CN211977008U - Air conditioning system - Google Patents

Abstract

The utility model discloses an air conditioning system, which comprises an energy production host and a heat exchanger, wherein the energy production host and the heat exchanger are connected with a medium circulation pipeline; the heat exchanger comprises a heat pipe capable of exchanging heat with the medium circulation pipeline; the medium circulation pipe is in contact with or connected to the heat pipe. The utility model discloses an air conditioning system, through setting up the heat pipe, the heat pipe releases energy (cold volume or heat) to external environment fast in, does not need high blast volume motor just can obtain fine radiating effect, can not have wind directly to blow to the human body, and does not have the fan noise and produce, has improved the comfort level that the air conditioner used.

Description

Air conditioning system

Technical Field

The utility model relates to an air conditioning technology field especially relates to an air conditioning system.

Background

In the prior art, a traditional air conditioning system simply depends on a high-air-volume motor to obtain a better heat dissipation effect, the high-air-volume motor brings great noise, and the high air volume blows towards a human body, so that people feel uncomfortable, and even air conditioning diseases can be possibly caused.

In view of this, it is necessary to provide an air conditioning system that can achieve a good heat dissipation effect without using a fan.

SUMMERY OF THE UTILITY MODEL

The technical scheme of the utility model provides an air conditioning system, which comprises an energy production host and a heat exchanger, wherein the energy production host and the heat exchanger are connected with a medium circulation pipeline;

the heat exchanger comprises a heat pipe capable of exchanging heat with the medium circulation pipeline;

the medium circulation pipe is in contact with or connected to the heat pipe.

Further, the energy-making main machine is an outdoor machine of a split air conditioner.

Further, the heat exchanger comprises a plurality of heat pipes which are arranged at intervals.

Further, the medium circulation pipeline comprises a refrigerating medium circulation pipeline and a heating medium circulation pipeline;

the refrigerating medium circulating pipeline is connected to one end of the heat pipe, and the heating medium circulating pipeline is connected to the other end of the heat pipe;

and valves are respectively arranged on the refrigerating medium circulating pipeline and the heating medium circulating pipeline.

Further, the refrigeration medium circulation pipeline is connected to the upper end of the heat pipe, and the heating medium circulation pipeline is connected to the lower end of the heat pipe.

Further, the refrigerant medium circulation pipe includes a refrigerant medium supply pipe and a refrigerant medium return pipe connected to the refrigerant medium supply pipe;

the refrigerating medium supply pipe is connected to the upper end of the heat pipe, and the refrigerating medium return pipe is separated from the heat pipe by a first preset distance;

the heating medium circulating pipeline comprises a heating medium supply pipe and a heating medium return pipe connected with the heating medium supply pipe;

the heating medium supply pipe is connected to the lower end of the heat pipe, and a second preset distance is reserved between the heating medium return pipe and the heat pipe;

valves are respectively arranged on the refrigerating medium supply pipe, the refrigerating medium return pipe, the heating medium supply pipe and the heating medium return pipe.

Furthermore, a plurality of radiating fins are arranged on the heat pipe.

Further, the heat exchanger includes a thermally conductive housing having a mounting cavity within which the heat pipe is mounted.

Further, phase change materials are filled in the installation cavity.

Further, a water receiving container is arranged below the heat exchanger.

Further, the heat exchanger is arranged in a wall or a ceiling.

Further, the energy-making system also comprises a room temperature measuring device and a controller for controlling the switch of the energy-making host;

the room temperature measuring device is arranged on the outer side of the heat exchanger, and the controller is installed in the energy production host;

the room temperature measuring device is in signal connection with the controller.

Further, the refrigeration medium is a refrigerant or water.

By adopting the technical scheme, the method has the following beneficial effects:

the utility model provides an air conditioning system, through heat pipe transmission energy, the heat pipe can be fast with energy (cold volume or heat) diffusion to the surrounding environment in, does not need high air-volume motor just can obtain fine radiating effect, can not have wind directly to blow to the human body, and does not have the fan noise and produces, has improved the comfort level that the air conditioner used.

