CN107367028B - Temperature control system and air conditioner - Google Patents

Abstract

The invention discloses a temperature control system and an air conditioner, and relates to the field of air conditioners. The invention provides a temperature control system which is applied to an air conditioner. The temperature control mechanism comprises a first drainage device, a first channel and a second channel, wherein the first drainage device is used for guiding airflow in the first channel to flow, and the first drainage device is used for guiding airflow in the second channel to flow. The heat dissipation assembly is connected with the power mechanism and is arranged inside the first channel so that the heat dissipation assembly can heat air flow inside the first channel. The refrigeration mechanism is connected with the second channel and is used for refrigerating the air flow in the second channel. An air conditioner adopts the temperature control system. The temperature control system and the air conditioner provided by the invention can reasonably utilize waste heat generated by the air conditioner.

Description

Temperature control system and air conditioner

Technical Field

The invention relates to the field of air conditioners, in particular to a temperature control system and an air conditioner.

Background

The temperature control system adopted by the existing air conditioner generally controls the temperature through frequent start and stop of a compressor, and waste heat generated by an engine is cooled by a cold area system, so that the occupied space of air conditioning equipment is large, and the energy loss is high.

Disclosure of Invention

The invention aims to provide a temperature control system which can reasonably utilize waste heat generated by the temperature control system, can effectively perform refrigeration and heating and can save a large amount of energy.

Another object of the present invention is to provide an air conditioner which can reasonably use waste heat generated by itself, can effectively perform cooling and heating, and can save a large amount of energy.

The invention provides a technical scheme that:

the temperature control system is applied to an air conditioner and comprises a refrigerating mechanism, a power mechanism, a heat dissipation assembly and a temperature control mechanism, wherein the power mechanism is connected with the refrigerating mechanism and is used for driving the refrigerating mechanism. The temperature control mechanism comprises a first drainage device, a first channel and a second channel, wherein the first drainage device is connected with the first channel and used for guiding airflow in the first channel to flow, and the first drainage device is connected with the second channel and used for guiding airflow in the second channel to flow. The heat dissipation assembly is connected with the power mechanism, and is used for dissipating heat of the power mechanism, and the heat dissipation assembly is arranged inside the first channel, so that the heat dissipation assembly can heat air flow inside the first channel. The refrigeration mechanism is connected with the second channel and is used for refrigerating the air flow in the second channel.

Further, the temperature control system further comprises a first airtight air valve and a second airtight air valve, the first airtight air valve is arranged inside the first channel, the first airtight air valve selectively opens the first channel or closes the first channel, the second airtight air valve is arranged inside the second channel, and the second airtight air valve selectively opens the second channel or closes the second channel.

Further, the heat dissipation assembly is arranged between the first closed air valve and the first drainage device, and the refrigeration mechanism is arranged between the first drainage device and the second closed air valve.

Further, the temperature control system further comprises a main flow channel, the first drainage device is arranged inside the main flow channel, and the first channel and the second channel are respectively communicated with the main flow channel.

Further, the power mechanism comprises a generator, the refrigeration mechanism comprises a compressor, the generator is connected with the compressor, the generator is used for providing mechanical energy for the compressor, the generator is connected with the first drainage device, and the generator is used for providing electric energy for the first drainage device.

Further, the heat dissipation assembly comprises a heat dissipation water tank, a heat exchanger and a first flow channel, wherein the heat dissipation water tank is communicated with the heat exchanger through the first flow channel to form a circulation loop, the heat dissipation water tank is connected with the power mechanism, and the heat exchanger is arranged in the first channel.

Further, the heat dissipation assembly further comprises a first control valve, the first control valve is connected with the first flow channel, and the first control valve selectively opens the first flow channel to enable the first flow channel to be conducted, or closes the first flow channel.

Further, the power mechanism further comprises a smoke exhaust silencer and a second water flow channel, the smoke exhaust silencer is connected with the generator, and the smoke exhaust silencer is communicated with the heat exchanger through the second water flow channel and forms a circulation loop.

Further, a second control valve is arranged on the second water flow channel, and the second control valve selectively opens the second water flow channel to enable the second water flow channel to be conducted, or closes the second water flow channel.

