BR112015002987B1 - Refrigeration system for an inverter air conditioner, and inverter air conditioner - Google Patents

Abstract

REFRIGERATION SYSTEM FOR AN AIR CONDITIONING WITH INVERTER, AND, AIR CONDITIONING WITH INVERTER. A refrigeration system (10) for an inverter air conditioner and an inverter air conditioner having it are provided. The system (10) includes a compressor (100), a four-way switching valve (600), an external heat exchanger (200), a heat exchanger (300), a throttling element (400), a internal heat (500) and a check valve (700). The heat exchanger (300) is connected between a second end of the external heat exchanger (200) and a second end of the throttling element (400). The check valve (700) is connected between the second end of the external heat exchanger (200) and the second end of the throttling element (400). In cooling mode of operation the refrigerant flows from the external heat exchanger (200) to the throttling element (400), the refrigerant passes the heat exchanger (300) and bypasses the check valve (700); in the heating mode of operation when the refrigerant flows from the throttling element (400) to the external heat exchanger (200), the refrigerant passes through the check valve (700) and bypasses the heat exchanger (300).

Description

Field

[001] Embodiments of the present invention are generally related to an air conditioning field and more particularly to a refrigeration system for an inverter air conditioner and an inverter air conditioner having the same.

Rationale

[002] In the related technique a radiator connected with a refrigerant pipe is used to cool a circuit board, such that a circuit board temperature can be reduced and electronic components on it will not burn out due to an elevated temperature. Typically, a heat exchanger is generally connected in series or parallel with the pipeline after a throttling control. Since the throttling refrigerant has a low temperature, it is easy to generate condensed water, which results in a circuit board failure and shortens the life of the circuit board, so the technology has not been widely applied. In addition, the heat exchanger can also be directly connected in series between an output of an external heat exchanger and a throttling element to cool the circuit board. With this technology, a great cooling effect can be achieved without generating the condensed water in a cooling mode of operation. However, in heating operation mode, since the refrigerant temperature is too low so that condensed water may be generated due to low circuit board temperature, thus resulting in circuit board failure and shortening life. circuit board useful.

summary

[003] Embodiments of the present invention seek to solve at least one of the problems that exist in the related art to at least some extent. Accordingly, the purpose of the present disclosure is to provide a refrigerant system for an inverter air conditioner that ensures a good cooling effect on an external control box and prevents the external control box from the influence of condensed water in both operating modes. of cooling and heating.

[004] Another objective of the present disclosure is to provide an inverter air conditioner that has the refrigeration system.

[005] The refrigeration system for an inverter air conditioner according to embodiments of the present disclosure includes: a compressor having an outlet and an inlet, a four-way switching valve having first to fourth ports, the first port being connected with the compressor output and the second port being connected with the compressor input; an external heat exchanger defining a first end connected with the third port and a second end; an internal heat exchanger defining a first connected with a fourth port and a second end; a throttling member defining a first end connected with the second end of the internal heat exchanger and a second end; a heat exchanger defining a first end and a second end and configured to cool an external air conditioning control box and connected between the second end of the external heat exchanger and the second end of the throttling member; a check valve connected between the second end of the external heat exchanger and the second end of the throttling element, in which, when the refrigerant flows from the external heat exchanger to the throttling element in a cooling mode of operation, the refrigerant passes through the heat exchanger and bypasses the check valve; in which when the refrigerant flows from the throttling element to the external heat exchanger in a heating mode of operation, the refrigerant passes through the check valve and bypasses the heat exchanger.

[006] With the refrigeration system for an inverter air conditioner according to embodiments of the present disclosure, the heat exchanger is placed between the external heat exchanger and the throttling element, such that the refrigerant, which has a temperature close to at or slightly higher than ambient temperature, passes through the heat exchanger to cool the external control box. Therefore, the external control box can be cooled efficiently without reducing a compressor operating frequency even when the ambient temperature is high, such that the cooling performance of inverter air conditioner can be ensured when the ambient temperature is high. , thus improving a user's comfort. In addition, since the temperature of the refrigerant flowing in the heat exchanger is close to or slightly higher than the ambient temperature, condensed water will not be generated in the external control box and the temperature of the external control box will not be too high. reduced, such that reliability and safety of the external control box are improved. In the heating mode of operation, most of the refrigerant that flows out of the throttling element flows into the external heat exchanger through the check valve, and only a small part of the refrigerant cools the external control box, such that the temperature of the external control box can be reduced without generating the condensed water, thus ensuring the reliability of the external control box when the refrigeration system is in heating operation mode.