Drawings

Fig. 1 is a schematic layout view of an air conditioning system according to a first embodiment of the present invention;

fig. 2 is a schematic layout view of an air conditioning system according to a second embodiment of the present invention;

fig. 3 is a schematic layout view of an air conditioning system according to a third embodiment of the present invention;

FIG. 4 is a schematic diagram of the arrangement of the heat conducting shell and heat pipes of the heat exchanger;

fig. 5 is a schematic layout view of an air conditioning system according to a fourth embodiment of the present invention;

fig. 6 is a schematic arrangement diagram of a heating medium circulation pipe, a cooling medium circulation pipe, and a heat pipe in a fourth embodiment;

FIG. 7 is a schematic diagram of the medium flow of the air conditioning system in the fourth embodiment during cooling;

fig. 8 is a schematic diagram of the medium flow of the air conditioning system in the fourth embodiment when heating;

FIG. 9 is a schematic diagram of a heat pipe with a branch heat pipe disposed thereon and a heat sink fin disposed thereon;

FIG. 10 is a schematic view of a phase change material filled in the mounting cavity;

FIG. 11 is a schematic view of a heat exchanger disposed within a wall.

Detailed Description

The following describes the present invention with reference to the accompanying drawings. In which like parts are designated by like reference numerals. It should be noted that the terms "front," "back," "left," "right," "upper" and "lower" used in the following description refer to directions in the drawings, and the terms "inner" and "outer" refer to directions toward and away from, respectively, the geometric center of a particular component.

As shown in fig. 1-5, an embodiment of the present invention provides an air conditioning system, which includes a system energy host 1 and a heat exchanger 2, wherein the system energy host 1 and the heat exchanger 2 are connected to a medium circulation pipeline 3.

The heat exchanger 2 comprises heat pipes 22 which are able to exchange heat with the medium flow channels 3.

The medium circulation duct 3 is in contact or connected with the heat pipe 22.

The utility model provides a system can the host computer be split air conditioner or domestic air conditioner's off-premises station, also can be central air conditioning's system can the host computer, it can be for the refrigeration host computer, heat the host computer or can refrigerate and heat the host computer.

The heat exchanger 2 is an indoor unit for releasing the exchanged energy (cold or heat) into the ambient environment to change the indoor temperature. The heat exchanger 2 is mainly composed of heat pipes 22. The heat pipe 22 is a heat transfer element that relies on the phase change of its internal working fluid to effect heat transfer. The heat pipe is mainly used for transferring heat by the vapor-liquid phase change of the working liquid, and has low thermal resistance, so that the heat pipe has high heat conduction capability. Heat pipes generally consist of a pipe shell, a wick, and end caps. The interior of the heat pipe is pumped into a negative pressure state and filled with proper liquid, and the liquid has a low boiling point and is easy to volatilize. The tube wall has a wick that is constructed of a capillary porous material. When one end of the heat pipe is heated, the liquid in the capillary tube is quickly vaporized, the vapor flows to the other end under the power of heat diffusion, the vapor is condensed at the cold end to release heat, and the liquid flows back to the evaporation end along the porous material by the capillary action, so that the circulation is not stopped until the temperatures of the two ends of the heat pipe are equal (at the moment, the heat diffusion of the vapor is stopped). This cycle is rapid and heat can be conducted away from the heat source.

The heat pipe 22 can rapidly release energy (cold or heat) into the surrounding environment.

The medium circulation pipeline 3 is connected between the energy production main machine 1 and the heat exchanger 2, and the heat pipe 22 is in contact with or connected with the medium circulation pipeline 3. The heat pipe 22 and the medium circulation duct 3 may be connected by a fastener.

When the energy production host machine 1 refrigerates, the air conditioning medium cools the medium circulation pipeline 3, the heat pipe 22 is in contact with the medium circulation pipeline 3, the heat pipe and the medium circulation pipeline exchange heat, the temperature of the heat pipe 22 is reduced, cold energy is released to the surrounding environment, the temperature of the surrounding environment is changed, and the function of cooling the indoor machine is achieved.

When the energy production host machine 1 heats, the air conditioning medium heats the medium circulation pipeline 3, the heat pipe 22 is in contact with the medium circulation pipeline 3, the heat exchange between the heat pipe and the medium circulation pipeline 3 is carried out, the temperature of the heat pipe 22 rises, heat is released to the surrounding environment, the temperature of the surrounding environment is changed, and the function of heating the indoor unit is achieved.

