RU2721628C1 - Air conditioner and refrigeration system thereof - Google Patents

Abstract

FIELD: refrigerating equipment.

SUBSTANCE: invention relates to the refrigeration equipment. Refrigerating system (100) comprises compressor (1), four-way reversing valve (2), external heat exchanger (3), internal heat exchanger (4), first throttling device (4) and flow control unit (6). Flow control device (6) is connected in parallel to first throttling device (4), and flow control unit (6) comprises two-position valve (61), liquid storage device (62) and second throttling device (63) connected in series, wherein two-position valve (61) is connected between first throttling device (4) and second external port (32), and second throttling device (63) is connected between first throttling device (4) and second internal joint (52). Two-position valve comprises one-way solenoid valve configured to open and close pipeline, in which one-way solenoid valve is located, when refrigerating system is in cooling cycle, and made with possibility of being in normal state when cooling system is in heating cycle. One-way valve is connected in series with the one-way solenoid valve and is connected unidirectionally from the second external port towards the second internal joint.

EFFECT: technical result is providing adjustment of coolant flow rate under various operating conditions.

7 cl, 1 dwg

Description

FIELD OF TECHNOLOGY

The present invention relates to the field of refrigeration and, in particular, to a refrigeration system and an air conditioner containing such a system.

BACKGROUND

In a refrigeration system with a cooling cycle and a heating cycle, due to differences between the operating conditions and the characteristics of the system, the total amount of refrigerant required by the system during the cooling cycle or heating cycle is different. Under normal circumstances, the difference in refrigerant requirements during the cooling cycle and the heating cycle is usually from 10% to 20% or even more.

In the prior art, a separate liquid storage tank is typically added and, in general, used to balance the difference in refrigerant requirements between the cooling cycle and the heating cycle. However, in the existing solution, when the refrigeration system operates in the same operation mode (cooling mode or heating mode), but under different operating conditions, the refrigerant flow rate adjustment cannot be realized, therefore, improvement is desirable.

SUMMARY OF THE INVENTION

The present invention is directed to solving at least one of the technical problems existing in the prior art. To this end, the present invention provides a refrigeration system that can control the amount of refrigerant participating in a cycle in a system, which not only solves the problem of the difference in refrigerant needs in cooling mode and heating mode, but also solves the problem of difference in refrigerant demand under different conditions work in the same mode of operation.

The present invention also provides an air conditioner with such a refrigeration system.

A refrigeration system in accordance with embodiments of the first aspect of the present invention comprises a compressor having an exhaust port and a return port; a four-way reversing valve having a first valve port, a second valve port, a third valve port and a fourth valve port; wherein the first valve port is connected to the outlet port, and the fourth valve port is connected to the return port; an external heat exchanger having a first external port and a second external port, wherein the first external port is connected to a second valve port; an internal heat exchanger having a first inner joint and a second inner joint, the first inner joint being connected to a third valve port; a first throttling device having two ends connected to a second external port and a second internal joint, respectively; a flow control unit connected in parallel to the two ends of the first throttling device and comprising a two-position valve, a liquid storage device and a second throttling device, which are connected in series. The on-off valve is connected between the first throttling device and the second external port, and the second throttling device is connected between the first throttling device and the second inner joint.

The refrigeration system in accordance with embodiments of the invention can control the amount of refrigerant participating in the cycle in the system, which not only solves the problem of differences in refrigerant requirements in cooling mode and heating mode, but also solves the problem of difference in refrigerant requirements under different operating conditions in the same operating mode.

In addition, the refrigeration system in accordance with the invention may also have the following additional technical features.

In a preferred embodiment, the on-off valve is in the form of a two-position solenoid valve or an electric ball valve.

In a preferred embodiment, the on-off valve includes a one-way solenoid valve configured to selectively open and close a pipe in which the one-way solenoid valve is located when the refrigeration system is in the cooling cycle and configured to be in the normally on state when the refrigeration system the system is in a heating cycle; and a one-way valve connected in series with the one-way solenoid valve and configured to be unidirectionally turned on in the direction from the second external port to the second internal joint.

