阅读说明：本技术 制冷系统和制冷设备 (Refrigerating system and refrigerating equipment ) 是由 李燕 于 2021-08-23 设计创作，主要内容包括：本申请提出了一种制冷系统和制冷设备。制冷系统包括：压缩机；蒸发器,蒸发器的出口端与压缩机的进口端连接；第一冷凝器,第一冷凝器的进口端与压缩机的出口端相连,第一冷凝器的出口端与蒸发器的进口端连接；换向阀,具有第一接口、第二接口、第三接口,第一接口与压缩机的出口端连接,第三接口与蒸发器的出口端连接；第二冷凝器,第二冷凝器的进口端与第二接口连接,第二冷凝器的出口端与蒸发器的进口端连接,其中,换向阀用于切换制冷系统的工作模式。通过本申请的技术方案,可以实现压缩制冷、自然冷却两种方式同时进行制冷循环或者各自制冷循环,不需要设置中间换热介质和中间换热结构,制冷剂直接自然冷却,有利于提升自然冷却的效率。(The application provides a refrigerating system and a refrigerating device. The refrigeration system includes: a compressor; the outlet end of the evaporator is connected with the inlet end of the compressor; the inlet end of the first condenser is connected with the outlet end of the compressor, and the outlet end of the first condenser is connected with the inlet end of the evaporator; the reversing valve is provided with a first interface, a second interface and a third interface, the first interface is connected with the outlet end of the compressor, and the third interface is connected with the outlet end of the evaporator; and the inlet end of the second condenser is connected with the second interface, the outlet end of the second condenser is connected with the inlet end of the evaporator, and the reversing valve is used for switching the working mode of the refrigeration system. Through the technical scheme of this application, can realize that compression refrigeration, natural cooling two kinds of modes carry out refrigeration cycle simultaneously or refrigeration cycle separately, need not set up middle heat transfer medium and middle heat transfer structure, the direct natural cooling of refrigerant is favorable to promoting natural cooling's efficiency.)

1. A refrigeration system, comprising:

a compressor;

the outlet end of the evaporator is connected with the inlet end of the compressor;

the inlet end of the first condenser is connected with the outlet end of the compressor, and the outlet end of the first condenser is connected with the inlet end of the evaporator;

the reversing valve is provided with a first interface, a second interface and a third interface, the first interface is connected with the outlet end of the compressor, and the third interface is connected with the outlet end of the evaporator;

the inlet end of the second condenser is connected with the second interface, the outlet end of the second condenser is connected with the inlet end of the evaporator,

wherein, the reversing valve is used for switching the working mode of the refrigeration system.

2. The refrigeration system of claim 1, further comprising:

the two ends of the first pipeline are respectively connected with the inlet end of the evaporator and the outlet end of the first condenser;

the two ends of the second pipeline are respectively connected with the outlet end of the second condenser and the first pipeline;

and the check valve is arranged on the second pipeline and is used for limiting the flow direction of the fluid in the second pipeline.

3. The refrigeration system of claim 2, further comprising:

and the throttling piece is arranged on the first pipeline.

4. The refrigeration system of claim 2 or 3,

the number of the second condenser, the second pipeline, the one-way valve and the reversing valve is multiple.

5. A refrigeration system as recited in any one of claims 1 to 3 further comprising:

and two ends of the third pipeline are respectively connected with the inlet end of the evaporator and the outlet end of the second condenser.

6. The refrigeration system of claim 5, further comprising:

and the control valve is arranged on the third pipeline and is used for controlling the opening and closing of the third pipeline.

7. The refrigerant system as set forth in claim 6,

the control valve comprises any one or combination of the following components: solenoid valve, butterfly valve, ball valve.

8. The refrigerant system as set forth in claim 6,

the number of the second condenser, the third pipeline and the control valve is multiple.

9. The refrigeration system according to any one of claims 1 to 3,

the refrigeration system has an indoor side and an outdoor side, the compressor and the evaporator are arranged on the indoor side, and the first condenser and the second condenser are arranged on the outdoor side.

10. The refrigeration system according to any one of claims 1 to 3,

in the top-to-bottom direction of the refrigeration system, the distance from the outlet end of the first condenser and/or the outlet end of the second condenser to the bottom of the evaporator is larger than the distance from the inlet end of the evaporator to the bottom of the evaporator.