Therefore, the utility model provides an air conditioning system, through setting up heat pipe 22, heat pipe 22 releases energy (cold volume or heat) to outside surrounding environment fast, does not need high blast volume motor just can obtain fine radiating effect, can not have wind direct blow to the human body, and does not have the fan noise to produce, has improved the comfort level that the air conditioner used.

In one embodiment, as shown in fig. 1 to 5, the heat exchanger 2 includes a plurality of heat pipes 22 arranged at intervals, and each heat pipe 22 is in contact with or connected to the medium circulation duct 3, so that the heat exchange efficiency between the heat pipe 22 and the medium circulation duct 3 is improved, and the heat exchanger 2 is beneficial to rapidly changing the temperature of the surrounding environment.

Preferably, any two adjacent heat pipes 22 are arranged in parallel, so that the arrangement is convenient, the heat flowing direction of each heat pipe 22 is consistent when heat exchange is carried out, heat turbulence between the adjacent heat pipes cannot be caused, and the heat exchange effect is further improved.

In one embodiment, as shown in fig. 1 to 2, fig. 5, and fig. 7 to 8, the medium circulation line 3 includes a cooling medium circulation line 31 and a heating medium circulation line 32.

The refrigerant circulation pipe 31 is connected to one end of the heat pipe 22, and the heating medium circulation pipe 32 is connected to the other end of the heat pipe 22.

Valves are provided in the refrigerant circulation line 31 and the heating medium circulation line 32, respectively.

With the arrangement, when the energy-producing main machine 1 produces the cooling, the cooling medium or the air conditioning medium exchanges heat with one end of the heat pipe 22 through the cooling medium circulating pipeline 31, and when the energy-producing main machine 1 produces the heating, the heating medium or the air conditioning medium exchanges heat with the other end of the heat pipe 22 through the heating medium circulating pipeline 32, so that the medium circulation during the cooling and the medium circulation during the heating are separated. The valves 6 may be provided in the cooling medium circulation line 31 and the heating medium circulation line 32 to achieve switching.

The utility model provides a refrigerant circulating line 31 is mainly for supplying refrigerant's pipeline to the heat exchanger, and after the heat transfer, the medium after the backward flow can be through other pipelines. The heating medium circulation pipe 32 is a pipe that mainly supplies the heating medium to the heat exchanger, and the medium after the heat exchange may pass through other pipes.

As shown in fig. 1 to 2, the present invention provides an air conditioning system in which a medium circulation line 3 includes a refrigerant medium circulation line 31, a heating medium circulation line 32, a communication line 33, and a branch line 34.

A valve K1 is provided at one end of the refrigerant circulation pipe 31 near the brake master 1. The communication pipe 33 is connected between the refrigerant circulation pipe 31 and the heating medium circulation pipe 32, and a valve K2 is provided in the communication pipe 33. The branch pipe 34 is connected between the communication pipe 33 and the refrigerant medium circulation pipe 31, and a valve K3 is provided in the branch pipe 34.

The connection point of the branch pipe 34 and the refrigerant medium circulation pipe 31 is located between the valve K1 and the brake master 1.

When the heating system 1 performs cooling, the valve K1 and the valve K2 are opened, the valve K3 is closed, and the medium circulates along the cooling medium circulation line 31, the communication line 33, and the heating medium circulation line 32.

When the heating system 1 heats, the valve K3 is opened, the valve K1 and the valve K2 are closed, and the medium circulates along the heating medium circulation pipe 32 and the branch pipe 34.

As shown in fig. 2, the heat exchanger 2 may also be arranged in parallel with the indoor unit 4, and an air conditioning circulation duct is connected between the indoor unit 4 and the energy-producing main machine 1. The cooling medium circulation pipe 31 and the heating medium circulation pipe 32 are connected to one of the air-conditioning circulation pipes, respectively. A valve K5 is further provided in the refrigerant circulation pipe 31 to control the on/off of the refrigerant circulation pipe 31 and the air conditioning circulation pipe. A valve K7 is provided in the heating medium circulation pipe 32 to control the on/off of the heating medium circulation pipe 32 and the air conditioning circulation pipe.

