CN220852670U - Condenser and refrigeration system - Google Patents

Abstract

The utility model discloses a condenser and a refrigeration system. The condenser comprises a condenser shell, a condensing heat exchange tube and a flash evaporator. The condenser shell is provided with a refrigerant inlet and a refrigerant outlet. The condensing heat exchange tube is arranged in the condenser shell, and the refrigerant enters the condenser shell from the refrigerant inlet to be condensed through the condensing heat exchange tube and flows out through the refrigerant outlet. The flash evaporator is arranged in the condenser shell and is positioned above the condensing heat exchange tube. The flash vessel includes a flash chamber and a cooling heat exchange tube bank. The flash cavity is provided with a liquid inlet, a liquid outlet and an air outlet. The liquid inlet of the flash chamber is connected with the refrigerant outlet so that the refrigerant is subjected to gas-liquid separation in the flash chamber, and the cooling heat exchange tube group is connected with the air outlet of the flash chamber. According to the utility model, the flash evaporator is arranged in the condenser shell, and the cooling heat exchange tube group for circulating the separated gaseous refrigerant is arranged in the flash evaporator, so that the superheat degree of the gaseous refrigerant in the condenser is reduced, and the refrigerant is ensured to reach the saturation temperature during condensation, so that the heat exchange efficiency is improved.

Description

Condenser and refrigeration system

Technical Field

The present utility model relates to a condenser and a refrigeration system.

Background

In the refrigerating system, the compressor applies energy to the refrigerant to raise the pressure and temperature, and then the refrigerant is condensed and throttled twice to become low-temperature and low-pressure liquid refrigerant to enter the evaporator. The liquid refrigerant absorbs heat from the surrounding environment in the evaporator and evaporates into a gaseous refrigerant, thereby achieving the aim of artificial refrigeration.

When the high-temperature high-pressure gaseous refrigerant discharged by the compressor enters the condenser, the refrigerant is in an overheated state, so that part of the refrigerant entering the condenser is not condensed due to overheating, and the heat exchange efficiency of the condenser is further affected.

It should be noted that the statements in this background section merely provide background information related to the present disclosure and may not necessarily constitute prior art.

Disclosure of utility model

The utility model provides a condenser and a refrigeration system, which are used for improving the heat exchange efficiency of the condenser.

A first aspect of the present utility model provides a condenser comprising:

a condenser housing having a refrigerant inlet and a refrigerant outlet;

The condensing heat exchange tube is arranged in the condenser shell, and the refrigerant enters the condenser shell from the refrigerant inlet to be condensed through the condensing heat exchange tube and flows out through the refrigerant outlet;

The flash evaporator is arranged in the condenser shell and is positioned above the condensation heat exchange tube, the flash evaporator comprises a flash evaporation cavity and a cooling heat exchange tube group, the flash evaporation cavity is provided with a liquid inlet, a liquid outlet and an air outlet, the liquid inlet of the flash evaporation cavity is connected with a refrigerant outlet so that the refrigerant is subjected to gas-liquid separation in the flash evaporation cavity, and the cooling heat exchange tube group is connected with the air outlet of the flash evaporation cavity.

In some embodiments, the cooling heat exchange tube bank is disposed on the underside of the flash chamber.

In some embodiments, the cooling heat exchange tube bank includes one heat exchange tube or a plurality of heat exchange tubes arranged side by side.

In some embodiments, the flash chamber comprises a slot chamber with sidewalls disposed obliquely.

In some embodiments, the cooling heat exchange tube bank includes two cooling heat exchange groupings disposed outside of the side walls of the slot die cavity, respectively.

In some embodiments, the flash chamber includes a top wall including a main body section and end sections disposed on opposite sides of the main body section, the end sections being disposed obliquely with respect to the main body section.

In some embodiments, the flash evaporator further comprises an air collecting cavity, the air collecting cavity is connected with the flash evaporation cavity and the cooling heat exchange tube group, and the gaseous refrigerant separated by flash evaporation enters the air collecting cavity from the flash evaporation cavity and then enters the cooling heat exchange tube from the air collecting cavity.

In some embodiments, the flash vessel further comprises a gas collection baffle disposed within the gas collection chamber.

In some embodiments, the flash evaporator further comprises an air outlet cavity, wherein the air outlet cavity is connected with the cooling heat exchange tube, and the gaseous refrigerant separated by flash evaporation enters the air outlet cavity after passing through the cooling heat exchange tube group.

In some embodiments, the flash vessel further comprises an air outlet baffle disposed within the air outlet chamber.

