CN214276218U - Heat exchanger and air conditioner - Google Patents

Abstract

The application relates to the technical field of air conditioners and discloses a heat exchanger which comprises a gas collecting pipe, a first heat exchange flow path, a second heat exchange branch, a third heat exchange branch, a fourth heat exchange branch and a fifth heat exchange branch. The first end of a first heat exchange branch of the first heat exchange flow path is connected with the first pipe orifice of the gas collecting pipe, and the second end of the first heat exchange branch is connected with the first flow dividing element; the first end of the second heat exchange branch is connected with the second pipe orifice of the gas collecting pipe, and the second end of the second heat exchange branch is connected with the first shunt element; the first end of the third heat exchange branch is connected with a third pipe orifice of the gas collecting pipe, and the second end of the third heat exchange branch is connected with the second shunt element; the first end of the fourth heat exchange branch is connected with a fourth pipe orifice of the gas collecting pipe, and the second end of the fourth heat exchange branch is connected with the first shunt element; the first end of the fifth heat exchange branch is connected with the fifth pipe orifice of the gas collecting pipe, and the second end of the fifth heat exchange branch is connected with the second shunt element. The application provides a heat exchanger can guarantee the performance demand of heat exchanger under different mode simultaneously. The application also discloses an air conditioner.

Description

Heat exchanger and air conditioner

Technical Field

The application relates to the technical field of air conditioners, for example to a heat exchanger and an air conditioner.

Background

The existing air-conditioning product models are mostly of split structures and comprise indoor units and outdoor units which are respectively arranged indoors, wherein indoor heat exchangers of the indoor units and outdoor heat exchangers of the outdoor units are directly used for carrying out heat exchange with corresponding side environments, so that the indoor heat exchangers and the outdoor heat exchangers are key equipment of the air-conditioning products, and the refrigerating and heating performances of an air conditioner can be directly influenced by the heat exchange efficiency of the heat exchangers. In order to improve the refrigeration efficiency of the air conditioner during refrigeration operation, a supercooling section is additionally arranged on part of the heat exchangers, so that the length of a flow path of a high-temperature refrigerant in the heat exchangers is prolonged by utilizing the supercooling section, and the aim of fully exchanging heat is fulfilled.

In the process of implementing the embodiments of the present disclosure, it is found that at least the following problems exist in the related art:

the outdoor heat exchanger is taken as an example for illustration, the existing heat exchanger generally adopts a shunt pipe or a shunt to carry out shunt design, the shunt mode has no refrigerant flow direction distinction, although the refrigerant passes through the same pipeline during the cooling operation and the heating operation, the flow directions are opposite, the refrigerant can meet the cooling operation requirement through a supercooling section during the cooling operation, and the refrigerant still passes through the supercooling section during the heating operation, so that the pressure loss of the system is increased, and the overall heat exchange efficiency of the air conditioning system is reduced.

SUMMERY OF THE UTILITY MODEL

The following presents a simplified summary in order to provide a basic understanding of some aspects of the disclosed embodiments. This summary is not an extensive overview nor is intended to identify key/critical elements or to delineate the scope of such embodiments but rather as a prelude to the more detailed description that is presented later.

The embodiment of the disclosure provides a heat exchanger and an air conditioner, which are used for solving the technical problems that the pressure loss is increased, the heat exchange efficiency is reduced and the like caused by the fact that the refrigeration and heating flow directions cannot be distinguished in the shunting design of the heat exchanger in the related technology.

In some embodiments, the heat exchanger comprises: a gas collecting pipe; the first heat exchange flow path comprises one or more first heat exchange branch paths, the first end of each first heat exchange branch path is connected with the first pipe orifice of the gas collecting pipe, and the second end of each first heat exchange branch path is connected with the first flow dividing element; a first end of the first heat exchange branch is connected with a first pipe orifice of the gas collecting pipe, and a second end of the first heat exchange branch is connected with the first flow dividing element; a first end of the third heat exchange branch is connected with a third pipe orifice of the gas collecting pipe, and a second end of the third heat exchange branch is connected with the second shunt element; a first end of the fourth heat exchange branch is connected with a fourth pipe orifice of the gas collecting pipe, and a second end of the fourth heat exchange branch is connected with the first shunt element; a first end of the fifth heat exchange branch is connected with a fifth pipe orifice of the gas collecting pipe, and a second end of the fifth heat exchange branch is connected with the second shunt element; a bypass line connecting the first bypass element and the second bypass element; a first check valve disposed in the bypass line and having a direction defined from the second shunt element to the first shunt element; the second one-way valve is arranged between the first pipe orifice and the second pipe orifice of the gas collecting pipe, and the conduction direction is defined to flow from the second pipe orifice to the first pipe orifice; and the third one-way valve is arranged between the third pipe orifice and the fourth pipe orifice of the gas collecting pipe, and the conduction direction is defined to flow from the fourth pipe orifice to the third pipe orifice.