[007] In some embodiments the check valve includes a first valve port connected with the second end of the external heat exchanger; a second valve port connected with the first end of the heat exchanger; a third valve port connected with the second end of the heat exchanger; and a fourth valve port connected to the second end of the throttling member, wherein, the first valve port is connected to the second valve port, the third valve port is connected to the fourth valve port and a passageway between the first valve port and fourth valve port is led in one direction from the fourth valve port to the first valve port, and is cut in one direction from the first valve port to the fourth valve port.

[008] In addition, a diameter of the second valve port is smaller than a diameter of the first valve port.

[009] In some embodiments the heat exchanger includes a radiation tube, the radiation tube has a first end connected with the second end of the external heat exchanger and a second end connected with the second end of the throttling element.

[0010] In addition, the heat exchanger further includes a radiation plate which has a first surface and a second surface opposite each other, a first slit formed in the first surface, and the radiation tube is placed in the first slit.

[0011] In addition, a protrusion is placed on the second surface of the radiation plate.

[0012] In some embodiments the heat exchanger further includes a clamp plate placed on the radiation plate in a second slot formed in the clamp plate, and defines a receiving chamber configured to receive the radiation tube with the first slit.

[0013] Preferably the radiation tube is configured as a U-shaped tube.

[0014] In addition, the first slot is configured as a U-shaped slot.

[0015] The inverter air conditioner in accordance with embodiments of the present disclosure includes: a refrigeration system in accordance with the above embodiments of the present disclosure and an external control box placed adjacent to a heat exchanger of the refrigeration system.

[0016] With inverter air conditioner according to embodiments of the present disclosure, the external control box can be efficiently cooled by the refrigeration system without the condensed water generated in it, and the temperature of the external control box may not be very reduced. Thus, the inverter air conditioner according to embodiments of the present disclosure has high cooling efficiency, high performance, high reliability and high safety.

Brief description of drawings

[0017] These and other aspects and advantages of embodiments of the present invention will become apparent and more readily appreciated from the following description, made with reference to the accompanying drawings, in which:

[0018] Figure 1 is a schematic view of a refrigeration system for an inverter air conditioner according to an embodiment of the present disclosure;

[0019] Figure 2 is a partially schematic view of a refrigeration system for an inverter air conditioner according to an embodiment of the present disclosure;

[0020] Figure 3 is a schematic view of a heat exchanger from a refrigeration system to an inverter air conditioner according to an embodiment of the present disclosure, and

[0021] Figure 4 is an exploded view of a heat exchanger of a refrigeration system for an inverter air conditioner according to an embodiment of the present disclosure.

Reference numbers

[0022] Refrigeration system 10, compressor 100, external heat exchanger 200; heat exchanger 300, radiation tube 310, first subsegment 311, second subsegment 312, third subsegment 313, radiation plate 320, first slot 321, second surface 322, protrusion 323, anchor plate 330, second slot 331; throttling element 400, internal heat exchanger 500; four-way valve 600, first port a, second port b, third port c, fourth port d; check valve 700, first valve port 710, second valve port 720, third valve port 730, fourth valve port 740.

Detailed Description

[0023] Reference will be made in detail to modalities of the present disclosure. Embodiments of the present disclosure will be shown in drawings in which the same or similar elements and elements having the same or similar functions are indicated by like reference numerals throughout the descriptions. The embodiments described herein in accordance with the drawings are explanatory and illustrative, and used to generally understand the present invention. Embodiments are not intended to limit the present invention.

[0024] In the specification, unless otherwise specified or limited, relative terms such as “central”, “longitudinal”, “side”, “length”, “width”, “thickness”, “upwards”, “ below”, “front”, “rear”, “right”, “left”, “horizontal”, “vertical”, “top”, “bottom”, “inside”, “outside”, “clockwise”, “direction counterclockwise”, as well as derivatives thereof, should be imagined to refer to the orientation as then described, or as shown in the drawings under discussion. These relative terms are for convenience of description, and do not require that the present disclosure be imagined to operate in a particular orientation.

[0025] In addition, terms such as "first" and "second" are used herein for purposes of description, and are not intended to indicate or imply relative importance or significance. Thus, aspects limited by first and second are intended to indicate or imply including one or more than one of these aspects. In the description of the present disclosure "a plurality of" refers to two or more than two.