In some embodiments, the flash evaporator further comprises an air collecting cavity and an air outlet cavity arranged at two ends of the flash evaporator, the air collecting cavity comprises an air collecting port communicated with an air outlet of the flash evaporator and a first heat exchange tube connecting port communicated with the cooling heat exchange tube group, and the air outlet cavity comprises a second heat exchange tube connecting port communicated with the cooling heat exchange tube group.

In some embodiments, the flash vessel further comprises a liquid shield disposed in the flash chamber.

The second aspect of the utility model provides a refrigeration system, comprising a compressor, an evaporator and the condenser, wherein an exhaust port of the compressor is connected with a refrigerant inlet of a condenser shell, an air outlet of a flash cavity is connected with an air supplementing port of the compressor, and a liquid outlet of the flash cavity is connected with the evaporator.

Based on the technical scheme provided by the utility model, the condenser comprises a condenser shell, a condensation heat exchange tube and a flash evaporator. The condenser shell is provided with a refrigerant inlet and a refrigerant outlet. The condensing heat exchange tube is arranged in the condenser shell, and the refrigerant enters the condenser shell from the refrigerant inlet to be condensed through the condensing heat exchange tube and flows out through the refrigerant outlet. The flash evaporator is arranged in the condenser shell and is positioned above the condensing heat exchange tube. The flash vessel includes a flash chamber and a cooling heat exchange tube bank. The flash cavity is provided with a liquid inlet, a liquid outlet and an air outlet. The liquid inlet of the flash chamber is connected with the refrigerant outlet so that the refrigerant is subjected to gas-liquid separation in the flash chamber, and the cooling heat exchange tube group is connected with the air outlet of the flash chamber. The condenser shell is internally provided with the flash evaporator, and the flash evaporator is provided with the cooling heat exchange tube group for circulating the separated gaseous refrigerant. The gaseous refrigerant after flash evaporation separation of the flash evaporator flows in the cooling heat exchange tube group, and the temperature of the part of gaseous refrigerant is lower than the temperature of the gaseous refrigerant entering the top of the condenser through throttling of the first-stage throttling device, so that a temperature difference exists between the refrigerant in the cooling heat exchange tube group and the refrigerant at the top of the condenser, and the cooling heat exchange tube group can cool the overheated gas at the top of the condenser by utilizing the temperature difference so as to realize pretreatment, thereby reducing the superheat degree of the gaseous refrigerant in the condenser, and being beneficial to ensuring that the refrigerant reaches the saturation temperature during condensation and further improving the heat exchange efficiency. And when the refrigerant in the cooling heat exchange tube group exchanges heat with the superheated gas at the top of the condenser, the refrigerant in the cooling heat exchange tube group absorbs heat to be further evaporated into a gaseous state, so that the dryness of the gaseous refrigerant output by the flash evaporator is improved, and the phenomenon of liquid carrying in air suction generated when the flash evaporator supplements air for the compressor is avoided.

Other features of the present utility model and its advantages will become apparent from the following detailed description of exemplary embodiments of the utility model, which proceeds with reference to the accompanying drawings.

Drawings

The accompanying drawings, which are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate embodiments of the utility model and together with the description serve to explain the utility model and do not constitute a limitation on the utility model. In the drawings:

Fig. 1 is a schematic structural view of a condenser according to an embodiment of the present utility model.

Fig. 2 is a sectional view of the condenser shown in fig. 1 in the direction B-B.

Fig. 3 is a schematic view of a portion of a flash device according to an embodiment of the present utility model.

Fig. 4 is an exploded view of a part of the structure of the flash memory shown in fig. 3.

Fig. 5 is an exploded view of a flash device according to an embodiment of the present utility model.

Fig. 6 is a schematic structural diagram of an air outlet chamber according to an embodiment of the present utility model.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. The following description of at least one exemplary embodiment is merely exemplary in nature and is in no way intended to limit the utility model, its application, or uses. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

The relative arrangement of the components and steps, numerical expressions and numerical values set forth in these embodiments do not limit the scope of the present utility model unless it is specifically stated otherwise. Meanwhile, it should be understood that the sizes of the respective parts shown in the drawings are not drawn in actual scale for convenience of description. Techniques, methods, and apparatus known to one of ordinary skill in the relevant art may not be discussed in detail, but where appropriate, the techniques, methods, and apparatus should be considered part of the specification. In all examples shown and discussed herein, any specific values should be construed as merely illustrative, and not a limitation. Thus, other examples of the exemplary embodiments may have different values. It should be noted that: like reference numerals and letters denote like items in the following figures, and thus once an item is defined in one figure, no further discussion thereof is necessary in subsequent figures.