The utility model provides an air conditioner, includes casing and temperature control system, temperature control system is applied to the air conditioner, temperature control system includes refrigeration mechanism, power unit, radiator unit and temperature control mechanism, power unit with refrigeration mechanism connects, power unit is used for driving refrigeration mechanism. The temperature control mechanism comprises a first drainage device, a first channel and a second channel, wherein the first drainage device is connected with the first channel and used for guiding airflow in the first channel to flow, and the first drainage device is connected with the second channel and used for guiding airflow in the second channel to flow. The heat dissipation assembly is connected with the power mechanism, and is used for dissipating heat of the power mechanism, and the heat dissipation assembly is arranged inside the first channel, so that the heat dissipation assembly can heat air flow inside the first channel. The refrigeration mechanism is connected with the second channel and is used for refrigerating the air flow in the second channel. The temperature control system is arranged inside the shell.

Compared with the prior art, the temperature control system and the air conditioner provided by the invention have the beneficial effects that:

according to the temperature control system and the air conditioner, flowing air flows are formed in the first channel and the second channel through the first drainage device, the power mechanism is radiated through the radiating component, the radiating component radiates heat to the power mechanism and absorbs waste heat radiated by the power mechanism, the radiating component absorbing the waste heat heats the air flow in the first channel, the air flow led out of the first channel can achieve the heating function, the air flow in the second channel is refrigerated through the refrigerating mechanism, and the air flow led out of the second channel can achieve the refrigerating function. The waste heat generated by the power mechanism is reasonably utilized by utilizing the waste heat of the power mechanism to realize the heating function, so that a large amount of energy sources are saved.

Drawings

In order to more clearly illustrate the technical solution of the embodiments of the present invention, the drawings that are required to be used in the embodiments will be briefly described. It is appreciated that the following drawings depict only certain embodiments of the invention and are therefore not to be considered limiting of its scope. Other relevant drawings may be made by those of ordinary skill in the art without undue burden from these drawings.

FIG. 1 is a schematic diagram of a temperature control system according to a first embodiment of the present invention;

FIG. 2 is a schematic diagram of a temperature control system according to a second embodiment of the present invention;

FIG. 3 is a schematic diagram of a part of a temperature control system according to a first embodiment of the present invention;

FIG. 4 is a schematic diagram of a part of a temperature control system according to a first embodiment of the present invention.

Icon: 10-a temperature control system; 100-a temperature control mechanism; 110-a first drainage device; 120-first channel; 121-a first airtight air valve; 130-a second channel; 131-a second airtight air valve; 140-main flow channel; 200-a power mechanism; 220-a smoke exhaust muffler; 230-a second water flow path; 231-a second control valve; 300-a heat dissipation assembly; 310-radiating water tank; 320-heat exchanger; 330-a first flow channel; 331-a first control valve; 400-refrigeration mechanism; 410-a compressor; 420-a condenser; 430-a second drainage device; 440-reservoir; 450-drying the filter; 460-an expansion valve; 470-evaporating pressure regulating valve; 480-an evaporator; 490-gas-liquid separator.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention more clear, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention. It will be apparent that the described embodiments are some, but not all, embodiments of the invention. The components of the embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the invention, as presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

It should be noted that: like reference numerals and letters denote like items in the following figures, and thus once an item is defined in one figure, no further definition or explanation thereof is necessary in the following figures.

In the description of the present invention, it should be understood that the directions or positional relationships indicated by the terms "upper", "lower", "inner", "outer", "left", "right", etc. are based on the directions or positional relationships shown in the drawings, or the directions or positional relationships conventionally put in place when the inventive product is used, or the directions or positional relationships conventionally understood by those skilled in the art are merely for convenience of describing the present invention and simplifying the description, and do not indicate or imply that the apparatus or elements referred to must have a specific direction, be configured and operated in a specific direction, and therefore should not be construed as limiting the present invention.

Furthermore, the terms "first," "second," and the like, are used merely to distinguish between descriptions and should not be construed as indicating or implying relative importance.

In the description of the present invention, it should also be noted that, unless explicitly specified and limited otherwise, terms such as "disposed," "connected," and the like are to be construed broadly, and for example, "connected" may be either fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art according to the specific circumstances.