[0026] In the description of the present disclosure, unless otherwise specified or limited, it should be noted that terms "mounted", "connected", "connected" and "fixed" can be understood broadly such as permanent connection or detachable connection, electronic connection or mechanical connection, direct connection or indirect connection through an intermediary, internal communication, or interaction between two elements. Those of ordinary talent in the art should understand the specific meanings in the present disclosure in accordance with specific situations.

[0027] In the description of the present disclosure a structure in which a first aspect is over a second aspect may include an embodiment in which the first aspect directly contacts the second aspect, and may also include an embodiment in which an additional aspect is formed between the first aspect and second aspect such that the first aspect does not directly contact the second aspect unless otherwise specified. Furthermore, a first aspect over, above, or on top of a second aspect may include a modality in which the first aspect is directly "over", "above", or "on top of" the second aspect, and may also include an embodiment in which the first aspect is not directly over, above or on top of the second aspect, it just means that the first aspect has a higher sea level elevation than the sea level elevation of the second aspect. Although the first aspect down below or in the background of a second aspect may include a modality in which the first aspect is directly “underneath”, “below”, or “in the background of” the second aspect, and may also include a modality in which the first aspect is not directly "below", "below", or "at the bottom of" the second aspect, or it just means that the first aspect has a lower sea level rise than the second aspect's sea level rise.

[0028] An inverter air conditioner according to embodiments of the present disclosure will be described in the following. The inverter air conditioner according to embodiments of the present disclosure includes a refrigeration system 10 and an external control box (not shown).

[0029] First, the refrigeration system 10 for the inverter air conditioner according to embodiments of the present disclosure will be described in accordance with Figures 1-4. As shown in Figures 1-4, refrigeration system 10 in accordance with embodiments of the present disclosure includes a compressor 100, an external heat exchanger 200, a four-way switching valve 600, a heat exchanger 300, a throttling element 400 , an internal heat exchanger 500 and a check valve 700. The refrigeration system 10 has a cooling mode of operation and a heating mode of operation.

[0030] Compressor 100 has one output and one input. The four-way switch valve 600 has a first port a, a second port b, a third port c and a fourth port d. The first port a is connected with the output of the compressor and the second port b is connected with the input of the compressor. When the refrigeration system 10 is in the cooling operating mode, the first port a is connected with the third port c and the second port b is connected with the fourth port d. When the refrigeration system 10 is in heating operation mode, the first port a is connected with the fourth port d and the second port b is connected with the third port c.

[0031] The external heat exchanger 200 has a first end connected with the third port c and a second end. Internal heat exchanger 500 has a first connected with the fourth port d and a second end. The throttling element 400 has a first end connected with the second end of the internal heat exchanger 500 and a second end. Heat exchanger 300 is configured to cool the external air conditioning control box and is connected between the second end of the external heat exchanger 200 and the second end of the throttling element 400. The heat exchanger 300 has a first end and a second end.

[0032] Check valve 700 is connected between the second end of the external heat exchanger 200 and the second end of the throttling element 400. When the refrigeration system 10 is in the cooling operating mode, the refrigerant flows from the exchanger. external heat 200 to throttling element 400, the refrigerant passes through heat exchanger 300 and bypasses check valve 700; when the refrigeration system 10 is in the heating mode of operation, the refrigerant flows from the throttling element 400 to the external heat exchanger 200, the refrigerant passes through the check valve 700 and bypasses the heat exchanger 300. In In other words, the check valve 700 is led in one direction from the throttling element 400 to the external heat exchanger 200 and is cut in one direction from the external heat exchanger 200 to the throttling element 400.

[0033] That is, when the refrigeration system 10 is in the cooling operating mode, the refrigerant flowing out of the external heat exchanger 200 flows into the throttling element 400 through the heat exchanger 300 and bypasses the check valve 700. When refrigeration system 10 is in heating mode of operation, refrigerant flowing out of throttling element 400 flows into external heat exchanger 200 through check valve 700 and bypasses the exchanger. heat exchanger 300, i.e., no or only a small part of the refrigerant passes through heat exchanger 300.