Spatially relative terms, such as "above … …," "above … …," "upper surface on … …," "above," and the like, may be used herein for ease of description to describe one device or feature's spatial location relative to another device or feature as illustrated in the figures. It will be understood that the spatially relative terms are intended to encompass different orientations in use or operation in addition to the orientation depicted in the figures. For example, if the device in the figures is turned over, elements described as "above" or "over" other devices or structures would then be oriented "below" or "beneath" the other devices or structures. Thus, the exemplary term "above … …" may include both orientations "above … …" and "below … …". The device may also be positioned in other different ways and the spatially relative descriptions used herein are construed accordingly.

The refrigeration system also includes a flash vessel. The main function of the flash evaporator is to separate the gas-liquid two-phase refrigerant generated after the first-stage throttling device throttles, the separated gaseous refrigerant returns to the compressor to supplement the air for the compressor, and the separated liquid refrigerant enters the second-stage throttling device.

In the related art, the flash vessel is disposed outside the condenser, increasing the unit size. In the research process, it is also found that an overheating area which does not generate phase change exists at the top of the condenser, so that the heat exchange efficiency of the condenser is reduced.

In view of the above, embodiments of the present utility model provide a condenser. The condenser is internally provided with a flash evaporator, and the flash evaporator is provided with a cooling heat exchange tube group for circulating the separated gaseous refrigerant. The gaseous refrigerant after flash evaporation separation of the flash evaporator flows in the cooling heat exchange tube group, and the temperature of the part of gaseous refrigerant is lower than the temperature of the gaseous refrigerant entering the top of the condenser through throttling of the first-stage throttling device, so that a temperature difference exists between the refrigerant in the cooling heat exchange tube group and the refrigerant at the top of the condenser, and the cooling heat exchange tube group can cool the overheated gas at the top of the condenser by utilizing the temperature difference so as to realize pretreatment, thereby reducing the superheat degree of the gaseous refrigerant in the condenser, and being beneficial to ensuring that the refrigerant reaches the saturation temperature during condensation and further improving the heat exchange efficiency. And when the refrigerant in the cooling heat exchange tube group exchanges heat with the superheated gas at the top of the condenser, the refrigerant in the cooling heat exchange tube group absorbs heat to be further evaporated into a gaseous state, so that the dryness of the gaseous refrigerant output by the flash evaporator is improved, and the phenomenon of liquid carrying in air suction generated when the flash evaporator supplements air for the compressor is avoided.

The structure and operation of the condenser according to some embodiments of the present utility model will be described in detail with reference to fig. 1 to 6.

Referring to fig. 1 to 6, a condenser according to some embodiments of the present utility model includes a condenser case 20, a condensation heat exchange tube 22, and a flash vessel 10. The condenser case 20 has a refrigerant inlet 21 and a refrigerant outlet 23. The condensing heat exchange tube 22 is disposed in the condenser housing 20, and the refrigerant enters the condenser housing 20 from the refrigerant inlet 21 to be condensed by the condensing heat exchange tube 22 and flows out through the refrigerant outlet 23. The flash vessel 10 is disposed within the condenser housing 20 above the condensing heat exchange tube 22. The flash vessel 10 includes a flash chamber 11 and a cooling heat exchange tube bank 19. The flash chamber 11 is provided with a liquid inlet, a liquid outlet and an air outlet. The liquid inlet of the flash chamber 11 is connected with a refrigerant outlet 23 so as to enable the refrigerant to be subjected to gas-liquid separation in the flash chamber 11, and the cooling heat exchange tube group 19 is connected with the air outlet of the flash chamber 11.

The condenser shell of the embodiment of the utility model is internally provided with a flash evaporator, and the flash evaporator is provided with a cooling heat exchange tube group 19 for circulating the separated gaseous refrigerant. The gaseous refrigerant after flash evaporation separation of the flash evaporator 10 flows in the cooling heat exchange tube group 19, and the temperature of the part of gaseous refrigerant is lower than the temperature of the gaseous refrigerant entering the top of the condenser through throttling of the first-stage throttling device, so that a temperature difference exists between the refrigerant in the cooling heat exchange tube group 19 and the refrigerant at the top of the condenser, and the superheated gas at the top of the condenser can be cooled by the cooling heat exchange tube group 19 by utilizing the temperature difference so as to realize pretreatment, thereby reducing the superheat degree of the gaseous refrigerant in the condenser, and being beneficial to ensuring that the refrigerant reaches the saturation temperature during condensation and further improving the heat exchange efficiency. And when the refrigerant in the cooling heat exchange tube group 19 exchanges heat with the superheated gas at the top of the condenser, the refrigerant in the cooling heat exchange tube group absorbs heat to be further evaporated into a gaseous state, so that the dryness of the gaseous refrigerant output by the flash evaporator is improved, and the phenomenon of liquid entrainment during the air supplementing of the compressor by the flash evaporator is avoided.

