varied between 22 and 27 degrees. Therefore, dew condensation is avoided and a constant indoor temperature is maintained. The evaporation (pressure) temperature of the fine tube 9 on the ceiling is about 15 degrees, which corresponds to the maximum return air pressure of the current compressor. Since the floor slab 13 is very thick, there is no condensation within normal working hours. When the surface temperature reaches 22 degrees, the cold storage amount reaches 40 kW. The effect is very good because it cools at night and uses it in the daytime. The solenoid valve 20 can be opened at night to increase the required amount of cold in the room. When the evaporation temperature of the surface duct 22 on the wall is 7 to 15 degrees, the room can be dehumidified and immediately cooled by condensation. The condensed water is guided to the outside by the water tank 23.

  A sleeve tube or a plate heat exchanger 17 surrounding the compressor 4 is connected in series to the outlet of the compressor 4. Therefore, noise is reduced, space is saved, and hot water for daily use can be made using waste heat from the cooling process.

  By adopting a cross-sectional structure as shown in FIG. 4-A, this microtube increases the surface heat radiation area, improves the pressure resistance capability, and reduces the volume ratio of all systems.

The maximum temperature that this microtube can withstand is only 100 degrees. In winter, when functioning as heating, the temperature of the gas output from the compressor 4 is 80 degrees. Since the sleeve tube or the plate heat exchanger 17 and the pump 18 absorb this waste heat, the water becomes hot water, and the heat radiation temperature of the fine tube 9 on the ceiling becomes lower than 30 degrees. Therefore, the requirements for heat dissipation and pressure resistance are satisfied.
By using the surface pipe line 22 attached perpendicularly to the wall as the end of heat dissipation, the efficiency is improved and it is advantageous for circulation.

As shown in FIG. 4-C, the micropipe is affixed to a metal plate and is used as a heat exchanger for suspended ceilings and walls. As shown in FIG. 4-E, the metal micropipe is in the shape of a wing-shaped piece, and the heat dissipation effect is even better.
The two aluminum plates are formed with concave grooves by pressing or etching, and are integrated by hot pressing to form a metal radiation plate. As shown in FIGS. 4B and 4D, very thin ripples or rhombus-shaped channels are formed, and the surface is subjected to craft processing. Thus, a building having cooling, heating, and decoration functions is formed. A metal radiation board may be affixed on a wall and may be laid on the ground or a ceiling.

(Third embodiment)
As shown in FIG. 5, a carbon nanotube fiber sheet 26 is used, and plastic guide tubes 24 such as PB, PP, or PE are installed at both ends in the vertical direction. The carbon nanotube fiber sheet 26 is affixed to the ground, ceiling, or wall of the completed building with a high-strength heat transfer adhesive 25. Therefore, a reinforcing adhesive layer is formed. The guide tube 24 is connected to the outdoor unit 7.
Based on the pressure receiving formula (ρ = 2 × wall thickness × (tensile strength / 2) / diameter), the carbon fiber tube having a wall thickness of 30 μm and an inner diameter of 20 μm can withstand a pressure of 10 MPa or more. I understand that. The surface area around the sheet conduit may be greater than the laying area. Carbon conduits also have excellent thermal conductivity. The single sheet laying thickness is less than 2 mm. Even if individual parts are broken, they are sealed with the high-strength heat transfer adhesive 25. The flow cross-sectional area is larger than the outlet of the compressor 4. Since the internal volume is small, the effect of heating and cooling is very high.

(Fourth embodiment)
As shown in FIG. 6, the micropipe is at least one kind of metal capillary, PERT, or PB capillary. The micropipe is affixed to the ceiling such that a plurality of pipes are arranged in parallel, or is laid on the ground. The parallel opening at one end of the micropipe is connected to the opening on the right side of the four-way switching valve 3 by a check valve 8. The left opening of the four-way switching valve 3 is connected to the upper opening of the external heat exchanger 1. The lower opening of the external heat exchanger 1 is connected to the other plurality of parallel openings of the micropipe by a throttle member. The common opening located at the center of the four-way switching valve 3 is connected to the return air port of the compressor 4. The inlet of the four-way switching valve 3 is connected to the outlet of the compressor 4. Both ends of the check valve 8 are connected to the ventilating dehumidifier 28 in parallel. The venturi pipe 31 is installed on the side where the ventilator / dehumidifier 28 is connected to the outlet of the check valve 8.