[0034] In the following descriptions of the present disclosure, the first end of the external heat exchanger 200 is referred to as an inlet of the external heat exchanger 200, and the second end of the external heat exchanger 200 is referred to as an outlet of the external heat exchanger 200. external heat exchanger 200. The second end of the internal heat exchanger 500 is referred to as an inlet of the internal heat exchanger 500 and the first end of the internal heat exchanger 500 is referred to as an outlet of the internal heat exchanger 500. The first end of the heat exchanger 300 is referred to as an inlet of heat exchanger 300 and the second end of heat exchanger 300 is referred to as an outlet of heat exchanger 300. The first end of the throttling element 400 is referred to as an outlet of the heat exchanger 300. throttling 400 and the second end of throttling member 400 is referred to as an inlet of throttling 400.

[0035] It should be noted that a refrigerant flow direction in cooling operation mode is completely opposite to a refrigerant flow direction in heating operation mode. The inlet and outlet of each component (such as the external heat exchanger 200, the heat exchanger 300, the throttling element 400, and the internal heat exchanger 500) are defined with respect to the flow direction of the refrigerant in the flow mode. cooling operation. However, in heating operation or heating operation mode the inlet and outlet of each component are opposite the actual inlet and outlet of each component except compressor 100, no matter in cooling operation mode or cooling operation mode. heating, the refrigerant always flows into the compressor 100 through the inlet of the compressor 100 and flows out of the compressor 100 through the outlet of the compressor 100. For example, in the cooling mode of operation the refrigerant flows into the external heat exchanger 200. through the inlet of the external heat exchanger 200 and flows out of the external heat exchanger 200 through the outlet of the external heat exchanger 200; in operation in the heating mode of operation, the refrigerant flows into the external heat exchanger 200 through the outlet of the external heat exchanger 200 and flows out of the external heat exchanger 200 through the inlet of the external heat exchanger 200.

[0036] Specifically, the input of external heat exchanger 200 is connected to the third port c. The input of the heat exchanger 300 is connected to the output of the external heat exchanger 200. The input of the throttling element 400 is connected to the output of the heat exchanger 300. The input of the internal heat exchanger 500 is connected to the output of the throttling element 400. The output of the internal heat exchanger 500 is connected to the fourth port d. In other words, the heat exchanger 300 is placed between the external heat exchanger 200 and the throttling element 400. The external control box is adjacent to the heat exchanger 300 which facilitates cooling of the external control box through the exchanger. heat 300.

[0037] As shown in figure 1, the first port a of the four-way switching valve 600 is connected with the compressor output 100, the second port b of the four-way switching valve 600 is connected with the compressor inlet 100, the third port c of the four-way switching valve 600 is connected to the inlet of the external heat exchanger 200 and the fourth port d of the four-way switching valve 600 is connected to the output of the internal heat exchanger 500. Therefore, the system The refrigeration system 10 can cool and heat, i.e., the refrigeration system 10 has a cooling mode of operation and a heating mode of operation.

[0038] When the refrigeration system 10 is in the cooling operating mode, the first port a of the four-way switching valve 600 is connected with the third port c of the four-way switching valve 600, and the second port b of the valve four-way switching valve 600 is connected to the fourth port d of the four-way switching valve 600. As indicated by solid arrows in Figure 1, refrigerant flowing out of the compressor outlet 100 flows into the external heat exchanger 200 through the four-way switching valve 600. The refrigerant is condensed to dissipate heat from itself in the external heat exchanger 200, and a temperature of the condensed refrigerant is reduced to a temperature close to or slightly higher than an external ambient temperature. Once the check valve 700 is bypassed, the refrigerant flowing out of the external heat exchanger 200 flows into the heat exchanger 300. The refrigerant in the heat exchanger 300 absorbs heat from the external control box and cools the external control box. The coolant flowing out of the heat exchanger 300 flows into the throttling element 400 to be throtted. Refrigerant flowing out of the throttling element 400 flows into the internal heat exchanger 500 to absorb internal heat to reduce an internal temperature. Finally, the refrigerant flowing out of the internal heat exchanger 500 flows into the compressor 100 after passing through the four-way switching valve 600 and the inlet of the compressor 100, in turn thus completing a cooling cycle.

[0039] When the refrigeration system 10 is in the heating operating mode, the first port a of the four-way switching valve 600 is connected with the fourth port d of the four-way switching valve 600 and the second port b of the switching valve 600 is connected to the third port c of the four-way switch valve 600. As indicated by the dotted arrows in Figure 1, refrigerant flowing out of the compressor outlet 100 flows into the internal heat exchanger 500 through of the four-way switching valve 600 and the refrigerant in the internal heat exchanger 500 is condensed and dissipates heat from itself to increase the internal temperature. The refrigerant flowing out of the internal heat exchanger 500 flows into the throttling element 400 to be throttled. Once the check valve 700 is driven, most of the refrigerant flowing out of the throttling element 400 flows into the external heat exchanger 200 and the refrigerant in the external heat exchanger 200 is evaporated to absorb external heat. so as to reduce the outside ambient temperature. The refrigerant then flows back into the compressor 100 after passing through the four-way switching valve 600 and the compressor inlet 100, thus completing a heating cycle.