In some embodiments, the utility model also provides a refrigeration system. The refrigeration system of some embodiments includes a compressor, an evaporator, and a condenser. The exhaust port of the compressor is connected with the refrigerant inlet of the condenser shell. The gas outlet of the flash chamber 11 is connected with the gas supplementing port of the compressor, and the liquid outlet of the flash chamber 11 is connected with the evaporator.

The refrigeration system includes a compressor, a condenser, a first stage throttling device, a flash vessel, a second stage throttling device, and an evaporator. The refrigerant flow path is as follows: the compressor discharges high-temperature and high-pressure gaseous refrigerant, and the high-temperature and high-pressure gaseous refrigerant enters the condenser to perform condensation heat release so as to form high-temperature and high-pressure liquid refrigerant. The high-temperature high-pressure liquid refrigerant is decompressed and expanded through the first-stage throttling device, and the pressure and the temperature of the refrigerant are reduced to be changed into medium-temperature medium-pressure liquid refrigerant. The liquid refrigerant with medium temperature and medium pressure enters the flash evaporator to carry out gas-liquid separation. The gaseous refrigerant after flash separation enters into the air supplementing port of the compressor to supplement air for the compressor. The liquid refrigerant after flash separation enters the second-stage throttling device to expand and continuously enters the evaporator to absorb heat and evaporate.

The refrigerating system of the embodiment of the utility model embeds the flash evaporator which is positioned at the downstream of the condenser on the refrigerant flow path in the condenser so as to realize cooling of the overheated refrigerant of the condenser by utilizing the heat exchange between the refrigerant which is subjected to flash evaporation separation by the flash evaporator and the refrigerant which enters the condenser, namely cooling the high-temperature high-pressure gaseous refrigerant which just enters the condenser is equivalent to pretreatment, thereby reducing the superheat degree, and further enabling the refrigerant to be fully condensed when reaching the condensing heat exchange tube 22 to improve the heat exchange efficiency of the condenser.

In some embodiments, as shown in fig. 2, the refrigerant inlet 21 of the condenser housing 20 is located at the top of the condenser housing 20. The refrigerant outlet 23 of the condenser housing 20 is located at the bottom of the condenser housing 20. The high-temperature and high-pressure gaseous refrigerant enters the condenser casing 20 from the refrigerant inlet 21, and is condensed by the condensation heat exchange tube 22 in the condenser casing 20. Based on this structure, the condenser of the embodiment of the present utility model disposes the flash vessel 10 at the upper portion of the condenser case 20. Thus, the gaseous refrigerant entering the condenser shell 20 from the refrigerant inlet 21 at the top of the condenser shell 20 will first pass through the flash evaporator 10, so that the refrigerant before condensation is pretreated and cooled by the flash evaporator 10 to reduce the superheat degree, and then the gaseous refrigerant becomes saturated refrigerant when reaching the condensing heat exchange tube 22 at the lower part of the condenser shell 20, thereby realizing complete condensation and improving the heat exchange efficiency of the condenser.

Further, the refrigerant inside the cooling heat exchange tube group 19 of the flash evaporator 10 cools the refrigerant outside the flash evaporator 10, and the refrigerant inside the cooling heat exchange tube group 19 absorbs heat and heats up, so that the refrigerant inside the cooling heat exchange tube group 19 is further gasified, the dryness of the gaseous refrigerant output by the cooling heat exchange tube group 19 is improved, and the occurrence of liquid impact during air supplementing of the compressor is avoided.

As shown in fig. 2, in some embodiments, the flash vessel 10 is disposed in an upper portion of the condenser housing 20. The condensation heat exchange tube 22 is disposed at a lower portion of the condenser case 20. In this way, the refrigerant flows from the refrigerant inlet 21 to the refrigerant outlet 23, and sequentially passes through the flash evaporator 10 and the condensation heat exchange tube 22, so that the pretreatment of the flash evaporator 10 before the refrigerant is condensed is realized. The flash vessel 10 thus provided utilizes the internal space of the condenser housing 20, thereby reducing the overall height of the unit.