In a preferred embodiment, the second throttling device is in the form of a capillary tube.

In a preferred embodiment, the liquid storage device is in the form of a liquid storage tank.

In a preferred embodiment, the internal heat exchanger is in the form of a liquid-liquid heat exchanger, and the refrigeration system includes a liquid reservoir connected to an internal heat exchanger for cooling or heating the liquid in the liquid reservoir.

In a preferred embodiment, a plurality of flow control units are provided, and this plurality of flow control units are connected in parallel with each other.

In a preferred embodiment, the refrigeration system further comprises a high pressure sensor provided in an outlet port of the compressor; a low pressure sensor provided in the compressor return port; and a controller configured to communicate with the high pressure sensor, the low pressure sensor and the on-off valves of the plurality of flow control units to control the on and off of the on-off valves in the plurality of flow control units individually in accordance with the values detected by the high pressure sensor and the low pressure sensor .

An air conditioner in accordance with embodiments of the second aspect of the present invention comprises a refrigeration system in accordance with the first aspect of the present invention.

Since the refrigeration system has the above advantages, an air conditioner may have corresponding advantages in providing such a refrigeration system. That is, both in the cooling cycle and in the heating cycle, the air conditioner, in accordance with embodiments of the present invention, can control the refrigerant flow rate in the same operation mode, but under different operating conditions. The air conditioning system has the best cooling and heating effects, and the energy efficiency coefficient is greatly improved.

Additional aspects and advantages of embodiments of the present invention will be partially discussed in the following description, partially will become apparent from the following description, or will be studied in the practical use of embodiments of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS

The above and / or additional aspects and advantages of the present invention will become more apparent from the following description of embodiments with reference to the drawings, in which:

FIG. 1 is a schematic illustration of a refrigeration system in accordance with embodiments of the present invention.

Reference Positions:

refrigeration system 100;

compressor 1; outlet port 11; return port 12; high pressure sensor 13; low pressure sensor 14;

four-way reversing valve 2; a first valve port 21; second valve port 22; third valve port 23; fourth valve port 24;

external heat exchanger 3; first outer port 31; second outer port 32;

first throttling device 4;

internal heat exchanger 5; first inner joint 51; second inner joint 52;

node 6 flow control; on-off (on-off) valve 61; one-way solenoid valve 611; one-way valve 612; liquid storage device 62; a second throttling device 63;

flow path 7 for flow control; pipeline 71;

controller 8.

DETAILED DESCRIPTION

Embodiments of the present invention will be described in detail, and examples of embodiments are illustrated in the drawings. Identical or similar elements and elements having the same or similar functions are denoted by the same reference numerals throughout the description. The embodiments described below with reference to the drawings serve to explain the present invention and should not be construed as limiting the present invention.

It should be understood that the terminology used in this document with reference to the orientation or ratio of positions refers to the orientation or ratio of positions shown in the drawings, only for convenience and simplification of the description of the present invention, and is not intended to indicate or imply that said device or element must have a specific orientation or must be designed and operated in a specific orientation. Thus, this terminology should not be used to limit the present invention. Terms such as “first” and “second” are used herein for the purpose of description and are not intended to indicate or imply relative importance or imply the number of indicated technical features. Thus, a feature defined using “first” and “second” may include one or more of these features, either explicitly or implicitly. In the description of the present invention, the term “plurality” means two or more than two, unless otherwise indicated.

In the description of the present invention, unless otherwise specified or limited, the terms “installed”, “connected”, “connected” and the like are used in a broad sense and can be, for example, fixed connections, detachable connections or integral connections; may also be mechanical or electrical connections; may also be direct compounds or indirect compounds through intermediate structures; can also be internal compounds of two elements or the mutual interaction of two elements, which will be clear to specialists in this field of technology in accordance with specific situations.