In some optional embodiments, the second check valve and the third check valve divide the gas collecting tube into a first gas collecting tube section, a second gas collecting tube section and a third gas collecting tube section from top to bottom, wherein the first tube opening is located in the first gas collecting tube section, the second tube opening and the third tube opening are located in the second gas collecting tube section, and the fourth tube opening and the fifth tube opening are located in the third gas collecting tube section.

In some alternative embodiments, the first gas header section comprises a first upper section and a first lower section, wherein the first nozzle is located in the first upper section of the first gas header section.

In some alternative embodiments, the second gas header section comprises a second upper section and a second lower section, wherein the second and third nozzles are located in the second upper section of the second gas header section.

In some alternative embodiments, the third gas header section comprises a third upper section and a third lower section, wherein the fourth and fifth nozzles are located in the third upper section of the third gas header section.

In some optional embodiments, the number of the heat exchange tubes of the first heat exchange branch is greater than or equal to the number of the heat exchange tubes of the second heat exchange branch.

In some optional embodiments, the number of the heat exchange tubes of the fourth heat exchange branch is greater than or equal to the number of the heat exchange tubes of the second heat exchange branch.

In some optional embodiments, the air conditioner comprises a refrigerant circulation loop configured by at least an indoor heat exchanger, an outdoor heat exchanger, a compressor and a four-way valve, wherein the indoor heat exchanger and/or the outdoor heat exchanger are/is the heat exchanger as described above.

In some optional embodiments, when the outdoor heat exchanger is the heat exchanger, the gas collecting pipe of the heat exchanger is communicated with the compressor, and the second flow dividing element is communicated with the indoor heat exchanger.

In some optional embodiments, when the indoor heat exchanger is the heat exchanger, the gas collecting pipe of the heat exchanger is communicated with the compressor, and the second flow dividing element is communicated with the outdoor heat exchanger.

The heat exchanger and the air conditioner provided by the embodiment of the disclosure can realize the following technical effects:

the heat exchanger that this disclosed embodiment provided includes collector, first heat transfer flow path, second heat transfer branch road, third heat transfer branch road, fourth heat transfer branch road and fifth heat transfer branch road, and sets up first check valve on shunting bypass pipeline, sets up second check valve and third check valve on the collector for the heat exchanger can carry out the refrigerant with different flow paths respectively under the air conditioner mode of difference and carry out the refrigerant. The heat exchanger adopting the split-flow design can not only enable the refrigerant flow to be downward, and prolong the length of a flow path of a high-temperature refrigerant in the heat exchanger, so that the refrigerant can fully exchange heat to realize supercooling, but also can avoid the problem of pressure loss caused by overlong flow path in the refrigerant flow downward, and accordingly can simultaneously guarantee the performance requirements of the heat exchanger in different working modes.

The foregoing general description and the following description are exemplary and explanatory only and are not restrictive of the application.

Drawings

One or more embodiments are illustrated by way of example in the accompanying drawings, which correspond to the accompanying drawings and not in limitation thereof, in which elements having the same reference numeral designations are shown as like elements and not in limitation thereof, and wherein:

FIG. 1 is a schematic diagram of a heat exchanger according to an embodiment of the present disclosure;

fig. 2 is a schematic structural diagram of another heat exchanger provided by the embodiment of the disclosure.

Reference numerals:

100: a gas collecting pipe; 101: a first header port; 111: a first nozzle; 112: a second orifice; 113: a third nozzle; 114: a fourth orifice; 115: a fifth pipe orifice; 201: a first heat exchange branch; 202: a second heat exchange branch; 203: a third heat exchange branch; 204: a fourth heat exchange branch; 205: a fifth heat exchange branch; 300: a bypass line; 401: a first check valve; 402: a second one-way valve; 403: a third check valve; 501: a first shunt element; 502: a second flow dividing element; 601: a second port.

Detailed Description

So that the manner in which the features and elements of the disclosed embodiments can be understood in detail, a more particular description of the disclosed embodiments, briefly summarized above, may be had by reference to the embodiments, some of which are illustrated in the appended drawings. In the following description of the technology, for purposes of explanation, numerous details are set forth in order to provide a thorough understanding of the disclosed embodiments. However, one or more embodiments may be practiced without these details. In other instances, well-known structures and devices may be shown in simplified form in order to simplify the drawing.

The terms "first," "second," and the like in the description and in the claims, and the above-described drawings of embodiments of the present disclosure, are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It should be understood that the data so used may be interchanged under appropriate circumstances such that embodiments of the present disclosure described herein may be made. Furthermore, the terms "comprising" and "having," as well as any variations thereof, are intended to cover non-exclusive inclusions.