The air-conditioning circulation duct includes a first duct 101 and a second duct 102, and the first duct 101 and the second duct 102 are respectively connected between the indoor unit 4 and the heat exchanger 2.

The refrigerant circulation pipe 31 is connected to the first pipe 101, and a valve K4 is provided in the first pipe 101 to control the opening and closing of the first pipe 101. The interface between the refrigerant circulation pipe 31 and the first pipe 101 is located between the valve K4 and the energy control main unit 1, so as to ensure that the energy control main unit 1 can also supply the refrigerant to the refrigerant circulation pipe 31 when the valve K4 is closed. The heating medium circulation pipe 32 is connected to the second pipe 102. A valve K6 is provided on the second pipe 102 to control the on/off of the second pipe 102. The interface between the heating medium circulation pipe 32 and the second pipe 102 is located between the valve K6 and the energy-generating main unit 1, so as to ensure that the energy-generating main unit 1 can also supply the heating medium into the heating medium circulation pipe 32 when the valve K6 is closed.

The control of the heat dissipation of the indoor unit 4 and/or the heat exchanger 2 can be realized by operating the valve to open and close.

Preferably, a refrigerant circulation pipe 31 is connected to the upper end of the heat pipe 22, and a heating medium circulation pipe 32 is connected to the lower end of the heat pipe 22.

The refrigerating medium circulation duct 31 is arranged at the upper part of the heat pipe 22, and the cold energy is transmitted downwards along the heat pipe 22 after the heat pipe 22 exchanges heat with the refrigerating medium circulation duct 31. The heating medium circulation duct 32 is disposed at a lower portion of the heat pipe 22, and heat is transferred upward along the heat pipe 22 after the heat pipe 22 exchanges heat with the heating medium circulation duct 32.

In the fourth embodiment, as shown in fig. 5 to 8, the refrigerant medium circulating piping 31 includes a refrigerant medium supply pipe 311 and a refrigerant medium return pipe 312 connected to the refrigerant medium supply pipe 311.

The refrigerant supply pipe 311 is connected to the upper end of the heat pipe 22, and the refrigerant return pipe 312 is spaced apart from the heat pipe 22 by a first predetermined distance.

The heating medium circulation line 32 includes a heating medium supply line 321 and a heating medium return line 322 connected to the heating medium supply line 321.

The heating medium supply pipe 321 is connected to a lower end of the heat pipe 22, and the heating medium return pipe 322 is spaced apart from the heat pipe 22 by a second predetermined distance.

The valves 6 are provided in the refrigerant supply pipe 311, the refrigerant return pipe 312, the heating medium supply pipe 321, and the heating medium return pipe 322, respectively.

The heat pipes 22 are arranged vertically. The refrigerant medium circulation conduit 31 includes a refrigerant medium supply conduit 311 and a refrigerant medium return conduit 312. One end of the refrigerant supply pipe 311 is connected to the energy control main unit 1, and the refrigerant supply pipe 311 is in contact with or connected to the upper end of the heat pipe 22, thereby realizing the transmission of the refrigerant. The other end of the refrigerant medium supply pipe 311 is connected to one end of the refrigerant medium return pipe 312, and the other end of the refrigerant medium return pipe 312 is connected to the energy-generating main unit 1, thereby achieving the medium return after heat exchange.

The refrigerant medium return pipe 312 is installed to be suspended by a suspension member 313 at a first predetermined distance from the heat pipe 22, the first predetermined distance being greater than 0. The refrigerant medium return pipe 312 is not in contact with the heat pipe 22, so that the temperature of the heat pipe 22 is prevented from being influenced by the returned medium.

The heating medium circulation line 32 includes a heating medium supply line 321 and a heating medium return line 322. One end of the heating medium supply pipe 321 is connected to the heating main unit 1, and the heating medium supply pipe 321 is in contact with or connected to the lower end of the heat pipe 22 to transport the heating medium. The other end of the heating medium supply pipe 321 is connected to one end of the heating medium return pipe 322, and the other end of the heating medium return pipe 322 is connected to the energy generating main unit 1, so that the medium after heat exchange flows back.