11. The refrigeration system according to any one of claims 1 to 3,

the first condenser includes any one of: fin heat exchangers, floating head heat exchangers, U-shaped tube plate heat exchangers and plate heat exchangers; and/or

The second condenser includes any one of: fin heat exchanger, floating head heat exchanger, U-shaped tube plate heat exchanger, plate heat exchanger.

12. The refrigeration system according to any one of claims 1 to 3,

the reversing valve comprises any one of the following components: a two-position four-way valve, a two-position three-way valve, a three-position four-way valve and a three-position three-way valve.

13. The refrigeration system according to any one of claims 1 to 3,

the refrigeration system further includes:

and the two ends of the gas-liquid separator are respectively connected with the compressor and the evaporator.

14. The refrigerant system as set forth in claim 13,

and the oil separator is respectively connected with the gas-liquid separator, the compressor, the first condenser and the first interface of the reversing valve.

15. A refrigeration apparatus, comprising:

a refrigeration system according to any one of claims 1 to 14.

Technical Field

The application belongs to the technical field of refrigeration equipment, and particularly relates to a refrigeration system and refrigeration equipment.

Background

In the field of refrigeration equipment, natural cooling technology is widely applied. However, most natural cooling technologies use an indirect cooling mode or a mixed natural cooling mode, and natural cooling is performed by water or other coolant, which causes a reduction in natural cooling efficiency due to the presence of intermediate heat exchange.

Disclosure of Invention

Embodiments according to the present application aim to ameliorate at least one of the technical problems of the prior art or the related art.

In view of the above, an object according to an embodiment of the present application is to provide a refrigeration system.

It is another object according to embodiments of the present application to provide a refrigeration device.

To achieve the above object, an embodiment according to a first aspect of the present application provides a refrigeration system, including: a compressor; the outlet end of the evaporator is connected with the inlet end of the compressor; the inlet end of the first condenser is connected with the outlet end of the compressor, and the outlet end of the first condenser is connected with the inlet end of the evaporator; the reversing valve is provided with a first interface, a second interface and a third interface, the first interface is connected with the outlet end of the compressor, and the third interface is connected with the outlet end of the evaporator; and the inlet end of the second condenser is connected with the second interface, the outlet end of the second condenser is connected with the inlet end of the evaporator, and the reversing valve is used for switching the working mode of the refrigeration system.

Embodiments according to a second aspect of the present application provide a refrigeration device comprising: the refrigeration system of any of the embodiments of the first aspect as described above.

According to the refrigeration system provided by the embodiment of the application, a first condenser and a second condenser are arranged, wherein the first condenser is connected with a compressor and can form a compression refrigeration loop together with an evaporator. And then the second condenser and the reversing valve are arranged, so that the second condenser and the evaporator can form a natural cooling loop independently, and the refrigerant can perform refrigeration circulation through the compression refrigeration loop and also can perform refrigeration circulation through the natural cooling loop. In addition, the refrigeration cycle can be simultaneously carried out by two modes of compression refrigeration and natural cooling. Therefore, an intermediate heat exchange medium and an intermediate heat exchange structure are not required to be arranged, and the refrigerant is directly and naturally cooled or is directly air-cooled, so that the natural cooling efficiency is improved. When the external environment temperature is higher, the second condenser can participate in the compression refrigeration cycle together with the first condenser through the switching of the reversing valve, and the second condenser and the first condenser disperse heat dissipation and cool down, so that the refrigeration efficiency in the compression refrigeration cycle can be improved.

Additional aspects and advantages of embodiments in accordance with the present application will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of embodiments in accordance with the present application.

Drawings

FIG. 1 is a schematic block diagram of a refrigeration system according to an embodiment provided herein;

FIG. 2 is a schematic block diagram of a refrigeration system according to another embodiment provided herein;

FIG. 3 is a schematic block diagram of a refrigeration system according to yet another embodiment provided herein;

FIG. 4 is a block diagram schematic of a refrigeration unit according to one embodiment provided herein.

Wherein, the correspondence between the reference numbers and the part names in fig. 1 to 4 is:

10 refrigeration system, 100 compressor, 102 evaporator, 104 first condenser, 106 second condenser, 108 throttling element, 110 gas-liquid separator, 112 oil separator, 120 reversing valve, 122 control valve, 124 check valve, 140 first pipeline, 142 second pipeline, 144 third pipeline, 20 refrigeration equipment.