In the embodiments of the present disclosure, the terms "upper", "lower", "inner", "middle", "outer", "front", "rear", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings. These terms are used primarily to better describe the disclosed embodiments and their examples and are not intended to limit the indicated devices, elements or components to a particular orientation or to be constructed and operated in a particular orientation. Moreover, some of the above terms may be used to indicate other meanings besides the orientation or positional relationship, for example, the term "on" may also be used to indicate some kind of attachment or connection relationship in some cases. The specific meanings of these terms in the embodiments of the present disclosure can be understood by those of ordinary skill in the art as appropriate.

In addition, the terms "disposed," "connected," and "secured" are to be construed broadly. For example, "connected" may be a fixed connection, a detachable connection, or a unitary construction; can be a mechanical connection, or an electrical connection; may be directly connected, or indirectly connected through intervening media, or may be in internal communication between two devices, elements or components. Specific meanings of the above terms in the embodiments of the present disclosure can be understood by those of ordinary skill in the art according to specific situations.

The term "plurality" means two or more unless otherwise specified.

In the embodiment of the present disclosure, the character "/" indicates that the preceding and following objects are in an or relationship. For example, A/B represents: a or B.

The term "and/or" is an associative relationship that describes objects, meaning that three relationships may exist. For example, a and/or B, represents: a or B, or A and B.

It should be noted that, in the case of no conflict, the embodiments and features in the embodiments of the present disclosure may be combined with each other.

The air conditioner comprises an indoor unit and an outdoor unit, wherein the indoor unit is provided with an indoor heat exchanger, an indoor fan and the like and can be used for realizing the functions of heat exchange and the like between a refrigerant and an indoor environment in a matching way; the outdoor unit is provided with an outdoor heat exchanger, an outdoor fan, a throttle valve, a compressor, a gas-liquid separator and the like, and can be used for realizing the functions of heat exchange, refrigerant compression, refrigerant throttling and the like by matching with a refrigerant and an outdoor environment.

The indoor heat exchanger, the outdoor heat exchanger, the throttle valve, the compressor, the gas-liquid separator and other components are connected through refrigerant pipelines to form a refrigerant circulating system for circularly conveying the refrigerant between the indoor unit and the outdoor unit; optionally, the refrigerant circulation system is at least limited to two refrigerant flow directions respectively used for a refrigeration mode or a heating mode, specifically, when the air conditioner operates in the refrigeration mode, the refrigerant circulation system conveys the refrigerant in a first refrigerant flow direction, and after being discharged from the compressor, the refrigerant sequentially flows through the outdoor heat exchanger, the throttle valve and the indoor heat exchanger, and then flows back to the compressor through the gas-liquid separator; and when the air conditioner operates in a heating mode, the refrigerant circulating system conveys the refrigerant in a second refrigerant flow direction, and the refrigerant flows through the indoor heat exchanger, the throttle valve and the outdoor heat exchanger in sequence after being discharged from the compressor and then flows back to the compressor through the gas-liquid separator.

In the heat exchanger and the air conditioner related to the embodiment of the disclosure, the heat exchanger can respectively convey refrigerants through different flow paths in different air conditioning modes through the arrangement of the bypass flow dividing pipeline and the one-way valve, so that the performance requirements of the heat exchanger in different working modes can be simultaneously ensured. Most of the embodiments provided by the application are the embodiments when the heat exchanger is used as an outdoor heat exchanger.

The disclosed embodiment provides a heat exchanger.

As shown in fig. 1 and fig. 2, an embodiment of the present disclosure provides a heat exchanger, where the heat exchanger includes a gas collecting pipe 100, a first heat exchange flow path, a second heat exchange branch 202, a third heat exchange branch 203, a fourth heat exchange branch 204, and a fifth heat exchange branch 205, and a first heat exchange flow path, a second heat exchange branch 202, and a third heat exchange branch 203 of the heat exchanger are sequentially connected in series to form a first series flow path, and the first heat exchange flow path, the fourth heat exchange branch 204, and the fifth heat exchange branch 205 are sequentially connected in series to form a second series flow path, so as to achieve an effect of increasing a length of a refrigerant flow path to increase a heat exchange time, thereby achieving a purpose of "supercooling" at a lower refrigerant temperature, and improving refrigeration efficiency; the heating flow is downward, and the first heat exchange flow path, the second heat exchange branch 202, the third heat exchange branch 203, the fourth heat exchange branch 204 and the fifth heat exchange branch 205 of the heat exchanger are communicated in parallel, so that the problem of pressure loss caused by overlong flow paths can be avoided downward in the heating flow, and the heating efficiency is improved.