The heating medium return pipe 322 is installed by a support 323 spaced apart from the heat pipe 22 by a second predetermined distance, which is greater than 0. The heating medium return pipe 322 is not in contact with the heat pipe 22, so as to avoid the returned medium from influencing the temperature of the heat pipe 22.

Valves 6 are provided to the refrigerant supply pipe 311, the refrigerant return pipe 312, the heating medium supply pipe 321, and the heating medium return pipe 322, respectively, for controlling the switching of the pipes.

When the heating main unit 1 performs cooling, the valves 6 of the cooling medium supply pipe 311 and the cooling medium return pipe 312 are opened, and the valves 6 of the heating medium supply pipe 321 and the heating medium return pipe 322 are closed. When the heating main unit 1 heats, the valves 6 of the heating medium supply pipe 321 and the heating medium return pipe 322 are opened, and the valves 6 of the cooling medium supply pipe 311 and the cooling medium return pipe 312 are closed.

In one embodiment, as shown in fig. 4, 6 and 9, a plurality of heat dissipation fins 221 are disposed on the heat pipe 22, and heat in the heat pipe 22 is released through the heat dissipation fins 221, so that heat of the heat pipe 22 can be quickly released and transferred, thereby improving heat exchange capability of the heat pipe 22.

Preferably, a plurality of branch heat pipes 222 extending obliquely are disposed on the heat pipe 22, and the heat dissipation fins 221 are disposed on the branch heat pipes 222, so that the heat dissipation area of the heat pipe 22 can be expanded, and the heat exchange efficiency of the heat conduction housing 21 can be improved.

In the second, third and fourth embodiments, as shown in fig. 3-5 and 7-8, the heat exchanger 2 includes a thermally conductive housing 21 having a mounting cavity 211 with a heat pipe 22 mounted within the mounting cavity 211.

The heat conductive casing 21 provides protection for the heat pipe 22 and also has a heat dissipation function to achieve a change in ambient temperature.

The thermally conductive housing 21 may release heat from the heat pipe 22 to the ambient environment. The heat conductive outer case 21 is a case capable of transferring heat, and may be a metal case, for example, a copper case, an iron case, an aluminum case, or the like. The heat pipe 22 is mounted in the mounting cavity 211 of the heat conductive housing 21.

A plurality of heat radiation holes or heat radiation ports may be provided on the heat conductive housing 21 as needed.

Preferably, the heat pipe 22 is in contact with the heat conductive housing 21 to facilitate rapid heat transfer.

The medium circulation pipeline 3 outside the installation cavity 21 is coated with the heat preservation layer, and the medium circulation pipeline 3 inside the installation cavity 21 is exposed, so that heat exchange with the heat pipe 22 is facilitated.

When the energy production host machine 1 refrigerates, the air conditioning medium cools the medium circulation pipeline 3, the heat pipe 22 is in contact with the medium circulation pipeline 3, the heat pipe and the medium circulation pipeline exchange heat, the temperature of the heat pipe 22 is reduced, cold energy is transmitted to the heat conduction shell 21, the heat conduction shell 21 releases the cold energy to the surrounding environment, the temperature of the surrounding environment is changed, and the function of cooling the indoor machine is achieved.

When the energy production host machine 1 heats, the air conditioning medium heats the medium circulation pipeline 3, the heat pipe 22 is in contact with the medium circulation pipeline 3, the heat pipe and the medium circulation pipeline exchange heat, the temperature of the heat pipe 22 rises, heat is transferred to the heat conduction shell 21, the heat conduction shell 21 releases the heat to the surrounding environment, the temperature of the surrounding environment is changed, and the function of heating of the indoor machine is achieved.

The refrigerant medium return pipe 312 may be hung in the mounting chamber 211 by a hanger 313, and the heating medium return pipe 322 is mounted in the mounting chamber 211 by a supporter 323.

The heat dissipation fins 221 are located in the installation cavity 211, heat in the heat pipe 22 is released through the heat dissipation fins 221 and then transferred to the heat conduction shell 21, the heat conduction shell 21 releases and transfers heat of the heat pipe 22 quickly, and heat exchange capacity of the heat pipe 22 and the heat conduction shell 21 is improved.