Detailed Description

In order that the above objects, features and advantages of embodiments according to the present application may be more clearly understood, embodiments according to the present application will be described in further detail below with reference to the accompanying drawings and detailed description. It should be noted that features of embodiments according to the present application may be combined with each other without conflict.

In the following description, numerous specific details are set forth to provide a thorough understanding of embodiments according to the present application, however, embodiments according to the present application may be practiced in other ways than those described herein, and therefore the scope of protection afforded by embodiments according to the present application is not limited by the specific embodiments disclosed below.

Some embodiments provided in accordance with the present application are described below with reference to fig. 1-4.

As shown in fig. 1 to 3, an embodiment according to a first aspect of the present application proposes a refrigeration system 10, comprising a compressor 100, an evaporator 102, a first condenser 104, a second condenser 106 and a reversing valve 120.

The inlet end of the compressor 100 is connected to the outlet end of the evaporator 102. The outlet end of the compressor 100 is connected to the inlet end of a first condenser 104. The outlet end of the first condenser 104 is connected to the inlet end of the evaporator 102. Thus, the compressor 100, the first condenser 104, and the evaporator 102 may form one compression refrigeration loop. That is, the refrigerant absorbs heat in the evaporator 102 and evaporates into a gas, and then enters the compressor 100. Compressed by the compressor 100 into a high-temperature and high-pressure gas, and then introduced into the first condenser 104. The high-temperature and high-pressure gas is cooled in the first condenser 104 to form a low-temperature and high-pressure liquid. The low-temperature high-pressure liquid flows into the evaporator 102 again to absorb heat and evaporate again, so that the temperature of a medium exchanging heat with the evaporator is reduced, and a compression refrigeration cycle process is completed.

In the above process, the natural cooling cycle may not be performed, or may be performed simultaneously. Specifically, the directional valve 120 has a first port, a second port, and a third port. The first port is connected to the outlet end of the compressor 100. The second port is connected at the inlet end of the second condenser 106. The third port is connected to the outlet of the evaporator 102. The outlet of the second condenser 106 is connected to the inlet of the evaporator 102.

As shown in fig. 2, when the natural cooling cycle is required, the second port and the third port of the direction valve 120 are conducted. Thus, the inlet end of the second condenser 106 communicates with the outlet end of the evaporator 102. Since the outlet end of the second condenser 106 communicates with the inlet end of the evaporator 102, both the second condenser 106 and the evaporator 102 can form a natural cooling loop. The refrigerant absorbs heat in the evaporator 102 and evaporates, so that the temperature of the medium around the evaporator 102 is lowered, and cooling is achieved. The evaporated refrigerant gas flows into the second condenser 106, and the refrigerant gas is radiated to the second condenser 106 to be cooled, thereby raising the temperature of the medium around the second condenser 106. The cooled refrigerant flows into the evaporator 102 again, and starts to absorb heat and increase temperature again, and simultaneously reduces the temperature of the medium around the evaporator 102, thereby realizing a natural cooling cycle process. It can be understood that when the ambient temperature of the second condenser 106 is low, the natural cooling efficiency can be significantly improved by using the natural cooling method.

Of course, when the ambient temperature of the second condenser 106 is high and the natural cooling effect is not good, the second condenser 106 may also participate in the compression refrigeration cycle. Specifically, when the second condenser 106 needs to participate in the compression refrigeration cycle, the first and second ports of the direction valve 120 are communicated such that the inlet end of the second condenser 106 is communicated with the outlet end of the compressor 100. At this time, both the second condenser 106 and the first condenser 104 are in parallel. The refrigerant flows from the outlet end of the compressor 100 to both the first condenser 104 and the second condenser 106. After the refrigerant dissipates heat and cools in the first condenser 104 and the second condenser 106, the refrigerant flows into the evaporator 102 from the two condensers, absorbs heat in the evaporator 102 and heats up, and reduces the ambient temperature of the evaporator 102, so that the first condenser 104 and the second condenser 106 participate in the compression refrigeration cycle together.