In some embodiments, as shown in fig. 2, the refrigerant outlet 23 of the condenser case 20 is connected with the liquid inlet of the flash vessel 10 through the communication pipe 24 such that the condensed refrigerant flows into the flash vessel 10 through the communication pipe 24. Specifically, as shown in fig. 2, the communication pipe 24 is a bent pipe to communicate the refrigerant outlet 23 with the liquid inlet of the flash evaporator 10.

In some embodiments, as shown in FIG. 2, a first stage restriction 30 is provided on the communication tube 24. The refrigerant flows out from the refrigerant outlet of the condenser housing 20, throttled by the first-stage throttle device 30, and then enters the flash evaporator 10 for flash evaporation.

Referring to fig. 2, in some embodiments, the condenser housing 20 is a cylindrical housing. The condenser housing 20 has a smaller head space in its cross section. To properly arrange the various components of the flash vessel 10, referring to fig. 3-5, in some embodiments, a cooling heat exchange tube bank 19 is disposed on the underside of the flash chamber 11. The cooling heat exchange tube group 19 is arranged at the lower side of the flash chamber 11, so that the cooling heat exchange tube group 19 can be arranged by fully utilizing the wider position of the condenser shell 20, and the cooling effect of the flash vessel 10 on the refrigerant is improved.

In some embodiments, the cooling heat exchange tube group 19 includes one heat exchange tube or a plurality of heat exchange tubes arranged side by side. In one embodiment, as shown in FIG. 5, the cooling heat exchange tube group 19 includes a plurality of heat exchange tubes arranged side by side. Thus, the heat exchange area of the refrigerant is increased, the cooling effect on the refrigerant is improved, and the superheat degree of the refrigerant is better reduced.

The flash evaporator 10 is used for separating gas from liquid of the refrigerant entering the flash evaporator 11 by the flash evaporator 11. After the gas-liquid separation, the gaseous refrigerant rises upward and the liquid refrigerant falls downward, and in order to improve the gas-liquid separation effect, referring to fig. 5, the flash chamber 11 includes a tank cavity 112. The side walls of the slot die cavity 112 are disposed obliquely. After the gas-liquid separation, the refrigerant liquid drops slide down to the bottom of the groove cavity 112 along the side wall which is obliquely arranged, so that the aggregation of the refrigerant liquid drops is facilitated.

In one embodiment, the slot die cavity 112 is a triangular cavity.

To make the flash vessel 10 more compact to occupy a smaller interior space of the condenser housing, embodiments of the present application utilize the triangular void created by the angled arrangement of the side walls of the slot die cavity 112, and in some embodiments the cooling heat exchanger tube bank 19 includes two cooling heat exchanger tube heat packs disposed outside of the two side walls, respectively. Referring to fig. 5, the flash chamber 11 is matched with the two groups of cooling heat exchange tubes in shape, and the structure is compact.

Specifically, as shown in fig. 5, the cross-sectional shape of each cooling heat exchange tube group is triangular.

As mentioned above, the condenser housing 20 of the present embodiment is a cylindrical housing. So that the head space of the condenser housing 20 is small. In some embodiments, flash chamber 11 includes a top wall 111. The top wall 111 includes a main body section and end sections disposed on both sides of the main body section, respectively, the end sections being disposed obliquely with respect to the main body section. As shown in fig. 2, the top wall 111 is adapted to the top shape of the condenser housing 20, so that the flash evaporator 10 is located closer to the top end of the condenser housing 20, so that the high-temperature and high-pressure refrigerant just entering the condenser housing 20 can be cooled by the flash evaporator 10, and the superheat degree is reduced. Moreover, the shape of the top wall 111 is adapted to the shape of the top of the condenser housing 20, so that the arrangement of the flash vessel 10 inside the condenser housing 20 is more compact.

In some embodiments, the flash 10 further comprises an air collection chamber 13. The gas collecting chamber 13 connects the flash chamber 11 and the cooling heat exchange tube group 19. The gaseous refrigerant separated by flash evaporation enters the gas collection chamber 13 from the flash evaporation chamber 11. And then from the gas collection chamber 13 to the cooling heat exchange tube group 19. That is, the gaseous refrigerant separated by flash evaporation flows from the flash evaporation chamber 11 to the gas collection chamber 13, and then flows Dong Dao from the gas collection chamber 13 to cool the heat exchange tube group 19, so that the flow path of the gaseous refrigerant is increased, and the gaseous refrigerant collides with the wall surface of the gas collection chamber 13 in the flowing process, so that the gas-liquid separation effect is further improved. The cooling heat exchange tube group 19 is arranged at the lower side of the flash chamber 11, so that the refrigerant flows from the flash chamber 11 to the gas collection chamber 13 and then flows into the cooling heat exchange tube group 19, the flowing direction of the refrigerant is changed, and the gas-liquid separation effect is improved. And particularly, in the flowing process, the flow direction of the refrigerant is changed by 180 degrees, so that the gas-liquid separation effect is better.