In one embodiment, as shown in FIG. 10, the phase change material 23 is filled within the mounting cavity 211.

A Phase Change Material (PCM-Phase Change Material) refers to a substance that changes the state of a substance at a constant temperature and can provide latent heat. The process of changing physical properties is called a phase change process, and in this case, the phase change material absorbs or releases a large amount of latent heat.

The phase change material mainly comprises three types of inorganic phase change materials, organic phase change materials and composite phase change materials. Wherein, the inorganic phase-change material mainly comprises crystalline hydrated salt, molten salt, metal or alloy and the like; the organic phase-change material mainly comprises paraffin, acetic acid and other organic matters; the composite phase-change material is formed by compounding a plurality of different phase-change materials, can effectively overcome the defects of a single inorganic or organic phase-change heat storage material, and can improve the application effect and expand the application range of the phase-change material.

The phase change material can be directly processed and molded into a required shape according to needs, and can also be mixed into a building material to be molded into a required shape.

The phase change material can store cold and heat, i.e. store energy. When the power grid is in a valley period, the electricity price is low, the energy-making host machine 1 can be started to refrigerate or heat, then the cold or heat is transferred to the phase-change material 23 through the heat pipe 22, and then the cold or heat is temporarily stored through the phase-change material 23, so that cold or heat accumulation is realized. When the power grid is in a peak period, the electricity price is high, the energy-making host 1 can be turned off at the moment, the stored cold or heat is released through the phase change material 23, the heat conduction shell 21 transmits the cold or heat released by the phase change material 23 to the ambient environment, the temperature of the ambient environment is changed or the room temperature is changed, and the electricity fee can be saved.

In one embodiment, as shown in fig. 8, the phase-change material 23 surrounds the heat pipe 22, so that the heat exchange capability between the heat pipe 22 and the phase-change material 23 is improved, and the energy can be stored quickly. The phase change material 23 may be in contact with the heat pipe 22 to improve the heat exchange effect with the heat pipe. The phase change material 23 may also be spaced a distance from the heat pipe 22 to accommodate the space required for the volume change.

In one embodiment, as shown in fig. 1 to 3 and 5, a water receiving container 5 is arranged below the heat exchanger 2 for receiving the condensed water to prevent the condensed water from dropping to the ground. The water receiving container 5 can be hung below the heat exchanger 2 through a hanging device, and the water receiving container 5 can also be installed on a wall body through screws, bolts and the like so as to be positioned below the heat exchanger 2. The top of the water receiving container 5 is provided with a container opening, and the area of the container opening is larger than that of the bottom of the heat exchanger 2, so that condensed water dropping from the heat exchanger 2 can be conveniently received.

In one embodiment, as shown in fig. 11, the heat exchanger 2 is placed in the wall 7 or the ceiling, which is beneficial to maintaining the cleanness of the indoor wall and the installation of the heat exchanger 2. The heat exchanger 2 is combined with a wall or a ceiling to radiate heat to the outside. The wall body 7 or the ceiling is provided with a mounting groove, the heat exchanger 2 is arranged in the mounting groove, and one surface of the heat conduction shell 21 faces the indoor space and is used for radiating heat to the indoor space.

In one embodiment, as shown in fig. 3, the air conditioning system further includes a room temperature measuring device 8 and a controller 11 for controlling the on/off of the brake master 1.

The room temperature measuring device 8 is arranged outside the heat exchanger 2, and the controller 11 is installed in the energy production main machine 1. The room temperature measuring device 8 is in signal connection with the controller 11.

The room temperature measuring device 8 is a temperature sensor, which is in signal connection with the controller 11. The signal connection may be an electrical signal or a communication signal. The room temperature measuring device 8 can be connected with the controller 11 through a wire, and the room temperature measuring device 8 can also be wirelessly connected with the controller 11. The room temperature measuring device 8 can send a signal to the controller 11, and the controller 11 can control the switch of the energy control host 1 according to the signal transmitted by the room temperature measuring device 8. The controller 11 may be a single chip, a chip, or a CPU. The controller 11 may be connected to a compressor, a fan, or the like in the energy control main unit 1 by signals, and controls the on/off of each electronic component.