[0040] When the refrigeration system 10 is in heating operation mode, the outside ambient temperature is low and no or a small part of the refrigerant passes through the heat exchanger 100 in the heating cycle, so as to prevent the refrigerant from with a low temperature, further reduce the temperature of the external control box, thus ensuring reliability of the external control box when the refrigeration system 10 is in heating operation mode.

[0041] With the refrigeration system 10 for the inverter air conditioner according to embodiments of the present disclosure, the heat exchanger 300 is placed between the external heat exchanger 200 and the throttling element 400, such that the refrigerant having the temperature close to or slightly higher than ambient temperature passes through heat exchanger 300 to cool the external control box. Therefore, the external control box can be cooled efficiently without reducing a compressor operating frequency 100 even when the ambient temperature is high, such that an inverter air conditioner cooling performance can be ensured when the ambient temperature is high. high, thus improving a user's comfort. Furthermore, since the temperature of the refrigerant flowing into the heat exchanger is close to or slightly higher than the ambient temperature, condensed water will not be generated in the external control box, and a control box temperature external control box will not be greatly reduced, such that the reliability and safety of the external control box are improved. In the heating mode of operation, most of the refrigerant flowing out of the throttling element 400 flows into the external heat exchanger 200 through the check valve 700, and only a small part of the refrigerant cools the external control box. , whereby the temperature of the external control box can be reduced without generating the condensed water, thus ensuring the reliability of the external control box when the refrigeration system is in heating operation mode.

[0042] With inverter air conditioning according to embodiments of the present disclosure, the external control box can be efficiently cooled with the refrigeration system 10, and the condensed water will not be generated in the external control box, and the temperature of the external control box will not be greatly reduced. Thus, the inverter air conditioner according to embodiments of the present disclosure has high cooling efficiency, high performance, high reliability and high safety.

[0043] In the same working condition compared with inverter air conditioner in the related art, the temperature of the external control box according to embodiments of the present invention can be reduced by more than 15° centigrade and the operating frequency of the compressor can be increased by 20 Hz. When the outdoor temperature is higher than 35° centigrade, a cooling capacity of the inverter air conditioner according to embodiments of the present disclosure is increased by more than 10%, compared to inverter air conditioner in the related art. When the outdoor temperature is higher than 45° centigrade, a cooling capacity of the inverter air conditioner according to embodiments of the present disclosure is increased by more than 20% compared to the inverter air conditioner in the related art.

[0044] As shown in Figures 1 and 2, in some embodiments of the present disclosure the check valve has a first valve port 710, a second valve port 720, a third valve port 730, and a fourth valve port 740. The first valve port 710 is connected to the second valve port 720, the third valve port 730 is connected to the fourth valve port 740, and a passage between the first valve port 710 and the fourth valve port 740 is led in one direction from fourth valve port 740 to first valve port 710 and is cut in one direction from first valve port 710 to fourth valve port 740.

[0045] Specifically a through port may be provided inside the check valve 700 and the first valve port 710 and the second valve port 720 connected with the pass through are placed at one discharge end of the check valve, and the third valve port 730 and fourth valve port 740 connected with the through-pass are placed at an inlet end of check valve 700. The first valve port 710 is connected with the outlet of external heat exchanger 200, the second port valve port 720 is connected to the inlet of the heat exchanger 300, the third valve port 730 is connected to the outlet of the heat exchanger 300, and the fourth valve port 740 is connected to the inlet of the throttling element 400. Thus, only a small part of the refrigerant passes through heat exchanger 300 in the heating cycle, such that condensed water will not be generated in the external control box and control box temperature external will not be greatly reduced. It should be noted that a structure of check valve 700 in drawings is only an illustration taken as an example, and structure of check valve 700 is not limited thereto. The check valve 700 may be replaced by other structures, provided that the structure is led in the direction from the throttling element 400 to the external heat exchanger 200, and is bypassed in the direction from the external heat exchanger 200 to the throttling element 400.