A refrigeration system 100 in accordance with embodiments of the present invention will be described below with reference to FIG. 1.

As shown in FIG. 1, a refrigeration system 100 in accordance with embodiments of the present invention comprises a compressor 1, a four-way reversing valve 2, an external heat exchanger 3, an internal heat exchanger 5, a first throttling device 4, and a flow control unit 6.

The compressor 1 has an exhaust port 11 for discharging air (gaseous refrigerant) and a return port 12 for returning air (gaseous refrigerant).

The four-way reversing valve 2 has a first valve port 21, a second valve port 22, a third valve port 23 and a fourth valve port 24. The first valve port 21 is connected to the outlet port 11, and the fourth valve port 24 is connected to the return port 12. In a four-way reversing valve 2, the first port 21 can communicate with one of the second valve port 22 and the third port 23, while the fourth port 24 can communicate with the other from the second valve port 22 and the third valve port 23. Consequently, the direction of flow of the refrigerant can be changed using the four-way reversing valve 2.

As shown in FIG. 1, the external heat exchanger 3 has a first external port 31 and a second external port 32, and the first external port 31 is connected to the second valve port 22. The inner heat exchanger 5 has a first inner joint 51 and a second inner joint 52, and the first inner joint 51 is connected to the third valve port 23. Both ends of the first throttling device 4 are connected to the second outer port 32 and the second inner joint, respectively.

The refrigeration system 100 in embodiments of the present invention has a cooling mode and a heating mode. When the refrigeration system 100 is in cooling mode, the flow direction of the refrigerant is such that the refrigerant flows from the exhaust port 11 of the compressor to the outdoor heat exchanger 3 to condense and remove heat in the outdoor heat exchanger 3, is throttled by the first throttling device 4 after flowing out of the outdoor heat exchanger 3, then it flows into the internal heat exchanger 5 for evaporation and absorption of heat and finally returns to the compressor 1 through the return port 12 of the compressor 1 for compression, and thus the refrigerant is circulated. When the refrigeration system 100 is in heating mode, the flow direction of the refrigerant is such that the refrigerant flows from the outlet port of the compressor 11 to the internal heat exchanger 5 to condense and remove heat in the internal heat exchanger 5, is throttled by the first throttling device 4 after flowing out of the internal heat exchanger 5, then it flows to the external heat exchanger 3 for evaporation and absorption of heat, and finally returns to the compressor 1 through the port 12 to return the air of the compressor 1 for compression, and thus the refrigerant is circulated.

As shown in FIG. 1, the flow control unit 6 is connected in parallel to both ends of the first throttling device 4, and the flow control unit 6 comprises a two-position valve 61, a liquid storage device 62 and a second throttling device 63 connected in series. The on-off valve 61 is connected between the first throttling device 4 and the second external port 32, and the second throttling device 63 is connected between the first throttling device 4 and the second inner joint.

In other words, the flow control unit 6 is connected in parallel to the two ends of the first throttling device 4 through a pipeline. That is, the aforementioned three series-connected components in the flow control unit 6 and the connection pipes form a separate flow path 7 for controlling the flow, in parallel with the first throttling device 4.

The flow path 7 for controlling the flow may represent two different situations, namely, the open state and the closed state, when the on / off valve 61 is turned on and off. When the on / off valve 61 is turned on, the flow path 7 for controlling the flow is open and the refrigerant can flow through the whole path 7 flow rate control. When the on-off valve 61 is turned off, the flow path 7 for controlling the flow rate is closed, the refrigerant can only flow through one part of the flow path 7 for controlling the flow and cannot flow through the other part of the flow path 7 for controlling the flow due to different directions of flow of the refrigerant.

In an embodiment of the invention, the flow control unit 6 comprises a liquid storage device 62 configured to store a portion of the refrigerant, so that the flow control unit 6 can control the flow of the refrigerant involved in the cycle of the refrigeration system 100.