  In this embodiment, the micropipe is directly laid on the ground. The ground is flattened with graphite, sand and cement. The micropipe is affixed to the ceiling with a heat conductive adhesive. The fine tubes on the ground and the ceiling are connected in parallel, and are connected to the four-way switching valve 3 by an air-cooling heat exchanger. Since the heat transfer coefficient of graphite is higher than that of ordinary metal, when the refrigerant flows directly into the fine pipe through the check valve 8 during heating, the temperature of the ground corresponds to the condensation temperature of the fine pipe. Therefore, the heat radiation end reaches the maximum efficiency. Moreover, since the heat | fever of the compressed gas is utilized and the wind which flowed in into the room from the outdoor is heated, indoor air becomes fresh.

  When the check valve is closed during operation in summer, the refrigerant flows into the air-cooled heat exchanger 28 mainly via the venturi pipe 31. The refrigerant can be dehumidified indoors when the evaporation temperature is 10 degrees or less. Since the evaporation temperature in the micropipe is about 20 degrees, the temperature of the refrigerant slowly decreases to prevent condensation. Further, the temperature can be quickly lowered by the air cooling heat exchanger 28.

(Fifth embodiment)
In order to provide heavy-duty heating and cooling on the first and second floors of the building instead of the air-cooling heat exchanger of the outdoor unit 7 at the stage of building the foundation, a plurality of stainless steel or carbon steel micro tubes are used. The pipes are connected in parallel, fixed to the reinforcing bars of the foundation pile, and integrated with concrete by casting. As shown in FIG. 7, when the outer wall is thick, the diameter is thick, and the strength is high, the microtube can directly replace the reinforcing bar 12. Total cost is lower than air-cooled heat exchanger. Evaporation temperature is high in winter, condensation temperature is low in summer, and there is no fan that consumes electricity, so that not only heating and cooling performance is improved, but noise of the outdoor unit 7 is reduced, life and reliability Will increase. When functioning as heating, a heat insulating layer 27 of foam material may be laid before casting the floor slab 13.

(Sixth embodiment)
Since the compressor of the conventional air conditioner has a high output pressure, the maximum function cannot be exhibited particularly when performing a cooling function in summer. The four-way switching valve is prone to failure when used for a long period of time, and the efficiency of the internal cold heat exchange becomes low.

  In the compressor 4 of the present invention, the middle portion is a motor, the right end is a heat pump working space, and the left end is a cooling working space. When the motor rotates in the forward direction, the compressor is operated with the left end directly connected and the right end compressed. When the motor rotates in the reverse direction, the compressor is operated by compressing the working space for cooling at the left end, so that the right end is directly connected. As shown in FIG. 8, for example, the above function is realized by using a scroll compressor to function as a heat pump on the right side by removing the rotor and cooling the left side by forward / reverse rotation of the fan. be able to.

An optimal compression ratio is set according to different requirements for cooling and heating. By setting the condensing pressure on the cooling side to a value corresponding to 30 degrees and the evaporating side to a value corresponding to 20 degrees, the compression ratio becomes smaller than 1. The energy efficiency ratio can reach 15 or more.
By setting the condensation pressure on the heat pump side to a value corresponding to 25 to 30 degrees and setting the evaporation side to a value corresponding to -10 degrees ± 15 degrees, the compression ratio is greater than 3, and the energy efficiency ratio is 4 to 6

Since the case is made of aluminum, the noise is reduced to the maximum.
In both the cooling operation and the heat pump operation, the operation and the end evaporation of the refrigerant are radiated by a motor. Therefore, since the four-way switching valve is removed, the operation reliability is high and the failure rate is low.
As described above, the object of the present invention can be achieved.