In an embodiment, the same structural design is adopted for the structures of the single heat exchange tubes in the first heat exchange branch 201, the second heat exchange branch 202, the third heat exchange branch 203, the fourth heat exchange branch 204 and the fifth heat exchange branch 205, for example, the pipe diameters of the single heat exchange tubes in the first heat exchange branch 201, the second heat exchange branch 202, the third heat exchange branch 203, the fourth heat exchange branch 204 and the fifth heat exchange branch 205 are the same, the pipe wall thicknesses are uniform, the curvatures and lengths of the bent pipes are the same, and the like, so that the refrigerant can uniformly flow in the heat exchanger, and unstable changes of the pressure and the flow rate of the refrigerant caused by the pipe diameter changes are avoided, so that the refrigerant can stably realize heat exchange with the surrounding environment when flowing through the heat exchanger.

The above-mentioned body definition mainly is to the division that each part pipeline down of refrigeration flow played the refrigerant, but does not constitute the restriction to structural design, the heat transfer effect of heating flow direction etc. of this application heat exchanger.

As shown in fig. 1 and 2, a heat exchanger provided in an embodiment of the present disclosure includes: the gas collecting pipe 100, the first heat exchange flow path, the second heat exchange branch 202, the third heat exchange branch 203, the fourth heat exchange branch 204 and the fifth heat exchange branch 205. The first heat exchange flow path comprises one or more first heat exchange branches 201, a first end of each first heat exchange branch 201 is connected with the first nozzle 111 of the gas collecting pipe 100, and a second end of each first heat exchange branch 201 is connected with the first flow dividing element 501; the first end of the second heat exchange branch 202 is connected with the second pipe orifice 112 of the gas collecting pipe 100, and the second end is connected with the first flow dividing element 501; the first end of the third heat exchange branch 203 is connected with the third pipe orifice 113 of the gas collecting pipe 100, and the second end is connected with the second flow dividing element 502; a first end of the fourth heat exchange branch 204 is connected with the fourth port 114 of the gas collecting pipe 100, and a second end is connected with the first shunt element 501; a first end of the fifth heat exchange branch 205 is connected with the fifth nozzle 115 of the gas collecting pipe 100, and a second end is connected with the second flow dividing element 502; the shunt bypass line 300 connects the first shunt element 501 and the second shunt element 502; the first check valve 401 is disposed in the bypass line 300, and the direction of conduction is defined as flowing from the second flow splitting element 502 to the first flow splitting element 501; the second check valve 402 is disposed between the first pipe orifice 111 and the second pipe orifice 112 of the gas collecting pipe 100, and the conducting direction is defined as flowing from the second pipe orifice 112 to the first pipe orifice 111; the third check valve 403 is disposed between the third nozzle 113 and the fourth nozzle 114 of the gas collecting pipe 100, and the conducting direction is defined as flowing from the fourth nozzle 114 to the third nozzle 113.

The heat exchanger provided by the embodiment of the present disclosure includes a gas collecting pipe 100, a first heat exchange flow path, a second heat exchange branch 202, a third heat exchange branch 203, a fourth heat exchange branch 204, and a fifth heat exchange branch 205. The refrigerating flow is downward, and the flow path of the gaseous refrigerant in the heat exchanger is as follows: the refrigerant enters through the first main port 101 of the gas collecting pipe 100, flows through the first pipe orifice 111, flows through the first heat exchange flow path, and is divided into two paths, the first path flows through the second heat exchange branch 202 and the third heat exchange branch 203 and flows out of the heat exchanger through the second main port 603, and the second path flows through the fourth heat exchange branch 204 and the fifth heat exchange branch 205 and flows out of the heat exchanger through the second main port 603. It can be seen that, the heat exchanger provided by the embodiment of the present disclosure has a downward refrigerant flow, and due to the arrangement of the first check valve 401, the second check valve 402 and the third check valve 403, the length of a refrigerant path flowing downward in a refrigeration flow direction is increased, and the heat exchange time of the refrigerant in the heat exchanger is prolonged, so that the refrigerant can exchange heat with the surrounding environment sufficiently, and the refrigeration efficiency of the air conditioner is improved.