According to the embodiment of the present application, a refrigeration system 10 is provided with a first condenser 104 and a second condenser 106, wherein the first condenser 104 is connected to the compressor 100 and forms a compression refrigeration loop with the evaporator 102. The second condenser 106 and the reversing valve 120 are arranged so that the second condenser 106 can form a natural cooling loop with the evaporator 102 alone, and thus, the refrigerant can perform a refrigeration cycle through the compression refrigeration loop or the natural cooling loop. In addition, the second condenser 106 can participate in the compression refrigeration cycle by switching the reversing valve 120, so that the refrigeration cycle can be simultaneously performed by two modes of compression refrigeration and natural cooling. Through the components and the connecting structure thereof, an intermediate heat exchange medium and an intermediate heat exchange structure are not required to be arranged. The refrigerant is directly cooled naturally or is directly cooled by air, so that the natural cooling efficiency is improved. When the external environment temperature is high, the second condenser 106 can participate in the compression refrigeration cycle together with the first condenser 104 by switching the reversing valve 120, and disperse, dissipate heat and reduce temperature with the first condenser 104, so that the refrigeration efficiency in the compression refrigeration cycle can be improved.

In addition, the second condenser 106 can participate in both the compression refrigeration cycle and the natural cooling cycle, which is beneficial to the full utilization of the second condenser 106, the limitation of components is reduced, and the resource is wasted.

In some embodiments, the reversing valve 120 is a four-way valve. Such as a two-position four-way valve, a three-position four-way valve. Or the diverter valve 120 may be a three-position, three-way valve, a two-position, three-way valve, etc.

It is understood that fin heat exchangers can be used in both the first condenser 104 and the second condenser 106 of the embodiments of the present application because of the natural cooling. With the fin heat exchanger, the surface areas of the first condenser 104 and the second condenser 106 are greatly increased, and accordingly, the heat exchange area is increased. Thus being beneficial to greatly improving the heat exchange efficiency.

Of course, the first condenser 104 and the second condenser 106 are not limited to the fin heat exchanger. Other types of heat exchangers are possible, and they may be the same or different.

For example, the first condenser 104 is a fin heat exchanger, and the second condenser 106 is a floating head heat exchanger. Alternatively, both the first condenser 104 and the second condenser 106 are floating head heat exchangers. Alternatively, the first condenser 104 is a plate heat exchanger and the second condenser 106 is a floating head heat exchanger. Alternatively, the first condenser 104 is a U-tube plate heat exchanger and the second condenser 106 is a plate heat exchanger. Still alternatively, the first condenser 104 is a fin heat exchanger, the second condenser 106 is a U-tube plate heat exchanger, and so on.

In the above embodiment, the natural cooling and the compression refrigeration may be performed simultaneously. That is, the first condenser 104 participates in compression refrigeration, and the second condenser 106 participates in natural cooling. Since both the first condenser 104 and the second condenser 106 are connected to the inlet end of the evaporator 102, there is also communication between the first condenser 104 and the second condenser 106. This may cause the high-temperature gas in the gas-liquid mixture flowing out of the first condenser 104 to flow into the second condenser 106, which may affect the heat exchange effect of the second condenser 106. Accordingly, in some embodiments, the refrigeration system 10 also includes a check valve 124. The flow of the gas-liquid mixture in the first condenser 104 into the second condenser 106 can be restricted by the setting of the check valve 124.

As shown in fig. 1, in particular, the refrigeration system 10 further includes a first line 140, a second line 142, and a check valve 124. One end of the first pipe 140 is connected to the inlet end of the evaporator 102. The other end of the first pipe 140 is connected to the outlet end of the first condenser 104. I.e., the inlet end of the evaporator 102 communicates with the outlet end of the first condenser 104 through a first conduit 140. One end of the second pipe 142 is connected to the first pipe 140, and the other end of the second pipe 142 is connected to the outlet end of the second condenser 106. A check valve 124 is provided on the second line 142. The flow direction of the fluid in the second pipe 142 can be restricted by the arrangement of the check valve 124, and more specifically, the check valve 124 can restrict the fluid in the first pipe 140 from flowing to the second condenser 106 through the second pipe 142. It will be appreciated that the inlet end of the check valve 124 is connected to the outlet end of the second condenser 106 and the outlet end of the check valve 124 is connected to the first conduit 140. Thus, the fluid in the first pipe 140 can only flow out from the outlet end of the second condenser 106, but not into the second condenser 106. Thus, even if a small amount of the gas-liquid mixture in the first condenser 104 enters the second pipe 142, it is blocked by the check valve 124 so that the gas-liquid mixture cannot flow into the second condenser 106.

The check valve 124 is used for blocking the gas-liquid mixture from entering the second condenser 106, the structure is simple, the number of parts is small, special control is not needed, the use is convenient, and the stability is good.