When the room temperature measuring device 8 monitors that the room temperature reaches the first preset temperature, the room temperature measuring device 8 sends a first signal to the controller 11, and the controller 11 starts the energy control host 1 when receiving the first signal. When the room temperature measuring device 8 monitors that the room temperature reaches the second preset temperature, the room temperature measuring device 8 sends a second signal to the controller 11, and the controller 11 closes the energy control host 1 when receiving the second signal. By such arrangement, the automatic control of the energy-producing host 1 can be realized, and the electric charge can be saved.

The first preset temperature and the second preset temperature can be set arbitrarily according to requirements.

In one embodiment, the refrigerating medium is a refrigerant or water, and can meet the requirements of different refrigerating working conditions. The refrigerant may be R134a, R22, R410A, etc.

To sum up, the utility model provides an air conditioning system, through be provided with the heat pipe in the heat exchanger, the heat pipe does not need high blast volume motor just can obtain fine radiating effect with energy (cold volume or heat) release to the external environment fast, can not have windy direct blow to the human body, and does not have the fan noise to produce, has improved the comfort level that the air conditioner used.

According to the needs, the above technical schemes can be combined to achieve the best technical effect.

What has been described above is merely the principles and preferred embodiments of the present invention. It should be noted that, for those skilled in the art, on the basis of the principle of the present invention, several other modifications can be made, and the protection scope of the present invention should be considered.

Claims (12)

1. The air conditioning system is characterized by comprising an energy production host and a heat exchanger, wherein the energy production host and the heat exchanger are connected with a medium circulation pipeline;

the heat exchanger comprises a heat pipe capable of exchanging heat with the medium circulation pipeline;

the medium circulation pipe is in contact with or connected to the heat pipe.

2. The system of claim 1, wherein the energy generating main unit is an outdoor unit of a split air conditioner.

3. The air conditioning system as claimed in claim 1, wherein said heat exchanger includes a plurality of said heat pipes arranged at intervals.

4. The air conditioning system according to any one of claims 1 to 3, wherein the medium circulation line includes a cooling medium circulation line and a heating medium circulation line;

the refrigerating medium circulating pipeline is connected to one end of the heat pipe, and the heating medium circulating pipeline is connected to the other end of the heat pipe;

and valves are respectively arranged on the refrigerating medium circulating pipeline and the heating medium circulating pipeline.

5. The air conditioning system as claimed in claim 4, wherein the refrigerant circulation pipe is connected to an upper end of the heat pipe, and the heating medium circulation pipe is connected to a lower end of the heat pipe.

6. The air conditioning system as claimed in claim 5, wherein the refrigerant medium circulation pipe includes a refrigerant medium supply pipe and a refrigerant medium return pipe connected to the refrigerant medium supply pipe;

the refrigerating medium supply pipe is connected to the upper end of the heat pipe, and the refrigerating medium return pipe is separated from the heat pipe by a first preset distance;

the heating medium circulating pipeline comprises a heating medium supply pipe and a heating medium return pipe connected with the heating medium supply pipe;

the heating medium supply pipe is connected to the lower end of the heat pipe, and a second preset distance is reserved between the heating medium return pipe and the heat pipe;

valves are respectively arranged on the refrigerating medium supply pipe, the refrigerating medium return pipe, the heating medium supply pipe and the heating medium return pipe.

7. An air conditioning system according to any of claims 1 to 3, wherein a plurality of fins are provided on the heat pipe.

8. An air conditioning system according to any of claims 1 to 3, wherein the heat exchanger comprises a thermally conductive housing having a mounting cavity within which the heat pipe is mounted.

9. The air conditioning system as claimed in claim 8, wherein the installation cavity is filled with a phase change material.

10. Air conditioning system according to any of claims 1-3, characterized in that a water receptacle is arranged below the heat exchanger.

11. An air conditioning system according to any of claims 1 to 3, wherein the heat exchanger is placed in a wall or ceiling.

12. The air conditioning system of any of claims 1-3, further comprising a room temperature measuring device and a controller for controlling the energy producing main machine switch;

the room temperature measuring device is arranged on the outer side of the heat exchanger, and the controller is installed in the energy production host;

the room temperature measuring device is in signal connection with the controller.

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