Taking the example that the first heat exchange flow path includes two heat exchange branches, when the heat flow is downward, the refrigerant enters through the second header 603 and is divided into six branches, and the first branch passes through the first check valve 401, flows through the first heat exchange branch 201, and flows out from the first header 101; the second branch passes through the first check valve 401, flows through the other first heat exchange branch 201 and flows out of the first main port 101; the third branch passes through the first check valve 401, flows through the second heat exchange branch 202, passes through the second check valve 402, and flows out of the first main port 101; the fourth branch passes through the first check valve 401, flows through the fourth heat exchange branch 204, passes through the third check valve 403 and the second check valve 402, and then flows out of the first main port 101; the fifth branch flows through the third heat exchange branch 203, passes through the second one-way valve 402 and flows out of the first main port 101; the sixth branch flows through the fifth heat exchange branch 205, passes through the third check valve 403 and the second check valve 402, and then flows out of the first main port 101. It can be seen that in the heat exchanger provided by the embodiment of the present disclosure, due to the arrangement of the first check valve 401, the second check valve 402 and the third check valve 403, the first heat exchange flow path, the second heat exchange branch 202, the third heat exchange branch 203, the fourth heat exchange branch 204 and the fifth heat exchange branch 205 are connected in parallel, so that the problem of pressure loss caused by an excessively long flow path is avoided, and the heating efficiency is improved.

Optionally, the first flow splitting element 501 comprises one or more flow splitters and similarly, the second flow splitting element 502 comprises one or more flow splitters. Wherein the flow divider is a flow dividing element having one or more inflow inlets and one or more outflow outlets, optionally the flow divider is cylindrical and the interior is a brass type flow divider of hollow construction.

Optionally, the inner diameter of the gas collecting tube 100 is greater than the inner diameter of a single heat exchange tube in the first heat exchange branch 201, the second heat exchange branch 202, the third heat exchange branch 203, the fourth heat exchange branch 204 and the fifth heat exchange branch 205, and the wall thickness of the gas collecting tube 100 is greater than the wall thickness of a single heat exchange tube in the first heat exchange branch 201, the second heat exchange branch 202, the third heat exchange branch 203, the fourth heat exchange branch 204 and the fifth heat exchange branch 205, so that the flow stability of the refrigerant in the whole heat exchange path is improved.

Optionally, the first pipe orifice 111 of the gas collecting pipe 100 is communicated with the first heat exchange branch 201 through a first branch pipe, and the number of the first pipe orifice 111, the number of the first branch pipe and the number of the first heat exchange branch 201 are the same, for example, the number of the first pipe orifice 111 is two, and the number of the first heat exchange branch 201 is two; similarly, the second nozzle 112 of the gas collecting tube 100 communicates with the second heat exchanging branch 202 through a second branch tube, the third nozzle 113 of the gas collecting tube 100 communicates with the third heat exchanging branch 203 through a third branch tube, the fourth nozzle 114 of the gas collecting tube 100 communicates with the fourth heat exchanging branch 204 through a fourth branch tube, and the fifth nozzle 115 of the gas collecting tube 100 communicates with the fifth heat exchanging branch 205 through a fifth branch tube. In practical use, the gas collecting pipe 100 is vertically arranged and is arranged at one side of a heat exchange pipe group consisting of a first heat exchange flow path, a second heat exchange branch 202, a third heat exchange branch 203, a fourth heat exchange branch 204 and a fifth heat exchange branch 205, and the first branch pipe, the second branch pipe, the third branch pipe, the fourth branch pipe and the fifth branch pipe are all transversely arranged, so that a refrigerant can flow in the heat exchanger according to a set path by utilizing gravity, as shown in fig. 1.

Optionally, the setting method of the second one-way valve 402 and the third one-way valve 403 in the gas collecting pipe 100 may be: the three-stage manifold is welded together with the second one-way valve 402 and the third one-way valve 403.

Optionally, the first flow splitting element 501 comprises one or more flow splitters and similarly, the second flow splitting element 502 comprises one or more flow splitters.

Optionally, the second check valve 402 and the third check valve 403 divide the gas collecting tube 100 into a first gas collecting tube section, a second gas collecting tube section and a third gas collecting tube section from top to bottom, wherein the first nozzle 111 is located in the first gas collecting tube section, the second nozzle 112 and the third nozzle 113 are located in the second gas collecting tube section, and the fourth nozzle 114 and the fifth nozzle 115 are located in the third gas collecting tube section.

The second check valve 402 and the third check valve 403 on the gas collecting pipe 100 are arranged to increase the length of the flow path of the gaseous refrigerant in the heat exchanger.

Optionally, the length of the first gas header section is less than the length of the second gas header section, and the length of the first gas header section is less than the length of the third gas header section.