1 ... External heat exchanger,
2 ... Fan,
3 ... Four-way switching valve,
4 ... Compressor,
5 ... Throttle member,
6 ... Connection valve,
7… Outdoor unit,
8 ... Check valve,
9 ... micro tube on the ceiling 10 ... micro tube on the wall,
11 ... fine tubes,
12 ... rebar,
13 ... Floor slab,
14 ... floor mat or floor tile,
15 ... One-way inorganic super heat conduction material,
16 ... heat transfer layer,
17 ... Plate heat exchanger,
18 ... pump,
19 ... capillaries,
20 ... Solenoid valve,
21 ... Wall insulation board,
22: Wall surface pipe line,
23 ... aquarium,
24 ... guide tube,
25. High strength heat transfer adhesive,
26 ... carbon nanotube fiber sheet,
27 ... heat insulation layer,
28 ... Air-cooled heat exchanger,
29 ... Windscreen,
30 ... Fan,
31 ... Venturi tube,
32 ... Heat exchanger using foundation pile,
33. Compression expansion machine,
34: Microporous reinforcing bar.

Claims (10)

An external heat exchanger (1), a four-way switching valve (3), a compressor (4), and a fine pipe (11),
The micropipe is a metal capillary, is fixed to the reinforcing bar (12) and is integrally formed with concrete, and has a parallel opening at one end connected to an opening on the right side of the four-way switching valve, and a parallel opening at the other end. Is connected to the lower opening of the external heat exchanger via a throttle member (5),
The external heat exchanger has an upper opening connected to the left opening of the four-way switching valve,
In the four-way switching valve, a common opening located in the center is connected to a return air port of the compressor,
The four-way switching valve has an inlet connected to an outlet of the compressor;
The built-in air conditioner, wherein the external heat exchanger is any one of an air-cooled heat exchanger, a water-cooled heat exchanger, a heat exchanger using a foundation pile, and a solar panel heat exchanger.   The built-in air conditioner according to claim 1, wherein the compressors are two or more compressors or a compressor whose frequency can be changed. An external heat exchanger (1), a four-way switching valve (3), a compressor (4), and a fine pipe (11),
The fine tube is a capillary tube made of metal, PB, or PERT, or a fiber sheet made of carbon nanotubes, and is laid on a floor slab so that a plurality of pipe lines are arranged in parallel. Or pasted on the wall,
The ceiling micro-tube (9) has one end of the parallel opening connected to the end of the wall micro-tube (10) via the capillary (19).
The capillary (19) has a solenoid valve (20) connected in parallel at both ends,
The wall fine pipe (10) has a parallel opening at the other end connected to the lower opening of the external heat exchanger via a throttle member (5).
The external heat exchanger has an upper opening connected to the left opening of the four-way switching valve,
The four-way switching valve has a right-side opening connected to a parallel opening at the other end of the fine tube (10) on the ceiling,
The four-way switching valve is a built-in air conditioner characterized in that a common opening located in the center is connected to a return air port of the compressor. The fine pipe is provided with a reinforcing rib in the pipe, and a heat transfer layer (16) made of at least one of cement, sand, graphite, and metal powder is provided between the pipes. In addition, a heat insulating layer (15) formed of a one-way inorganic super heat conductive material or foam material is installed on the upper side of the heat transfer layer,
The water-cooled heat exchanger (17) has an opening at one end connected in series between the inlet of the four-way switching valve and the outlet of the compressor, and the opening at the other end via a pump (18). The built-in air conditioner according to claim 3, wherein the built-in air conditioner is connected to an indoor pipeline that requires External heat exchanger (1), four-way switching valve (3), compressor (4), check valve (8), fine pipe (11), ventilation dehumidifier (28), venturi pipe ( 31), and
The fine tube is a capillary tube made of metal, PB or PERT, and is affixed to the ceiling such that a plurality of pipelines are arranged in parallel, or is laid on the ground,
The microtube has a parallel opening at one end connected to the opening on the right side of the four-way switching valve via the check valve,
The four-way switching valve has a left opening connected to the upper opening of the external heat exchanger,
The external heat exchanger has a lower opening connected to a parallel opening at the other end of the microtube via a throttle member,
In the four-way switching valve, a common opening located in the center is connected to a return air port of the compressor,
The four-way switching valve has an inlet connected to an outlet of the compressor;