In particular, the control effect of the flow control unit 6 on the refrigerant in the embodiments of the present invention is based on the refrigerant characteristics with respect to temperature. In particular, the refrigerant in the system can flow from a place with a high temperature to a place with a low temperature. Therefore, in the refrigeration system 100, in accordance with embodiments of the present invention, whether or not refrigerant flows into the liquid storage device 62 depends on the operating mode of the refrigeration system 100 and depends on whether the flow path of the pipe 71 formed by the flow control unit 6 open or closed. Based on this, the principle of operation of the flow control unit 6 will be described in detail below.

When the refrigeration system 100 is in cooling mode and the on-off valve 61 is turned on, i.e. the aforementioned flow path 7 for controlling the flow is open, after exiting the second external port 32 of the external heat exchanger 3, the refrigerant is separated before being supplied to the first throttling device 4, with one part of the refrigerant flowing into the flow path 7 for controlling the flow, and the other part flows into the first throttling device 4. Since the flow path 7 for controlling the flow rate is open, the refrigerant can flow through the entire flow path, i.e. sequentially flow through a two-position valve 61, a liquid storage device 62 and a second throttling device 63. At this time, a second throttling device 63 is used to throttle the refrigerant flowing through it, so that part of the refrigerant upstream of the second throttling device 63 is in a high state temperature and high pressure relative to the other part of the refrigerant downstream from the second throttling device 63. The liquid storage device 62 is located upstream from the second throttling device 63, therefore, it should be understood that the liquid storage device 62 is connected to the high pressure end of the flow path 7 to control the flow rate, so that the temperature at the high pressure end is greater than the temperature of the liquid storage device 62. Therefore, the refrigerant will enter the liquid storage device 62 and cannot continue to flow along the original path until the liquid storage device 62 is filled with the refrigerant. Therefore, when the refrigeration system 100 is in the cooling mode and the flow path 7 for controlling the flow is opened by the on-off valve 61, a part of the refrigerant will be stored in the liquid storage device 62, so that the refrigerant flow involved in the cooling cycle will be reduced.

When the refrigeration system 100 is in cooling mode and the on-off valve 61 is turned off, that is, the above flow path 7 for controlling the flow is closed, the flow path 7 for controlling the flow is disconnected from the second external port 32 of the outdoor heat exchanger, and the refrigerant cannot flow into the flow path 7 for controlling the flow from the external heat exchanger 3. At this time, the liquid storage device 62 is connected to the second inner joint of the internal heat exchanger 5 through the second throttling device 63, but the temperature in the liquid storage device 62 is higher than the temperature at the outlet of the first throttling device 4, so that the refrigerant will not flow downstream from the first throttling device 4 into the liquid storage device 62. Therefore, all refrigerant is involved in the cooling cycle of the refrigeration system 100.

The above description relates to the operating principle of the flow control unit 6 in cooling mode, and the operation principle of the flow control unit 6 in heating mode will be described below.

When the refrigeration system 100 is in heating mode and the on-off valve 61 is turned on, that is, the flow path 7 for controlling the flow is open, after the internal heat exchanger 5 flows out of the second internal joint, the refrigerant is separated before being fed to the first throttling device 4, and a part of the refrigerant flows to path 7 flow to control the flow, and the other part flows into the first throttling device 4. Since the flow path 7 for flow control is open, the refrigerant can flow through the entire flow path, i.e. flow sequentially through the second throttling device 63, the liquid storage device 62, and the on / off valve 61. At this time, the second throttling device 63 acts to throttle the refrigerant flowing through it, so that part of the refrigerant upstream of the second throttling device 63 is in a high state temperature and high pressure with respect to the other part of the refrigerant downstream from the second throttling device 63. The liquid storage device 62 is located downstream of the second throttling device 63, therefore, the temperature in the liquid storage device 62 is lower than the inlet temperature of the second throttling device devices 63. Consequently, the refrigerant will not enter the liquid storage device 62, and thus all the refrigerant is involved in the cooling cycle of the refrigeration system 100.