As shown in fig. 1, under the refrigeration condition, the gaseous refrigerant is divided into two paths after passing through the first heat exchange flow path, the first path performs heat exchange with the external environment through the second heat exchange branch 202, the temperature is reduced, part of the refrigerant becomes liquid and becomes a gas-liquid mixed state, and the refrigerant enters the gas collecting pipe 100 again through the second pipe orifice 112, at this time, the second gas collecting pipe section of the gas collecting pipe 100 can be used as a liquid reservoir to store the liquid refrigerant in the gas-liquid mixed refrigerant, and the gaseous refrigerant continues to perform heat exchange through the third heat exchange branch 203; the second path fourth heat exchange branch 204 exchanges heat with the external environment, the temperature is reduced, part of the refrigerant becomes liquid and becomes gas-liquid mixed state, and the refrigerant enters the gas collecting pipe 100 again through the fourth port 114, at this time, the third gas collecting pipe section of the gas collecting pipe 100 can be used as a liquid reservoir to store the liquid refrigerant in the gas-liquid mixed refrigerant, and the gaseous refrigerant continues to exchange heat through the fifth heat exchange branch 205. Under the low-temperature refrigeration working condition, the air conditioner has the advantages that the condensing effect of the outdoor heat exchanger is good due to the fact that the external environment temperature is low, and the liquid refrigerant generated in the condensing process occupies the space of the heat exchanger, so that the heat exchange effect of the heat exchanger is reduced. The gas collecting pipe provided by the embodiment of the disclosure can enable the second gas collecting pipe section and the third gas collecting pipe section to be used as liquid reservoirs to store liquid refrigerants generated in a condensation process, so that the content of the liquid refrigerants in a heat exchange flow path is reduced, and the condensation effect of the heat exchanger is improved.

Optionally, the first header section comprises a first upper section and a first lower section, wherein the first nozzle 111 is located in the first upper section of the first header section.

The first gas collecting pipe section is divided into a first upper pipe section positioned at the upper part and a first lower pipe section positioned at the lower part. It will be understood that the first upper section and the first lower section are in a top-to-bottom relationship with respect to each other and that the relationship of the lengths of the first upper section and the first lower section is not overly limited. The first pipe orifice 111 is disposed at a first upper pipe section of the first gas collecting pipe section, so that the first pipe orifice 111 is located at an upper portion of the second check valve 402, which is beneficial for the gaseous refrigerant to enter the first heat exchange flow path through the first pipe orifice 111.

Optionally, the second gas header section comprises a second upper section and a second lower section, wherein the second nozzle 112 and the third nozzle 113 are located in the second upper section of the second gas header section.

And the second gas collecting pipe section is divided into a second upper pipe section positioned at the upper part and a second lower pipe section positioned at the lower part. It will be understood that the second upper and lower sections are in an up and down relationship with each other and that the relationship of the lengths of the second upper and lower sections is not overly limited. The second pipe orifice 112 and the third pipe orifice 113 are located in the second upper pipe section, so that the liquid refrigerant passing through the second heat exchange branch 202 flows to the lower part of the second gas collecting pipe section for storage, and the gaseous refrigerant enters the third heat exchange branch 203 through the third pipe orifice 113, so that gas-liquid separation is realized, the content of the liquid refrigerant in the heat exchange flow path is reduced, and the condensation effect of the heat exchanger is improved.

Optionally, the third gas header section includes a third upper section and a third lower section, wherein the fourth nozzle 114 and the fifth nozzle 115 are located at the third upper section of the third gas header section.

Similarly, the third gas collecting pipe section is divided into an upper third upper pipe section and a lower third lower pipe section. It will be understood that the third upper section and the third lower section are in an up-down relationship with respect to each other and that the relationship between the lengths of the third upper section and the third lower section is not overly limited. The fourth nozzle 114 and the fifth nozzle 115 are located in the third upper pipe section, so that the liquid refrigerant passing through the fourth heat exchange branch 204 flows to the lower part of the third gas collecting pipe section to be stored, and the gaseous refrigerant enters the fifth heat exchange branch 205 through the fifth nozzle 115, so that gas-liquid separation is realized, the content of the liquid refrigerant in the heat exchange flow path is reduced, and the condensation effect of the heat exchanger is improved.

Optionally, the number of heat exchange tubes of the first heat exchange branch 201 is greater than or equal to the number of heat exchange tubes of the second heat exchange branch 202.

Optionally, the second heat exchanging branch 202 and the third heat exchanging branch 203 constitute a second heat exchanging flow path, and the fourth heat exchanging branch 204 and the fifth heat exchanging branch 205 constitute a third heat exchanging flow path. The first heat exchange flow path, the second heat exchange flow path and the third heat exchange flow path are sequentially arranged from top to bottom, namely, the first heat exchange flow path is arranged at the upper part of the second heat exchange flow path, and the second heat exchange flow path is arranged at the upper part of the third heat exchange flow path. Optionally, at least two first heat exchange branches 201 in the first heat exchange flow path are arranged side by side in the transverse direction, for example, when the number of the first heat exchange branches 201 is two, the two first heat exchange branches 201 are arranged side by side in the transverse direction, and the number of the heat exchange tubes of the two first heat exchange branches 201 is the same; similarly, the second heat exchange branch 202 and the third heat exchange branch 203 in the second heat exchange flow path are arranged side by side in the transverse direction, and the heat exchange tubes of the second heat exchange branch 202 and the third heat exchange branch 203 have the same number; similarly, the fourth heat exchange branch 204 and the fifth heat exchange branch 205 in the third heat exchange flow path are arranged side by side in the transverse direction, and the number of heat exchange tubes of the fourth heat exchange branch 204 and the fifth heat exchange branch 205 is the same.