The check valve has the ventilation dehumidifier connected to both ends in parallel,
The built-in air conditioner, wherein the venturi pipe is installed on an outlet side of the check valve connected to the ventilation dehumidifier. A heat exchanger (32) using a foundation pile, a four-way switching valve (3), and a compression expander (33);
The heat exchanger using the foundation pile is integrally formed by flowing concrete in a state where the fine pipe (11) is fixed to the reinforcing bar (12), or is concreted to the microporous reinforcing bar (34). Is formed integrally by flowing in,
The heat exchanger using the foundation pile has an opening at one end connected to an opening on the left side of the four-way switching valve, and an opening at the other end via the compression / expansion machine. Connected to the parallel opening at one end of the
The four-way switching valve has a right opening connected to a parallel opening at the other end of the fine pipe of the floor slab, and a common opening located in the center connected to the return air port of the compression expander. A built-in air conditioner characterized in that an inlet is connected to an outlet of the compression expander. An external heat exchanger (1) and a compressor (4),
The rebar (12) and the fine pipe (11) fixed to the rebar and the concrete are integrated, or the microporous rebar (34) and the concrete are integrated,
The microtube or the microporous reinforcing bar has a parallel opening at one end connected to an opening at one end of the compressor, and the parallel opening at the other end is below the external heat exchanger via a throttle member (5). Connected to the opening of
The external heat exchanger has an upper opening connected to the opening at the other end of the compressor, an air-cooled heat exchanger, a water-cooled heat exchanger, a heat exchanger using a foundation pile, and a solar panel heat exchange Built-in air conditioner characterized by being any one of the units. An external heat exchanger (1), a four-way switching valve (3), a compressor (4), and a microporous reinforcing bar (34),
The microporous reinforcing bar is formed by welding into a reticulated flow path heat exchanger, integrated with concrete, and has a parallel opening at one end connected to an opening on the right side of the four-way switching valve, and a parallel opening at the other end. The throttle member (5) is connected to the lower opening of the external heat exchanger,
The external heat exchanger has an upper opening connected to the left opening of the four-way switching valve,
The four-way switching valve is a built-in air conditioner characterized in that a common opening located at the center is connected to a return air outlet of the compressor and an inlet is connected to an outlet of the compressor. An external heat exchanger (1), a four-way switching valve (3), a compressor (4), and two metal radiation plates,
The two metal radiating plates are installed so as to be opposed to each other, and have concave grooves or advancing guide pipes opposed to each other, and are united by heat and laid on the ground, or walls and ceilings The inlet is connected to the left opening of the four-way switching valve (3), and the outlet is connected to the lower opening of the external heat exchanger via the throttle member (5). And
The external heat exchanger has an upper opening connected to the right opening of the four-way switching valve,
The four-way switching valve has an inlet connected to the outlet of the compressor, a common opening located in the center connected to the return air port of the compressor,
The built-in air conditioner is characterized in that the external heat exchanger is any one of an air-cooled heat exchanger, a water-cooled heat exchanger, and a heat exchanger using a foundation pile. An external heat exchanger (1), a four-way switching valve (3), a compressor (4), and a fine pipe (11),
The fine tube is a capillary tube made of metal, PERT, or PB, and is affixed to the ceiling such that a plurality of pipelines are arranged in parallel, or is laid on the ground, and the parallel opening at one end has the four sides Connected to the opening on the right side of the switching valve,
The four-way switching valve has a left opening connected to the upper opening of the external heat exchanger,
The external heat exchanger has a lower opening connected to a parallel opening at the other end of the microtube via a throttle member (5),
The four-way switching valve is a built-in air conditioner characterized in that a common opening located at the center is connected to a return air outlet of the compressor and an inlet is connected to an outlet of the compressor.

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