When the refrigeration system 100 is in heating mode and the on-off valve 61 is turned off, that is, the aforementioned flow path 7 for controlling the flow rate is closed, the flow path 7 for controlling the flow rate is disconnected from the second external port 32 of the external heat exchanger 3, the liquid storage device 62 is connected to the second internal the joint of the internal heat exchanger 5 through the second throttling device 63, and the refrigerant at the second inner junction is throttled by the first throttling device 4. Therefore, at this time, the temperature in the second inner junction is higher than the temperature in the liquid storage device 62, so that the refrigerant will flow from the second an internal junction to the liquid storage device 62 until the liquid storage device 62 is filled with refrigerant. Therefore, when the refrigeration system 100 is in heating mode and the flow path 7 for controlling the flow rate is closed by the on-off valve 61, a part of the refrigerant will be stored in the liquid storage device 62, so that the refrigerant flow involved in the cooling cycle will be reduced.

In conclusion, for the refrigeration system 100 in accordance with embodiments of the present invention, in the cooling mode, the refrigerant flows or not into the storage liquid storage device 62, can be controlled by turning the on / off valve 61 on and off. Similarly, in the heating mode, it is also possible to control whether the refrigerant will enter the liquid storage device 62 or not by turning the on / off valve 61 on and off. Therefore, for the refrigeration system 100 in accordance with embodiments of the present invention in the same cooling mode, but under different operating conditions, the flow the refrigerant involved in the cooling cycle can be controlled by controlling the on / off valve 61 to turn it on or off, and the cooling cycle and the heating cycle of the refrigeration system 100 can provide high energy efficiency under various operating conditions. Therefore, the refrigeration system 100 in accordance with embodiments of the present invention realizes the adjustment of the amount of refrigerant participating in the system cycle, which not only solves the problem of the difference in refrigerant needs in the cooling mode and the heating mode, but also solves the problem of the difference in refrigerant demand for different working conditions in the same operating mode.

In one embodiment of the present invention, the on-off valve 61 may be a two-position solenoid valve or an electric ball valve. Therefore, it is convenient to open and close the flow path 7 for controlling the flow rate by making the on-off valve 61 in the form of a two-position solenoid valve or an electric ball valve with fewer components, convenient piping connection and high assembly efficiency.

In another embodiment of the present invention, as shown in FIG. 1, the on-off valve includes a one-way solenoid valve 611 and a one-way valve 612.

The one-way solenoid valve 611 is configured to selectively open and close a pipe in which the one-way solenoid valve 611 is located when the refrigeration system 100 is in the cooling cycle, and is configured to be in a normally on state when the refrigeration system 100 is in the heating cycle. That is, turning on and off the one-way solenoid valve 611 depends on its position and installation sequence. In embodiments of the present invention, the installation sequence of the one-way solenoid valve 611 determines that the one-way solenoid valve 611 can selectively open and close the pipe in which it is located when the refrigeration system 100 is in the cooling cycle, as shown in the example of FIG. 1, and the one-way solenoid valve 611 is in a normally on state when the refrigeration system 100 is in a heating cycle.

The one-way valve 612 is connected in series with the one-way solenoid valve 611, and the one-way valve 612 is connected unidirectionally from the second external port 32 towards the second internal joint.

The principle of operation of the one-way solenoid valve 611 and the one-way valve 612 will be described below with reference to FIG. 1.

As shown in FIG. 1, the end of the one-way solenoid valve 611 adjacent to the external heat exchanger 3 is referred to as the first end, and the other end of the one-way solenoid valve 611 remote from the external heat exchanger 3 is referred to as the second end.