Further, a throttle 108 is provided on the first pipe 140. By providing the throttle 108, the low-temperature and high-pressure refrigerant in the first condenser 104 or the second condenser 106 can be changed into a low-temperature and low-pressure liquid during the compression refrigeration cycle, and the liquid supply amount of the evaporator 102 can be adjusted, thereby adjusting the heat exchange effect.

In any of the above embodiments, the refrigeration system 10 includes a plurality of second condensers 106. Accordingly, the refrigeration system 10 also includes a plurality of second conduits 142 and a plurality of check valves 124. The outlet end of each second condenser 106 is connected to a first pipe 140 by a second pipe 142. A one-way valve 124 is provided on each second line 142. Of course, the number of the direction valve 120 is also plural. The inlet end of each second condenser 106 is also connected to the second port of a reversing valve 120. In this way, by the arrangement of the plurality of second condensers 106 and the associated components such as the check valve 124, the second pipeline 142, the reversing valve 120, etc., the plurality of second condensers 106 can participate in natural cooling at the same time, can participate in a natural cooling cycle and a refrigeration cycle respectively, or participate in a refrigeration cycle at the same time.

As shown in fig. 1, three second condensers 106 are shown in fig. 1. Of course, the number of the second condensers 106 is not limited to three, but may be more, such as five, eight, etc., or only two, one, etc.

The following description will be given taking three second condensers 106 as an example.

As shown in fig. 1, all condensers in the refrigeration system 10 participate in the compression refrigeration cycle. The first condenser 104, the throttle member 108, the evaporator 102, and the compressor 100 sequentially constitute a compression refrigeration cycle. That is, the refrigerant absorbs heat in the evaporator 102 and evaporates, and a high-temperature low-pressure gas-liquid mixture is formed and flows into the compressor 100. After being compressed by the compressor 100, a gas-liquid mixture with high temperature and high pressure is formed, and a part of the gas-liquid mixture flows into the first condenser 104, and is subjected to heat release and condensation in the first condenser 104 to form a liquid with low temperature and high pressure, and the liquid flows back to the evaporator 102 through the first pipeline 140 and the throttling element 108, thereby completing a compression refrigeration cycle process. Meanwhile, the second port of the reversing valve 120 connected to the inlet end of each of the three second condensers 106 is communicated with the first port, so that another part of the high-temperature and high-pressure gas flowing out of the compressor 100 flows into each of the second condensers 106 through the first port and the second port of the reversing valve 120, releases heat and cools in each of the second condensers 106, flows into the first pipeline 140 through each of the second pipelines 142 and the one-way valve 124, joins with the liquid flowing out of the first condenser 104, throttles by the throttling element 108, and then flows into the evaporator 102 again together, thereby forming compression refrigeration of the whole refrigeration system 10.

Through the arrangement of the plurality of second condensers 106, the refrigerant can be cooled more dispersedly by heat release, the heat dissipation area of the refrigerant is further increased, and the heat exchange and cooling efficiency of the refrigerant is favorably improved.

As shown in fig. 2, the refrigeration system 10 may employ natural cooling entirely when the ambient temperature is sufficiently low. At full free cooling, the compressor 100 is not operated, nor does the first condenser 104 participate in free cooling. At this time, the second port and the third port of each direction valve 120 are conducted. Accordingly, the inlet end of each second condenser 106 is in communication with the outlet end of the evaporator 102.

It is understood that the refrigeration system 10 also includes a plurality of third conduits 144. Each third line 144 is disposed between the evaporator 102 and one of the second condensers 106. One end of each third pipe 144 communicates with the inlet end of the evaporator 102, and the other end of each third pipe 144 communicates with the outlet end of the second condenser 106.

In the natural cooling, each second condenser 106 is connected to the evaporator 102 through a third pipe 144 connected thereto. In this way, the liquid in each second condenser 106 after releasing heat and lowering temperature can flow into the evaporator 102.

The plurality of third pipes 144 are provided to facilitate the communication between the second condensers 106 and the evaporator 102, respectively, without interfering with each other. More importantly, the provision of a plurality of third conduits 144 allows each of the second condensers 106 to operate independently of the other.

It is understood that in some embodiments, the refrigeration system 10 also includes a plurality of control valves 122. Each control valve 122 is provided on a third line 144. The control valve 122 is disposed on the third pipeline 144 to facilitate the opening and closing of each third pipeline 144, so as to ensure the independent operation of each second condenser 106.