[0046] Specifically, when the refrigeration system 10 is in the cooling operating mode, the refrigerant flowing out of the external heat exchanger 200 flows into the direct passage through the first valve port 710. Once the The first valve port 710 is placed at the discharge end of the check valve 700, the first valve port 710 is connected to the second valve port 720, the third valve port 730 is connected to the fourth valve port 740 and the passage between the first valve port 710 and the fourth valve port 740 is cut in the direction from the first valve port 710 to the fourth valve port 740, refrigerant cannot flow out of the third valve port 730 and the fourth valve port 740, but can only flow out of second valve port 720 to enter heat exchanger 300. Refrigerant flowing out of heat exchanger 300 flows into the passes through third valve port 730 and flows out of fourth valve port 740.

[0047] When the refrigeration system 10 is in heating operation mode, since the passage between the first valve port 710 and the fourth valve port 740 is conducted in the direction from the fourth valve port 740 to the first valve port 710, the refrigerant flowing out of the throttling member 400 flows into the direct passage through the fourth valve port 740 and flows out of the first valve 710. Also a small part of the refrigerant may enter the exchanger heat source 300 through third valve port 300 and/or fourth valve port 740.

[0048] Alternatively, a diameter of the second valve port 720 is smaller than a diameter of the first valve port 710. When the refrigeration system 10 is in the heating mode of operation, an amount of the refrigerant to enter the heat exchanger 300 is further reduced, such that condensed water will not be generated in the external control box and the temperature of the external control box will not be greatly reduced.

[0049] In one embodiment of the present disclosure the refrigeration system 10 further includes a controller (not shown). The controller can be placed between the second valve port 720 and the inlet of the heat exchanger 300, or between the third valve port 730 and the outlet of the heat exchanger 300. When the refrigeration system 10 is in the operating mode of cooling, the controller can be turned on. When the refrigeration system 10 is in heating operation mode, the controller can be turned off to prevent the refrigerant from entering the heat exchanger 300, such that condensed water will not be generated in the external control box and the temperature of the box external control will not be greatly reduced.

[0050] As shown in Figures 3 and 4, in some embodiments of the present disclosure the heat exchanger 300 may include a radiation tube 310. The inlet of the radiation tube 310 is connected to the output of the external heat exchanger 200 and the Radiation tube outlet 310 is connected with the inlet of throttling element 400. Therefore, heat exchanger 300 has a simple structure. In the embodiment of the present disclosure as shown in Figures 3 and 4, the radiation tube 310 has a first end connected with the second valve port 720 and a second end connected with the third valve port 730.

[0051] In an embodiment of the present disclosure as shown in Figures 3 and 4, the heat exchanger 300 further includes a radiating plate 320. The radiating plate 320 has a first surface and a second surface 322 opposite each other, and a first slot 321 is formed in the first surface. Radiation tube 310 includes a first subsegment 311, a second subsegment 312 connected with a first end of the first subsegment 311, a third subsegment 313 connected with a second end of the first subsegment 311. A portion of the first subsegment 311 is placed in the first slot 321. The second sub-segment 312 is connected to the output of the external heat exchanger 200 and the third sub-segment 313 is connected to the input of the throttling element 400. By placing the radiation plate 320, the external control box can be cooled in a similar manner. efficient.

[0052] Alternatively, the part of the first subsegment 311 may have a shape corresponding to that of the first slot 321. The first subsegment 311 may be a U-shaped slot, and thus a flow path of the coolant may be elongated such that the housing external control can be cooled efficiently. The first subsegment 311, the second subsegment 312 and the third subsegment 313 can be integrally formed. In one embodiment of the present, as shown in Figure 4, the radiation tube 310 is configured as a U-shaped tube and the first slit 321 is configured as a U-shaped slit.

[0053] As shown in Figures 3 and 4 a boss 323 is placed on the second surface 322 on the radiation plate 320. The boss 323 can contact an IPM (intelligent power module), a bridge rectifier and other elements that generate large heat in the external control box. By placing the boss 323 on the second surface 322 of the radiating plate 320, the external control box can be efficiently cooled. Alternatively, the IPM (intelligent power module), bridge rectifier and other elements that generate a lot of heat can be arranged in the same straight line over the external control box.