When the refrigeration system 100 is in the cooling cycle, the first end of the one-way solenoid valve 611 is connected to the external high pressure heat exchanger 3, and the second end of the one-way solenoid valve 611 is connected to the internal heat exchanger 5 of low pressure. The pressure at the first end is higher than the pressure at the second end. At this time, the one-way solenoid valve 611 can turn on and off when the power is turned on and off. That is, during the cooling cycle, the flow path 7 for controlling the flow rate may be in the open state or the closed state. In addition, since the one-way valve 612 is connected unidirectionally from the second external port 32 towards the second inner joint, as described above, when the one-way solenoid valve 611 is turned on, the combined use of the one-way solenoid valve 611 with the one-way valve 612 can allow refrigerant to flow through the flow path 7 to regulate the flow, and the refrigerant can be stored in the device 62 for storing liquid. Of course, when the one-way solenoid valve 611 is turned off and the flow path 7 for controlling the flow rate is closed, the refrigerant will not enter the liquid storage device 62.

When the refrigeration system 100 is in the heating cycle, the first end of the one-way solenoid valve 611 is connected to the external low pressure heat exchanger 3, and the second end of the one-way solenoid valve 611 is connected to the internal high pressure heat exchanger 5. The pressure at the first end is lower than the pressure at the second end. At this time, the one-way solenoid valve 611 is in the on state, regardless of whether the power is on or off, and the action to turn it off cannot be performed. That is, the position of the one-way solenoid valve 611 is a normally on position during a heating cycle. Since the one-way valve 612 is connected unidirectionally from the second external port 32 towards the second inner joint and is blocked in the opposite direction, the refrigerant cannot pass through the one-way valve 612, in which case the device 62 for storing liquid together with the second throttling device 63 is connected to the second inner joint. In addition, since the second inner joint is in a high pressure and high temperature state with respect to the liquid storage device 62, the refrigerant enters the liquid storage device 62 until the liquid storage device 62 is full.

Therefore, when the on-off valve 61 is a combination of a one-way solenoid valve 611 with a one-way valve 612, the flow of refrigerant can be adjusted as required when the refrigeration system 100 is operating for cooling. During the heating operation of the refrigeration system 100, a portion of the refrigerant can be stored in the liquid storage device 62, thereby achieving the goal of less refrigerant demand for the heating system. In addition, the cost can be reduced by using a one-way solenoid valve 611 and a one-way valve 612.

In an optional embodiment of the present invention, the second throttling device 63 is a capillary tube, thereby reducing the cost. Of course, the second throttling device 63 may also be an electronic control valve.

Optionally, the liquid storage device 62 is a liquid storage tank, so that the structure of the liquid storage device 62 can be simplified and easily adapted.

In one embodiment of the present invention, the internal heat exchanger 5 is a liquid-liquid heat exchanger, and the refrigeration system 100 further comprises a liquid reservoir connected to the internal heat exchanger 5 to cool or heat the liquid in the liquid reservoir. That is, the refrigeration system 100 in accordance with embodiments of the present invention may be a wind turbine heat pump unit. In addition, since a fluid reservoir is provided, the fluid in the fluid reservoir can be cooled or heated before being transferred to a room and used in a room requiring air conditioning. Therefore, this design is suitable for use in large refrigeration equipment.

In one embodiment of the present invention, as shown in FIG. 1, a plurality of flow control units 6 are provided that are connected in parallel to each other. Turning on and off the on-off valves 61 of the plurality of flow control units 6 are independent of each other and do not interfere with each other. Therefore, a plurality of flow control units 6 connected in parallel with each other can further control the flow of refrigerant in the system cycle. For example, liquid storage devices 62 in one part of flow control units 6 may be controlled to store refrigerant, and devices in another part may be free of refrigerant to satisfy more operating conditions and more accurately control the system.