The following describes specific embodiments of the present invention in detail with reference to the drawings.

First embodiment

Referring to fig. 1, the present invention provides a temperature control system 10 for an air conditioner (not shown), which can reasonably utilize waste heat generated by itself, can effectively perform cooling and heating, and can save a lot of energy.

Temperature control system 10 includes, among other things, a temperature control mechanism 100, a power mechanism 200, a heat dissipation assembly 300, and a refrigeration mechanism 400. The power mechanism 200 is connected to the refrigeration mechanism 400 to drive the refrigeration mechanism 400. In addition, the heat dissipation assembly 300 is connected to the power mechanism 200, the heat dissipation assembly 300 is used for dissipating heat of the power mechanism 200, and the heat dissipation assembly 300 can absorb waste heat dissipated by the power mechanism 200. The temperature control mechanism 100 includes a first drainage device 110, a first channel 120, and a second channel 130. The first drainage device 110 is connected to the first channel 120 and is used for guiding the airflow inside the first channel 120 to flow, and the heat dissipation assembly 300 is disposed inside the first channel 120, so that the heat dissipation assembly 300 can heat the airflow inside the first channel 120. The first drainage device 110 is connected to the second channel 130 and is used for guiding the airflow inside the second channel 130 to flow, and the refrigeration mechanism 400 is connected to the second channel 130, and the refrigeration mechanism 400 is used for refrigerating the airflow inside the second channel 130.

The heat dissipation assembly 300 absorbs waste heat of the power mechanism 200 and heats the air flow in the first channel 120, and the first drainage device 110 enables the heated air flow in the first channel 120 to flow and lead out of the first channel 120 so as to heat the external environment or objects. The air flow in the second channel 130 is cooled by the cooling mechanism 400, and the air flow in the second channel 130 flows and is led out of the second channel 130 by the first drainage device 110, so as to cool the external environment or objects. The heat dissipation assembly 300 fully utilizes waste heat generated by the power mechanism 200, improves the heat dissipation effect on the power mechanism 200, and saves a large amount of energy. And the hot air flow and the cold air flow led out through the first channel 120 and the second channel 130 respectively heat and cool the external environment or the object respectively, so that the heating and cooling functions are mutually independent, the heating and cooling efficiency is improved, and the external environment and the object can be heated and cooled rapidly and effectively.

Wherein, the external environment or the object is heated and cooled respectively through the first channel 120 and the second channel 130, so that the switching between the heating function and the cooling function is quicker, the heating can be quickly switched to the cooling or the cooling can be quickly switched to the heating, and the efficiency of temperature control is provided.

Referring to fig. 3, in the present embodiment, the first channel 120 and the second channel 130 share a sidewall, so that the temperature control system 10 is relatively compact, saves space, and meets the requirement of miniaturization.

Referring to fig. 1 and 2 in combination, the direction of the arrow refers to the direction of airflow. The temperature control mechanism 100 further includes a first sealing damper 121 and a second sealing damper 131. The first airtight air valve 121 is disposed inside the first channel 120, and the first airtight air valve 121 is configured to selectively open the first channel 120 to conduct the first channel 120, so that the first drainage device 110 can guide the airflow through the first channel 120; or the first sealing damper 121 closes the first passage 120 to reduce or block the air flow flowing inside the first passage 120. The second airtight air valve 131 is disposed inside the second channel 130, and the second airtight air valve 131 is configured to selectively open the second channel 130 to enable the second channel 130 to be conductive, so that the first drainage device 110 can guide the airflow through the second channel 130; or the second sealing damper 131 closes the second passage 130 to reduce or block the air flow flowing inside the second passage 130. So as to regulate the amount of the air flow flowing in the first channel 120 or the second channel 130 in time, so that the air flow passing through the first channel 120 or the second channel 130 can be regulated to a comfortable state.