Specifically, by controlling the setting of the valve 122 and switching the connection of the switching valve 120, a part of the plurality of second condensers 106 can participate in the natural cooling cycle, and another part can participate in the compression refrigeration cycle.

As shown in fig. 3, three second condensers 106 are shown, the first second condenser 106 on the left side participates in the compression refrigeration cycle, and the second condenser 106 on the left side, the third second condenser 106 on the left side participates in the natural cooling cycle. The first connection and the second connection of the reversing valve 120 connected to the left first second condenser 106 are connected, so that the refrigerant flowing out of the compressor 100 can flow not only into the first condenser 104, but also into the left first second condenser 106 through the left first reversing valve 120. Accordingly, the control valve 122 on the third line 144 connected to the first and second condensers 106 on the left is closed, so that the refrigerant can only flow from the second line 142 to the first line 140 through the check valve 124, join the refrigerant flowing out of the first condenser 104, and then flow into the evaporator 102, thereby completing the compression refrigeration cycle.

Meanwhile, the second and third condensers 106 on the left participate in the natural cooling cycle, respectively. The second and third left-hand reversing valves 120, both of which have their second ports in communication with the third port, respectively communicate between the inlet ports of the second and third left-hand condensers 106 and the outlet port of the evaporator 102. At this time, the left second and third control valves 122 are all opened to conduct the left second and third pipelines 144, and correspondingly, the outlet ends of the left second and third second condensers 106 are conducted to the inlet end of the evaporator 102, so that the left second and third second condensers 106 are communicated with the evaporator 102 through the respective connected reversing valves 120 and control valves 122, thereby realizing the natural cooling cycle.

In summary, by setting the plurality of second condensers 106 and the control valves 122 and the reversing valves 120 associated therewith, not only the compression refrigeration mode of the refrigeration system 10, but also the natural cooling mode of the refrigeration system 10, and also the hybrid refrigeration mode of the refrigeration system 10 can be realized. Moreover, the plurality of second condensers 106 are arranged, so that the refrigerant can be dispersed, the heat dissipation area of the refrigerant can be increased, and the natural cooling efficiency can be improved. On the other hand, due to the arrangement of the plurality of second condensers 106, the plurality of second condensers 106 can be distributed, the respective intervals are increased, the heat sources in the surroundings of each second condenser 106 are reduced, or the heat sources on the refrigeration system 10 are distributed, and due to the respective intervals, each second condenser 106 can be in contact with more cold air, thereby further improving the natural cooling efficiency.

In the above embodiment, the control valve 122 is a solenoid valve. Of course, the control valve 122 is not limited to a solenoid valve. The control valve 122 may also be a butterfly valve, a ball valve or other valves as long as the on/off of the pipeline can be controlled.

It should be noted that in other embodiments, the control valve 122 may not be disposed on a portion of the third conduit 144. The second condenser 106 not provided with the control valve 122 may not be provided with the second pipe 142 accordingly. Thus, this portion of the second condenser 106 only needs to be controlled by the reversing valve 120 to participate in free cooling. For example, for the portion of the second condenser 106 without the second pipeline 142 and the control valve 122, when it is necessary to participate in natural cooling, the second port and the third port are communicated such that the outlet ports thereof are directly communicated with the inlet port of the evaporator 102 and the inlet port thereof is directly communicated with the outlet port of the evaporator 102, thereby achieving natural cooling. When the air conditioner does not need to participate in natural cooling or the external environment temperature is high and only compression refrigeration can be performed, all the interfaces of the reversing valve 120 connected with the second condenser 106 are disconnected, so that the second condenser 106 is disconnected from other components and does not participate in natural cooling any more.

In any of the above embodiments, the refrigeration system 10 has an indoor side and an outdoor side. Both the compressor 100 and the evaporator 102 of the refrigeration system 10 are provided on the indoor side. Because the evaporator 102 needs to exchange heat with an indoor heat source and is arranged on the indoor side for cooling, the distance between the evaporator 102 and the indoor heat source can be reduced, and the heat exchange and cooling efficiency is improved. Evaporimeter 102 and compressor 100 set up at the indoor side, and it is mainly through compression refrigeration, and is little to the reliance of environment, sets up indoor, is favorable to reducing the distance between compressor 100 and the evaporimeter 102 equally to also can promote heat transfer cooling efficiency to a certain extent, can also through shortening of pipeline length and save material, promote the efficiency of construction installation. Further, the first condenser 104 and the second condenser 106 are provided outside the outdoor. By disposing the first condenser 104 and the second condenser 106 outside the room, it is convenient to improve the heat release efficiency of the refrigerant in the condensers by using the low temperature and the flowing air outside the room, thereby improving the efficiency of natural cooling.