To further enhance the effect of gas-liquid separation, in some embodiments, the flash vessel 10 further includes a gas collection baffle disposed within the gas collection chamber 13. And the flash vessel 10 further comprises a liquid outlet pipe arranged at the bottom of the gas collecting chamber 13. Thus, the refrigerant is subjected to gravity separation and collision separation in the gas collection cavity 13 through the gas collection liquid baffle. After separation, the liquid refrigerant is collected at the bottom of the gas collecting cavity, so that a liquid outlet pipe is arranged at the bottom of the gas collecting cavity and flows back to the bottom of the evaporator, and the flash separation efficiency of the refrigerant with the built-in flash evaporator with high efficiency is ensured.

Specifically, the gas collection baffle includes an apertured baffle. The gas collecting baffle plate can also be a baffle plate.

In other embodiments, the flash vessel 10 further includes a screen disposed within the gas collection chamber 13 to further enhance separation efficiency.

In some embodiments, the flash 10 further includes an air out chamber 15. The air outlet cavity 15 is connected with the cooling heat exchange tube group 19, and the gaseous refrigerant separated by flash evaporation enters the air outlet cavity 15 after passing through the cooling heat exchange tube group 19. Similarly, the refrigerant passing through the cooling heat exchange tube group 19 collides with the wall surface of the air outlet cavity 15 in the process of entering the air outlet cavity 15, so that gas-liquid separation is realized.

As shown in FIG. 6, in some embodiments, flash vessel 10 further includes an outlet baffle 30 disposed within outlet chamber 15. The refrigerant is thus gravity separated and collided separated in the gas outlet chamber 15 by the gas outlet baffle 30. After separation, the liquid refrigerant is collected at the bottom of the air outlet cavity, so that a liquid outlet pipe 40 is arranged at the bottom of the air outlet cavity and flows back to the bottom of the evaporator, and the flash separation efficiency of the refrigerant with the built-in flash evaporator with high efficiency is ensured.

In some embodiments, as shown in fig. 3 and 4, the flash vessel 10 further includes a gas collection chamber 13 and a gas exit chamber 15 disposed at both ends of the flash chamber 11. The gas collecting cavity 13 comprises a gas collecting port communicated with the gas outlet of the flash chamber 11 and a first heat exchange tube connection port communicated with the cooling heat exchange tube group 19, and the gas outlet cavity 15 comprises a second heat exchange tube connection port communicated with the cooling heat exchange tube group 19. By the arrangement of the air outlet chamber 15 and the air collecting chamber 13, the separation efficiency of the flash memory 10 is improved.

In some embodiments, the flash 10 further comprises a liquid barrier 12 disposed in the flash chamber 11.

The structure of the condenser according to one embodiment of the present utility model will be described in detail with reference to fig. 1 to 6.

As shown in fig. 1 and 2, the condenser includes a condenser case 20, a condensation heat exchange tube 22, a flash vessel 10, a communication tube 24, and a first-stage throttling device 30.

The condenser housing 20 includes a refrigerant inlet 21 and a refrigerant outlet 23. The high-temperature and high-pressure gaseous refrigerant enters the condenser casing 20 from the refrigerant inlet 21, and is condensed by the condensation heat exchange tube 22 in the condenser casing 20. The flash vessel 10 is disposed at an upper portion of the condenser housing 20. Thus, the gaseous refrigerant entering the condenser shell 20 from the refrigerant inlet 21 at the top of the condenser shell 20 will first pass through the flash evaporator 10, so that the refrigerant before condensation is pretreated and cooled by the flash evaporator 10 to reduce the superheat degree, and then the gaseous refrigerant becomes saturated refrigerant when reaching the condensing heat exchange tube 22 at the lower part of the condenser shell 20, thereby realizing complete condensation and improving the heat exchange efficiency of the condenser.

As shown in fig. 3 to 5, the flash vessel 10 includes a flash chamber 11, a gas collecting chamber 13, a cooling heat exchange tube group 19, and a gas outlet chamber 15. The top of the flash chamber 11 is connected with a liquid inlet pipe 17. The bottom of the flash chamber 11 is connected with a liquid outlet pipe 14. A plurality of liquid baffles 12 are provided in the flash chamber 11 at intervals in the flow direction of the refrigerant. The liquid baffle 12 is a porous plate.