In the embodiment of the present disclosure, the number of the heat exchange tubes of the first heat exchange branch 201 is greater than or equal to the number of the heat exchange tubes of the second heat exchange branch 202, which is beneficial to increasing the position of the second tube orifice 112 in the gas collecting tube 100, so that the second tube orifice 112 is located at an upper position of the second gas collecting tube section, which is beneficial to increasing the storage amount of the liquid refrigerant of the gas collecting tube 100. Optionally, the second nozzle 112 and the third nozzle 113 are disposed at the same height of the gas header 100.

Optionally, the number of heat exchange tubes of the fourth heat exchange branch 204 is greater than or equal to the number of heat exchange tubes of the second heat exchange branch 202. Optionally, the fourth nozzle 114 and the fifth nozzle 115 are disposed at the same height of the gas header 100.

The number of the heat exchange tubes of the fourth heat exchange branch 204 is greater than or equal to the number of the heat exchange tubes of the second heat exchange branch 202, which is beneficial to increasing the position of the fourth tube port 114 in the gas collecting tube 100, so that the fourth tube port 114 is located at the upper position of the third gas collecting tube section, which is beneficial to increasing the storage amount of the liquid refrigerant in the gas collecting tube 100.

The embodiment of the disclosure simultaneously provides an air conditioner.

The air conditioner provided by the embodiment of the disclosure comprises a refrigerant circulation loop at least composed of an indoor heat exchanger, an outdoor heat exchanger, a compressor and a four-way valve, wherein the indoor heat exchanger and/or the outdoor heat exchanger are/is the heat exchanger.

Optionally, in the cooling mode and when the heat exchanger is used as an outdoor heat exchanger, the first main port 101 is a port through which a refrigerant flows in, and the second main port 601 is a port through which the refrigerant flows out; in the heating mode, when the heat exchanger is used as an outdoor heat exchanger, the first header 101 serves as a port through which the refrigerant flows out, and the second header 601 serves as a port through which the refrigerant flows in.

Optionally, in the cooling mode and when the heat exchanger is used as an indoor heat exchanger, the first header port 101 is a port through which a refrigerant flows out, and the second header port 601 is a port through which the refrigerant flows in; in the heating mode, when the heat exchanger is used as an indoor heat exchanger, the first header port 101 serves as a port through which the refrigerant flows in, and the second header port 601 serves as a port through which the refrigerant flows out.

The air conditioner adopting the heat exchanger shown in the embodiment can respectively convey the refrigerant in different heating flow directions when the air conditioner runs in a refrigeration mode or a heating mode, not only can make the refrigerant fully exchange heat downwards in the refrigeration flow to realize supercooling, but also can avoid the problem of pressure loss caused by overlong flow path downwards in the heating flow direction, thereby simultaneously ensuring the performance requirements of the heat exchanger in different working modes.

Alternatively, when the outdoor heat exchanger is the aforementioned heat exchanger, the gas collecting pipe 100 of the heat exchanger is communicated with the compressor, and the second flow dividing element 502 is communicated with the indoor heat exchanger.

When the heat exchanger is used as an outdoor heat exchanger of an air conditioner, the gas collecting pipe 100 of the heat exchanger is communicated with the compressor, and the second flow dividing element 502 is communicated with the indoor heat exchanger. Therefore, when the refrigerant flows downwards, the high-temperature refrigerant discharged from the compressor enters the heat exchanger from the first main port 101 of the gas collecting pipe 100, flows through the first heat exchange flow path, the second heat exchange branch 202, the third heat exchange branch 203, the fourth heat exchange branch 204 and the fifth heat exchange branch 205 according to the aforementioned flow path, and flows into the indoor heat exchanger after throttling. Therefore, the path length and the time for the high-temperature refrigerant to exchange heat with the outdoor environment are prolonged, so that the high-temperature refrigerant can reach lower temperature after flowing through the outdoor heat exchanger, and the refrigeration performance is improved. The second flow dividing element 502 may be communicated with the indoor heat exchanger by using a pipeline where the second header 601 is located.

Alternatively, when the indoor heat exchanger is the aforementioned heat exchanger, the gas collecting pipe 100 of the heat exchanger is communicated with the compressor, and the second flow dividing element 502 is communicated with the outdoor heat exchanger.