In the present embodiment, the temperature control mechanism 100 has a cooling mode and a heating mode, wherein when the temperature control mechanism 100 is in the heating mode, as shown in fig. 1, the first airtight air valve 121 opens the first channel 120, the second airtight air valve 131 closes the second channel 130, and at this time, the first drainage device 110 guides the airflow inside the first channel 120 to flow, and the hot airflow led out through the first channel 120 heats the external environment or the object. When the temperature control mechanism 100 is in the cooling mode, as shown in fig. 2, the first airtight air valve 121 closes the first channel 120, the second airtight air valve 131 opens the second channel 130, and at this time, the first drainage device 110 guides the airflow inside the second channel 130 to flow, and the cold airflow led out through the second channel 130 cools the external environment or the object.

In addition, the first airtight air valve 121 and the second airtight air valve 131 have respective control systems (not shown), that is, the first airtight air valve 121 and the second airtight air valve 131 are independent from each other, and the opening or closing of the first passage 120 by the first airtight air valve 121 and the opening or closing of the second passage 130 by the second airtight air valve 131 do not affect each other. That is, in other embodiments, the temperature control mechanism 100 may also simultaneously close the first channel 120 and the second channel 130, or simultaneously open the first channel 120 and the second channel 130.

It should be understood that, in other embodiments, the control manners of the first sealing air valve 121 and the second sealing air valve 131 may be controlled in association, that is, when the first sealing air valve 121 is in a state of opening the first channel 120, the second sealing air valve 131 is in a state of closing the second channel 130; when the first sealing damper 121 is in a state of closing the first passage 120, the second sealing damper 131 is in a state of opening the second passage 130.

Further, the heat dissipation assembly 300 is disposed between the first sealing air valve 121 and the first drainage device 110, and the refrigeration mechanism 400 is disposed between the second sealing air valve 131 and the first drainage device 110. So that the first channel 120 and the second channel 130 are in a closed state, and a large amount of dust is not accumulated to open the first channel 120 or the second channel 130. Meanwhile, the working efficiency of the heat radiation assembly 300 and the refrigeration mechanism 400 can be prevented from being influenced by external dust accumulated on the heat radiation assembly 300 and the refrigeration mechanism 400.

In addition, the temperature control mechanism 100 further includes a main flow channel 140, the first drainage device 110 is disposed inside the main flow channel 140, and the first channel 120 and the second channel 130 are respectively communicated with the main flow channel 140. In the present embodiment, when the first sealing air valve 121 opens the first channel 120 and the second sealing air valve 131 closes the second channel 130, the first channel 120 is connected to form an air flow channel together with the main flow channel 140, and the first drainage device 110 guides the air flow out through the first channel 120 and the main flow channel 140. Similarly, when the first closed air valve 121 closes the first channel 120 and the second closed air valve 131 opens the second channel 130, the second channel 130 is connected to form an air flow channel together with the main flow channel 140, and the first air flow guiding device 110 guides the air flow out through the second channel 130 and the main flow channel 140.

Through setting up main flow channel 140 for first drainage device 110 can accomplish the drainage function of two passageways of first passageway 120 and second passageway 130, avoids the control complexity of a plurality of drainage devices, and can avoid the complexity that a plurality of drainage devices need switch, and can also practice thrift certain cost.

In addition, in the present embodiment, the number of the main flow channels 140 is two, and two main flow channels 140 are respectively provided at both ends of the first channel 120 or the second channel 130, that is, the first flow guiding device 110 guides the airflow so that the airflow sequentially passes through the main flow channels 140, the first channel 120 and the main flow channels 140, or sequentially passes through the main flow channels 140, the second channel 130 and the main flow channels 140.

The heat radiating assembly 300 includes a heat radiating water tank 310, a heat exchanger 320, and a first flow path 330. The radiator tank 310 and the heat exchanger 320 are communicated with each other through the first flow passages 330 and form a circulation loop, wherein the number of the first flow passages 330 is at least two, at least one first flow passage 330 is communicated with the heat exchanger 320 as a water outlet passage so that water in the radiator tank 310 can flow into the heat exchanger 320, and at least one first flow passage 330 is communicated with the heat exchanger 320 as a water inlet passage so that water treated by the heat exchanger 320 can flow back into the radiator tank 310. The radiator tank 310 is connected to the power unit 200 such that water in the radiator tank 310 can absorb heat emitted from the power unit 200. The heat exchanger 320 is disposed inside the first passage 120, such that water entering the heat exchanger 320 can exchange heat with the air flow inside the first passage 120 through the heat exchanger 320 to heat the air flow inside the first passage 120. I.e., fully utilizes the waste heat generated by the power mechanism 200 and saves energy.