As shown in FIG. 4, the flash vessel 10 also includes a screen 18. The refrigerant passes through the filter screen 18 to further realize gas-liquid separation.

As shown in fig. 1, in the flash chamber 11, the gaseous refrigerant G is located above, and the liquid refrigerant L is located below, thereby achieving gas-liquid separation. The bottom of the flash chamber 11 is connected with the liquid outlet pipe 14 so that the liquid refrigerant accumulated at the bottom of the flash chamber 11 is output through the liquid outlet pipe 14.

The gas collection chamber 13 includes a first gas collection side plate 133, an arc-shaped gas collection top plate 131, a gas collection bottom plate 132, and a second gas collection side plate 134. Wherein the first gas-collecting side plate 133 and the second gas-collecting side plate 134 are disposed opposite to each other. The first gas-collecting side plate 133, the second gas-collecting side plate 134, the arc-shaped gas-collecting top plate and the gas-collecting bottom plate 132 enclose to form the gas-collecting cavity 13. The first gas collecting side plate 133 is provided with a communication port communicated with the flash chamber 11 and a plurality of first heat exchange tube connection ports arranged on two sides of the communication port. The gaseous refrigerant after flash evaporation and separation in the flash evaporation cavity 11 enters the gas collection cavity 13 through the communication port. And then enters the cooling heat exchange tube group 19 through the plurality of first heat exchange tube connection ports. Wherein the shape of the communication port is matched with the shape of the end face of the flash chamber 11.

The top of the air collecting cavity 13 in this embodiment is in an arc structure, which is matched with the shape of the condenser shell 20, so that the inner space of the air collecting cavity 13 is fully utilized, and the structure of the condenser is more compact.

The air outlet chamber 15 includes a first air outlet side plate 154, an arcuate air outlet top plate 151, a second air outlet side plate 153, and an air outlet bottom plate 152. The first air outlet side plate 154, the arc-shaped air outlet top plate 151, the second air outlet side plate 153 and the air outlet bottom plate 152 enclose to form the air outlet cavity 15. Wherein, a plurality of second heat exchange tube connection ports connected with the cooling heat exchange tube group 19 are provided on the first air outlet side plate 154. The first outlet side plate 154 is in close connection with the flash chamber 11. That is, the first air outlet side plate 154 is hermetically connected to the end face of the groove cavity 112 of the flash chamber 11. The first outlet side plate 154 thus forms both the side wall of the outlet chamber 15 and the end wall of the flash chamber 11. And further, the structure of the flash device is simple and the weight is reduced.

The top end of the air outlet cavity 15 is provided with an air outlet pipe 16. The gas refrigerant after gas-liquid separation returns to the air supply port of the compressor through the air outlet pipe 16.

The mixed state refrigerant is separated in the flash chamber 11 through large space gravity separation, collision separation and filter screen adsorption, and the separated liquid refrigerant L is collected at the bottom of the flash chamber 11 and enters the next stage throttling device through the liquid outlet pipe 14. The separated gaseous refrigerant G is concentrated at the top of the flash chamber 11. And then enters the gas collection chamber 13, the cooling heat exchange tube group 19 and the gas outlet chamber 15. And finally enters the air supplementing port of the compressor through the air outlet pipe 16.

As shown in fig. 5, the cooling heat exchange tube group 19 is connected with the gas collecting cavity 13 and the gas outlet cavity 15 to form an integrated refrigerant gas passage. All the gaseous refrigerants separated by the flash chamber enter the gas collecting chamber 13, enter the gas outlet chamber 15 through the cooling heat exchange tube group 19, and finally enter the compressor through the gas outlet tube 16 to realize intermediate gas supplementing.