The refrigeration system 100 may further comprise a high pressure sensor 13 installed in the outlet port 11 of the compressor 1, a low pressure sensor 14 installed in the return port 12 of the compressor 1, and a controller 8. A controller 8 is connected to the high pressure sensor 13, the low pressure sensor 14, and on-off valves 61 of the plurality of flow control units 6, respectively, for controlling the on and off control of the on-off valves 61 in the plurality of flow control units 6 in accordance with the values detected by the high pressure sensor 13 and the low pressure sensor 14, respectively. That is, with a controller 8, the on and off states of the on-off valves 61 in the plurality of flow control units 6 can be controlled in accordance with the detected values of the high pressure sensor 13 and the low pressure sensor 14, respectively. Therefore, refrigerant control is more automatic, and control of the refrigeration system 100 is more accurate.

An air conditioner in accordance with embodiments of the present invention will be described below. An air conditioner in accordance with embodiments of the present invention comprises a refrigeration system 100 in accordance with the above embodiments of the present invention.

Since the refrigeration system 100 has the above advantages, the air conditioner may have corresponding advantages due to the design of the refrigeration system 100. That is, in the cooling cycle and the heating cycle of the air conditioner according to the embodiments of the present invention, the refrigerant flow participating in the system cycle can be controlled. In addition, the refrigerant flow can also be controlled in the same operating mode, but under different operating conditions. The effect of cooling and heating the air conditioning system will be better, and the energy efficiency coefficient will be greatly improved.

The reference in this description to “embodiment”, “some embodiments”, “illustrative embodiment”, “example”, “specific example” or “some examples” means that a particular feature, design, material or characteristic described in connection with an embodiment or example included in at least one embodiment or example of the present invention. The above phrases in various places throughout the present description do not necessarily refer to the same embodiment or example of the present invention. In addition, specific features, structures, materials or characteristics may be combined in any suitable manner in one or more embodiments or examples.

Although embodiments of the invention have been shown and described, those skilled in the art will appreciate that changes, modifications, alternatives, or variations can be made to these embodiments within the scope of the principles and objectives of the present invention. The scope of the present invention is limited by the claims and their equivalents.

Claims (19)

1. A refrigeration system comprising: a compressor having an outlet port and a return port; a four-way reversing valve having a first valve port, a second valve port, a third valve port and a fourth valve port, wherein the first valve port is connected to a compressor outlet port and the fourth port is connected to a compressor return port; an external heat exchanger having a first external port and a second external port, wherein the first external port is connected to a second valve port; an internal heat exchanger having a first inner joint and a second inner joint, the first inner joint being connected to a third valve port; a first throttling device having two ends connected respectively to a second external port and a second internal joint; and a flow control unit connected in parallel to the two ends of the first throttling device and comprising a two-position valve, a liquid storage device and a second throttling device connected in series, the on-off valve being connected between the first throttling device and the second external port, and the second throttling device connected between the first throttling device the device and the second internal joint; wherein the on-off valve contains: a one-way solenoid valve configured to open and close a pipe in which the one-way solenoid valve is located when the refrigeration system is in a cooling cycle, and configured to be in a normal state when the refrigeration system is in a heating cycle; and a one-way valve connected in series with a one-way solenoid valve and connected unidirectionally from the second external port towards the second internal joint. 2. The refrigeration system according to claim 1, in which the second throttling device is made in the form of a capillary tube. 3. The refrigeration system according to claim 1, in which the device for storing liquid is made in the form of a reservoir for storing liquid. 4. The refrigeration system according to claim 1, in which the internal heat exchanger is made in the form of a liquid-liquid heat exchanger, and the refrigeration system further comprises: a fluid reservoir connected to an internal heat exchanger for cooling or heating the fluid in the fluid reservoir. 5. The refrigeration system according to claim 1, in which there are many nodes of the flow control connected in parallel with each other. 6. The refrigeration system according to claim 5, further comprising: high pressure sensor in the outlet port of the compressor; low pressure sensor in the compressor return port; and a controller coupled to the high pressure sensor, the low pressure sensor and the on-off valves of the plurality of flow control units to individually control the on and off valves of the plurality of flow control units in accordance with the values determined by the high pressure sensor and the low pressure sensor. 7. An air conditioner comprising a refrigeration system according to any one of claims 1 to 6.

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