Further, the heat dissipating assembly 300 further includes a first control valve 331, the first control valve 331 is connected to the first flow channel 330, and the first control valve 331 selectively opens the first flow channel 330 to make the first flow channel 330 conductive, or closes the first flow channel 330. In the present embodiment, the number of the first control valves 331 and the number of the first flow channels 330 correspond, that is, each first flow channel 330 corresponds to one first control valve 331, and each first control valve 331 controls one first flow channel 330.

Wherein, when the water temperature in the radiator tank 310 is lower than a first preset value, the first control valve 331 closes the first flow passage 330. When the water temperature in the radiator tank 310 is higher than a first preset value, the first control valve 331 opens the first flow passage 330. In this embodiment, the first preset value is 30 ℃.

The power mechanism 200 includes a generator (not shown), a smoke muffler 220, and a second water flow path 230, wherein the generator is connected to the refrigeration mechanism 400 as a power source to provide power to the refrigeration mechanism 400, wherein the generator provides mechanical energy to the refrigeration mechanism 400 to drive the refrigeration mechanism 400. The mechanical energy adopted in the process of generating electricity by the generator drives the refrigeration mechanism 400 to operate, so that the refrigeration mechanism 400 does not need an additional power supply. In addition, the generator is connected to the first drainage device 110 to provide electric energy to the first drainage device 110 to drive the first drainage device 110. In this embodiment, the generator is a diesel generator.

The smoke silencer 220 is connected to a generator, and the smoke silencer 220 can eliminate noise of smoke, and cooling water for cooling the smoke silencer 220 is further provided in the smoke silencer 220. In addition, the smoke exhaust muffler 220 communicates with the heat exchanger 320 through the second water flow path 230 and forms a circulation loop. Like the first flow channels 330, at least two second flow channels 230 are provided, at least one second flow channel 230 is communicated with the heat exchanger 320 as an outlet channel so that cooling water can flow into the heat exchanger 320 through the second flow channel 230, and at least one second flow channel 230 is communicated with the heat exchanger 320 as an inlet channel so that cooling water treated by the heat exchanger 320 can flow back to the smoke exhaust muffler 220.

In the present embodiment, the power mechanism 200 further includes a second control valve 231, the second control valve 231 is connected to the second water flow path 230, and the second control valve 231 selectively opens the second water flow path 230 to turn on the second water flow path 230, or the second control valve 231 closes the second water flow path 230. Wherein the number of the second control valves 231 corresponds to the number of the second water flow channels 230, i.e., one second control valve 231 for each second water flow channel 230.

In the present embodiment, when the first control valve 331 is closed, the second control valve 231 is opened so that the cooling water in the smoke silencer 220 flows into the heat exchanger 320 to heat the air flow inside the first passage 120. When the first control valve 331 is opened, the second control valve 231 is closed, and the air flow inside the first passage 120 is heated by the water in the radiator tank 310 entering the heat exchanger 320.

Referring to fig. 1 and 4 in combination, the refrigeration mechanism 400 includes a compressor 410, a condenser 420, a second drainage device 430, a liquid reservoir 440, a dry filter 450, an expansion valve 460, an evaporation pressure adjusting valve 470, an evaporator 480, and a gas-liquid separator 490, wherein the compressor 410, the condenser 420, the liquid reservoir 440, the dry filter 450, the expansion valve 460, the evaporation pressure adjusting valve 470, the evaporator 480, and the gas-liquid separator 490 are sequentially connected, and the gas-liquid separator 490 is connected with the compressor 410 to form a circulation loop. The evaporator 480 is disposed inside the second channel 130, and the evaporator 480 is configured to absorb heat of the air flow inside the second channel 130 to cool the air flow inside the second channel 130.

In this embodiment, a generator is coupled to the compressor 410 and provides mechanical energy to the compressor 410 to drive the compressor 410 to operate. Wherein the generator includes a pulley (not shown), the generator is connected with the compressor 410 through the pulley, and the generator drives the compressor 410 to operate through the pulley.