The inner cavity of the condenser shell 20 can be divided into a superheating area, a condensing area and a supercooling area from top to bottom according to the heat exchange phase change. The high-temperature high-pressure gaseous superheated refrigerant entering from the top of the condenser is directly introduced into the flash chamber 11 of the flash evaporator 10 to avoid directly flushing the condensing heat exchange tube 22. The heat exchange is carried out by baffling to two sides through the flash chamber 11 and passing through the cooling heat exchange tube group 19, the condensation heat exchange tube 22 and the supercooling tube in sequence. Because a certain temperature difference exists between the cooling heat exchange tube group 19 and the inner space of the condenser shell, the superheat degree of the gaseous refrigerant in the superheat region of the condenser is greatly reduced, the gaseous refrigerant from the superheat region to the condensing region is ensured to reach a saturated state, and the high efficiency of heat exchange in the condensing region is ensured. Meanwhile, the heat exchange generated by the temperature difference of the mixed state refrigerant in the cooling heat exchange tube group 19 is further separated or evaporated, so that the dryness of the gaseous refrigerant is improved, and the phenomenon of liquid entrainment during air supplementing of the compressor is avoided.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present utility model and not for limiting the same; while the utility model has been described in detail with reference to the preferred embodiments, those skilled in the art will appreciate that: modifications may be made to the specific embodiments of the present utility model or equivalents may be substituted for part of the technical features thereof; without departing from the spirit of the utility model, it is intended to cover the scope of the utility model as claimed.

Claims (13)

1. A condenser, comprising:

A condenser housing (20) having a refrigerant inlet and a refrigerant outlet;

A condensing heat exchange tube (22) arranged in the condenser shell (20), wherein a refrigerant enters the condenser shell (20) from the refrigerant inlet to be condensed by the condensing heat exchange tube (22) and flows out from the refrigerant outlet;

The flash evaporator (10) is arranged in the condenser shell (20) and is located above the condensation heat exchange tube (22), the flash evaporator (10) comprises a flash evaporation cavity (11) and a cooling heat exchange tube group (19), the flash evaporation cavity (11) is provided with a liquid inlet, a liquid outlet and an air outlet, the liquid inlet of the flash evaporation cavity (11) is connected with a refrigerant outlet so that the refrigerant is subjected to gas-liquid separation in the flash evaporation cavity (11), and the cooling heat exchange tube group (19) is connected with the air outlet of the flash evaporation cavity (11).

2. Condenser according to claim 1, wherein the cooling heat exchanger tube bank (19) is arranged at the underside of the flash chamber (11).

3. A condenser according to claim 2, wherein the cooling heat exchange tube group (19) comprises one heat exchange tube or a plurality of heat exchange tubes arranged side by side.

4. The condenser of claim 1, wherein the flash chamber (11) comprises a tank cavity (112), the side walls of the tank cavity (112) being disposed obliquely.

5. The condenser according to claim 4, characterized in that the cooling heat exchange tube group (19) comprises two cooling heat exchange groups respectively arranged outside the side walls of the tank cavity (112).

6. The condenser according to claim 1, wherein the flash chamber (11) comprises a top wall (111), the top wall (111) comprising a main body section and end sections arranged on both sides of the main body section, respectively, the end sections being arranged obliquely with respect to the main body section.

7. The condenser according to claim 1, wherein the flash evaporator (10) further comprises an air collecting chamber (13), the air collecting chamber (13) connects the flash evaporator (11) and the cooling heat exchange tube group (19), and the gaseous refrigerant separated by flash enters the air collecting chamber (13) from the flash evaporator (11) and then enters the cooling heat exchange tube group (19) from the air collecting chamber (13).

8. The condenser of claim 7, wherein the flash vessel (10) further comprises a gas collection baffle disposed within the gas collection chamber (13).

9. The condenser according to claim 1, wherein the flash evaporator (10) further comprises an air outlet chamber (15), the air outlet chamber (15) is connected with the cooling heat exchange tube group (19), and the gaseous refrigerant separated by flash evaporation enters the air outlet chamber (15) after passing through the cooling heat exchange tube group (19).

10. The condenser of claim 9, wherein the flash vessel (10) further comprises an outlet baffle disposed within the outlet chamber (15).

11. The condenser according to claim 1, wherein the flash evaporator (10) further comprises an air collecting chamber (13) and an air outlet chamber (15) which are arranged at two ends of the flash evaporator chamber (11), the air collecting chamber (13) comprises an air collecting port communicated with an air outlet of the flash evaporator chamber (11) and a first heat exchange tube connection port communicated with the cooling heat exchange tube group (19), and the air outlet chamber (15) comprises a second heat exchange tube connection port communicated with the cooling heat exchange tube group (19).

12. The condenser of claim 1, wherein the flash vessel (10) further comprises a liquid baffle (12) disposed in the flash chamber (11).

13. A refrigeration system, characterized by comprising a compressor, an evaporator and a condenser according to any one of claims 1 to 12, wherein the exhaust port of the compressor is connected with the refrigerant inlet of the condenser housing, the air outlet of the flash chamber (11) is connected with the air supplementing port of the compressor, and the liquid outlet of the flash chamber (11) is connected with the evaporator.