Further, in the embodiments of the present application, the circulation of the refrigerant in the free cooling loop is accomplished mainly depending on the characteristics of gravity and the air flow itself. Specifically, in the top-to-bottom direction of the refrigeration system 10, the distance from the outlet end of the second condenser 106 to the bottom of the evaporator 102 is greater than the distance from the inlet end of the evaporator 102 to the bottom of the evaporator 102. Alternatively, the outlet end of the second condenser 106 is positioned higher than the inlet end of the evaporator 102. In this way, the refrigerant is condensed into a liquid by heat release in the second condenser 106, and then naturally flows toward the evaporator 102 by gravity. The high-temperature refrigerant gas formed by heat absorption and evaporation in the evaporator 102 can flow from the outlet end of the evaporator 102 at a lower position to the inlet end of the second condenser 106 at a higher position by utilizing the principle of hot gas rising, and then is subjected to heat release and condensation again in the second condenser 106, thereby completing the natural cooling cycle. With the structure, a driving part is not needed to be arranged in the refrigerating system 10, so that the number of parts can be reduced, the space occupied by the refrigerating system 10 can be reduced, the energy can be saved, and the energy consumption can be reduced.

It will be appreciated that the use of gravity to circulate the refrigerant is not limited to a natural cooling cycle. In the hybrid refrigeration mode, although a part of the second condenser 106, for example, the first second condenser 106 on the left side in fig. 3, participates in the compression refrigeration cycle, the refrigerant in the second condenser 106 can still flow into the evaporator 102 under the action of gravity to complete the compression refrigeration cycle, without driving the compressor 100, thereby saving energy and reducing energy consumption.

In any of the above embodiments, the refrigeration system 10 further includes a gas-liquid separator 110 and an oil separator 112. Specifically, the gas-liquid separator 110 serves to separate gas and liquid in a gas-liquid mixture. One end of the gas-liquid separator 110 is connected to an inlet end of the compressor 100, and one end of the gas-liquid separator 110 is also connected to the oil separator 112. The other end of the gas-liquid separator 110 is connected to the outlet end of the evaporator 102. Further, the inlet end of the oil separator 112 is connected to the outlet end of the gas-liquid separator 110, and the inlet end of the oil separator 112 is also connected to the outlet end of the compressor 100. The outlet end of the oil separator 112 is connected to the inlet end of the first condenser 104. The outlet end of the oil separator 112 is also connected to the first port of the diverter valve 120.

As shown in fig. 4, an embodiment according to a second aspect of the present application provides a refrigeration apparatus 20, including: the refrigeration system 10 of any of the embodiments of the first aspect described above.

In this embodiment, by using the refrigeration system 10 of any one of the above embodiments, all the beneficial technical effects of the above embodiments are achieved, and are not described herein again.

Further, the refrigeration apparatus 20 further includes a first housing and a second housing. The first housing is used for accommodating the compressor 100, the first condenser 104, the evaporator 102 and the like, so as to provide protection for the compressor 100, the first condenser 104 and the evaporator 102, reduce interference on the components, and improve the stability and safety of the operation of the components such as the compressor 100.

The second housing is used to house a second condenser 106. The number of the second housings may be one, and one second housing accommodates a plurality of second condensers 106 therein. Alternatively, the number of the second housings is plural, and one second condenser 106 is accommodated in each second housing.

Through the setting of second casing, can provide the protection for second condenser 106, reduce the interference of external impurity, debris, promote the stability and the reliability of second condenser 106 work. The second housing may also be used to support the second condenser 106.

The second housing may be provided with a plurality of openings in consideration of the heat dissipation requirements of the second condenser 106. Further, the second housing may be configured as a frame structure, so as to increase the air flow rate on the surface of the second condenser 106, and take away the heat on the surface of the second condenser 106 as soon as possible, thereby increasing the natural cooling efficiency.

In some embodiments, the refrigeration unit 20 further includes a fan. The fan is disposed at one side of the second condenser 106, so as to accelerate the air flow around the second condenser 106, and further improve the natural cooling efficiency.

The refrigerating apparatus 20 includes any one of a central air conditioner, a mobile air conditioner, and a home air conditioner.