The temperature control system 10 provided in this embodiment forms a flowing air flow inside the first channel 120 and inside the second channel 130 through the first drainage device 110, and dissipates heat to the power mechanism 200 through the heat dissipation component 300, the heat dissipation component 300 dissipates heat to the power mechanism 200 and absorbs waste heat emitted by the power mechanism 200, the heat dissipation component 300 that absorbs the waste heat heats the air flow inside the first channel 120, and the air flow led out from the first channel 120 can realize a heating function, and the air flow inside the second channel 130 is refrigerated through the refrigeration mechanism 400, so that the air flow led out from the second channel 130 can realize a refrigeration function. By utilizing the waste heat of the power mechanism 200 to realize the heating function, the waste heat generated by the power mechanism 200 is reasonably utilized, and a large amount of energy is saved.

Second embodiment

The present embodiment provides an air conditioner (not shown) which can reasonably use waste heat generated by itself, can effectively perform cooling and heating, and can save a large amount of energy. Wherein the air conditioner comprises a housing (not shown) and the temperature control system 10 provided in the first embodiment, wherein the temperature control system 10 is arranged inside the housing.

The above description is only of the preferred embodiments of the present invention and is not intended to limit the present invention, but various modifications and variations can be made to the present invention by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (8)

1. The temperature control system is applied to an air conditioner and is characterized by comprising a refrigerating mechanism, a power mechanism, a heat dissipation assembly and a temperature control mechanism, wherein the power mechanism is connected with the refrigerating mechanism and is used for driving the refrigerating mechanism;

the temperature control mechanism comprises a first drainage device, a first channel and a second channel, wherein the first drainage device is connected with the first channel and used for guiding airflow in the first channel to flow, and the first drainage device is connected with the second channel and used for guiding airflow in the second channel to flow;

the heat dissipation assembly is connected with the power mechanism and used for dissipating heat of the power mechanism, and is arranged inside the first channel so that the heat dissipation assembly can heat air flow inside the first channel;

the refrigeration mechanism is connected with the second channel and is used for refrigerating the air flow in the second channel;

the temperature control system further comprises a first airtight air valve and a second airtight air valve, wherein the first airtight air valve is arranged inside the first channel, the first airtight air valve selectively opens the first channel or closes the first channel, the second airtight air valve is arranged inside the second channel, and the second airtight air valve selectively opens the second channel or closes the second channel; the first airtight air valve and the second airtight air valve are respectively provided with corresponding control systems, and are mutually independent;

the heat dissipation assembly is arranged between the first closed air valve and the first drainage device, and the refrigerating mechanism is arranged between the first drainage device and the second closed air valve.

2. The temperature control system of claim 1, further comprising a main flow channel, wherein the first drainage device is disposed inside the main flow channel, and wherein the first channel and the second channel are in communication with the main flow channel, respectively.

3. The temperature control system of claim 1, wherein the power mechanism comprises a generator, the refrigeration mechanism comprises a compressor, the generator is coupled to the compressor, the generator is configured to provide mechanical energy to the compressor, the generator is coupled to the first flow directing device, and the generator is configured to provide electrical energy to the first flow directing device.

4. The temperature control system of claim 1, wherein the heat dissipating assembly comprises a heat dissipating water tank, a heat exchanger and a first flow channel, the heat dissipating water tank and the heat exchanger are communicated through the first flow channel and form a circulation loop, the heat dissipating water tank is connected with the power mechanism, and the heat exchanger is disposed inside the first channel.

5. The temperature control system of claim 4, wherein the heat sink assembly further comprises a first control valve coupled to the first flow channel and selectively opening the first flow channel to cause the first flow channel to be conductive or closing the first flow channel.

6. The temperature control system of claim 4, wherein the power mechanism further comprises a smoke muffler and a second water flow path, the smoke muffler being coupled to the power mechanism, the smoke muffler and the heat exchanger being in communication with the heat exchanger through the second water flow path and forming a circulation loop.

7. The temperature control system of claim 6, wherein a second control valve is provided on the second water flow passage, the second control valve selectively opening the second water flow passage to turn on the second water flow passage or closing the second water flow passage.

8. An air conditioner comprising a casing and the temperature control system according to any one of claims 1 to 7, the temperature control system being disposed inside the casing.