[0054] As shown in Figures 3 and 4, in one embodiment of the present disclosure the heat exchanger 300 further includes an attachment plate 330, and a second slot 331 is formed in the attachment plate 330. The attachment plate 330 is placed on the radiating plate 330 and the remainder of the first subsegment can be placed in the second slot 331. In other words, the second slot 331 is opposite the first slot 321 and defines a receiving chamber with the first slot 321. The first subsegment 311 is placed inside the receiving chamber. Therefore, the 300 heat exchanger has a reasonable and stable structure.

[0055] Reference throughout this specification to “a modality”, “some modalities”, “a modality”, “another example”, “an example”, “a specific example” or “a few examples”, means that an aspect particular structure, material, or feature described in connection with the embodiment or example is included in at least one embodiment or example of the present invention. Thus the appearance of phrases such as "in some modalities", "in a modality", in a modality", "in another example", "in an example", "in a specific example" or "in some instances" in several throughout this specification, are not necessarily referring to the same embodiment or example of the present invention. Furthermore, the particular features, structures, materials or features may be combined in any suitable manner in one or more embodiments or examples.

[0056] Although explanatory embodiments have been shown and described, it would be appreciated by those skilled in the art that the above embodiments cannot be imagined to limit the present invention, and changes, alternatives and modifications can be made to the embodiments without departing from the spirit, principles and scope of the present invention.

Claims (9)

1. A refrigeration system (10) for an inverter air conditioner, comprising: a compressor (100) having an outlet and an inlet; a four-way switching valve (600) having first to fourth ports, the first port being connected to the compressor outlet (100) and the second port being connected to the compressor inlet (100); an external heat exchanger (200) defining a first end connected with the third port and a second end; an internal heat exchanger (500) having a first port connected to the fourth port and a second end; a throttling member (400) defining a first end connected with the second end of the internal heat exchanger (500) and a second end; a heat exchanger (300) defining a first end and a second end and configured to cool an external air conditioning control box and connected between the second end of the external heat exchanger (200) and the second end of the throttling element (400); a check valve (700) connected between the second end of the external heat exchanger (200) and the second end of the throttling element (400), wherein when the refrigerant flows from the external heat exchanger (200) to the throttling element (400) in a cooling mode of operation, the refrigerant passes through the heat exchanger (300) and bypasses the check valve (700); wherein, when the refrigerant flows from the throttling element (400) to the external heat exchanger (200) in a heating mode of operation, the refrigerant passes through the check valve (700) and bypasses the heat exchanger (300), characterized in that the check valve (700) comprises: a first valve port (710) connected with the second end of the external heat exchanger (200); a second valve port (720) connected with the first end of the heat exchanger (300); a third valve port (730) connected with the second end of the heat exchanger (300); and a fourth valve port (740) connected with the second end of the throttling member (400), wherein the first valve port (710) is connected with the second valve port (720), the third valve port ( 730) is connected with the fourth valve port (740) and a passageway between the first valve port (710) and the fourth valve port (740) is led in one direction from the fourth valve port (740) to the first valve port (710) and is cut in one direction from the first valve port (710) to the fourth valve port (740). 2. Refrigeration system (10), according to claim 1, characterized in that a diameter of the second valve port (720) is smaller than a diameter of the first valve port (710). 3. Cooling system (10), according to claim 1, characterized in that the heat exchanger (300) comprises a radiation tube (310) and the radiation tube (310) has a first end connected with the second end of the external heat exchanger (200) and a second end connected with the second end of the throttling element (400). 4. Cooling system (10), according to claim 3, characterized in that the heat exchanger (300) further comprises a radiation plate (320) that has a first surface and a second surface opposite each other, a first slit (321) is formed in the first surface and the radiation tube (310) is placed in the first slit (321). 5. Cooling system (10), according to claim 4, characterized in that a protrusion (323) is placed on the second surface of the radiation plate (320). 6. Cooling system (10), according to claim 4, characterized in that the heat exchanger (300) also comprises a fixing plate (330) placed on the radiation plate (320), a second slot ( 331) is formed in the fixing plate (330) and defines a receiving chamber configured to receive the radiation tube (310) with the first slot (321). 7. Refrigeration system (10), according to claim 4, characterized in that the radiation tube (310) is configured as a U-shaped tube. 8. Cooling system (10), according to claim 7, characterized in that the first slot (321) is configured as a U-shaped slot. 9. Air conditioning with inverter, characterized in that it comprises: a refrigeration system (10) as defined in any one of claims 1 to 8; and an external control box placed adjacent to a heat exchanger (300) in the refrigeration system (10).

Images