According to the refrigeration system 10 of some embodiments of the present application, a split type direct natural cooling technology is adopted, and the natural cooling capacity is directly transmitted to the heat source under the direct circulation of the refrigerant by the mode of the natural cooling external unit + the intermediate connection pipeline + the indoor unit, so that the temperature of the heat source is reduced, no intermediate heat exchange link is involved, and the natural cooling efficiency is significantly improved.

According to the refrigeration system 10 of the embodiment of the present application, the natural cooling cycle and the compression refrigeration cycle can be compatible and compatible, and the unit can operate the compression refrigeration cycle alone or the compression refrigeration cycle and the natural cooling cycle can be used for refrigerating simultaneously. Or it may be completely cooled naturally.

According to the refrigeration system 10 of the embodiment of the application, the natural cooling energy efficiency can be greatly improved, the energy is saved, the consumption is reduced, meanwhile, the overall structure is simpler, the number of parts is less, and the occupied space is smaller.

In the refrigeration system 10 according to the embodiment of the present application, the first condenser 104 and the second condenser 106 are installed outdoors. The evaporator 102 is installed indoors and directly exchanges heat with a heat source. The second condenser 106, the first condenser 104, and the evaporator 102 are connected by pipes, refrigerant circulates in the compressor 100, the first condenser 104, the second condenser 106, and the evaporator 102, and the first condenser 104 and the second condenser 106 are installed at a higher position than the evaporator 102.

As shown in fig. 1, after the compressor 100 compresses the refrigerant, the high-temperature and high-pressure refrigerant passes through the oil separator 112 and the reversing valve 120, and enters the first condenser 104 and the second condenser 106 to exchange heat and condense. The first condenser 104 and the second condenser 106 are both fin heat exchangers. The condensed liquid refrigerant is throttled and enters the indoor evaporator 102, and is evaporated and returned to the compressor 100, thereby completing a compression refrigeration cycle.

As shown in fig. 2, the direct free cooling cycle is illustrated as follows: after the switching valve 120 is switched, the compressor 100 is not operated. The high temperature steam in the evaporator 102 enters the three second condensers 106 through the direction change valve 120. After the refrigerant condenses, the liquid refrigerant returns to the evaporator 102 under the force of gravity through the third line 144 and the open control valve 122 on the third line 144, completing a direct free cooling cycle.

As shown in fig. 3, the hybrid natural cooling cycle is illustrated as follows: the partial directional valve 120 switches. I.e., the first reversing valve 120 on the left is shifted with respect to fig. 2. The compressor 100 is operated and the high temperature vapor in the evaporator 102 enters the first condenser 104 and the left first second condenser 106 through the reversing valve 120. After condensation, the liquid refrigerant returns to the evaporator 102 under the force of gravity, completing a compression refrigeration cycle. Meanwhile, the high-temperature steam in the evaporator 102 enters the corresponding second condenser 106 through the second and third reversing valves 120 on the left side, that is, the second condenser 106 on the left side and the third condenser 106 on the left side, and after condensation, the high-temperature steam returns to the evaporator 102 through the opened control valve 122 under the action of gravity, thereby completing the natural cooling cycle. In fig. 3, two cooling modes of the natural cooling cycle and the compression refrigeration cycle are simultaneously performed.

In embodiments according to the present application, the terms "first", "second", "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance; the term "plurality" means two or more unless expressly limited otherwise. The terms "mounted," "connected," "fixed," and the like are to be construed broadly, and for example, "connected" may be a fixed connection, a removable connection, or an integral connection; "coupled" may be direct or indirect through an intermediary. Specific meanings of the above terms in the embodiments according to the present application can be understood by those of ordinary skill in the art as the case may be.

In the description of the embodiments according to the present application, it should be understood that the terms "upper", "lower", "left", "right", "front", "rear", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, only for convenience of description and simplification of description of the embodiments according to the present application, and do not indicate or imply that the referred devices or units must have a specific direction, be configured and operated in a specific orientation, and thus, cannot be construed as limitations on the embodiments according to the present application.

In the description herein, the description of the terms "one embodiment," "some embodiments," "specific embodiments," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example in accordance with the application. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The above embodiments are merely preferred embodiments according to the present application, and are not intended to limit the embodiments according to the present application, and those skilled in the art may make various modifications and variations to the embodiments according to the present application. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the embodiments according to the present application shall be included in the protection scope of the embodiments according to the present application.