When the heat exchanger is used as an indoor heat exchanger of an air conditioner, the gas collecting pipe 100 of the heat exchanger is communicated with the compressor, and the second flow dividing element 502 is communicated with the outdoor heat exchanger. Therefore, in the heating flow direction, the high-temperature refrigerant discharged from the compressor enters the heat exchanger from the first main port 101 of the gas collecting pipe 100, flows through the first heat exchange flow path, the second heat exchange branch 202, the third heat exchange branch 203, the fourth heat exchange branch 204 and the fifth heat exchange branch 205 according to the aforementioned flow path, and flows into the outdoor heat exchanger after throttling. Therefore, the path length and the time for the heat exchange between the high-temperature refrigerant and the indoor environment are prolonged, so that the heat of the high-temperature refrigerant can be greatly transferred to the indoor environment, and the heating performance is improved.

The above description and drawings sufficiently illustrate embodiments of the disclosure to enable those skilled in the art to practice them. Other embodiments may include structural and other changes. The examples merely typify possible variations. Individual components and functions are optional unless explicitly required, and the sequence of operations may vary. Portions and features of some embodiments may be included in or substituted for those of others. The embodiments of the present disclosure are not limited to the structures that have been described above and shown in the drawings, and various modifications and changes may be made without departing from the scope thereof. The scope of the present disclosure is limited only by the appended claims.

Claims (10)

1. A heat exchanger, comprising:

a gas collecting pipe;

the first heat exchange flow path comprises one or more first heat exchange branch paths, the first end of each first heat exchange branch path is connected with the first pipe orifice of the gas collecting pipe, and the second end of each first heat exchange branch path is connected with the first flow dividing element;

a first end of the first heat exchange branch is connected with a first pipe orifice of the gas collecting pipe, and a second end of the first heat exchange branch is connected with the first flow dividing element;

a first end of the third heat exchange branch is connected with a third pipe orifice of the gas collecting pipe, and a second end of the third heat exchange branch is connected with the second shunt element;

a first end of the fourth heat exchange branch is connected with a fourth pipe orifice of the gas collecting pipe, and a second end of the fourth heat exchange branch is connected with the first shunt element;

a first end of the fifth heat exchange branch is connected with a fifth pipe orifice of the gas collecting pipe, and a second end of the fifth heat exchange branch is connected with the second shunt element;

a bypass line connecting the first bypass element and the second bypass element;

a first check valve disposed in the bypass line and having a direction defined from the second shunt element to the first shunt element;

the second one-way valve is arranged between the first pipe orifice and the second pipe orifice of the gas collecting pipe, and the conduction direction is defined to flow from the second pipe orifice to the first pipe orifice;

and the third one-way valve is arranged between the third pipe orifice and the fourth pipe orifice of the gas collecting pipe, and the conduction direction is defined to flow from the fourth pipe orifice to the third pipe orifice.

2. The heat exchanger of claim 1, wherein the second and third check valves divide the gas header into a first gas header section, a second gas header section, and a third gas header section from top to bottom,

the first pipe orifice is positioned in the first gas collecting pipe section, the second pipe orifice and the third pipe orifice are positioned in the second gas collecting pipe section, and the fourth pipe orifice and the fifth pipe orifice are positioned in the third gas collecting pipe section.

3. The heat exchanger of claim 2,

the first gas header section includes a first upper section and a first lower section, wherein the first nozzle is located in the first upper section of the first gas header section.

4. The heat exchanger of claim 2,

the second gas header section comprises a second upper section and a second lower section, wherein the second and third nozzles are located in the second upper section of the second gas header section.

5. The heat exchanger of claim 2,

the third gas header section comprises a third upper section and a third lower section, wherein the fourth and fifth nozzles are located in the third upper section of the third gas header section.

6. The heat exchanger as claimed in claim 1, wherein the number of heat exchange tubes of the first heat exchange branch is greater than or equal to the number of heat exchange tubes of the second heat exchange branch.

7. The heat exchanger as recited in claim 1 wherein the number of heat exchange tubes of said fourth heat exchange branch is greater than or equal to the number of heat exchange tubes of said second heat exchange branch.

8. An air conditioner comprising a refrigerant circulation circuit constructed of at least an indoor heat exchanger, an outdoor heat exchanger, a compressor, and a four-way valve, wherein the indoor heat exchanger and/or the outdoor heat exchanger is the heat exchanger according to any one of claims 1 to 7.

9. The air conditioner according to claim 8, wherein when the outdoor heat exchanger is the heat exchanger, the header of the heat exchanger is in communication with the compressor, and the second flow dividing element is in communication with the indoor heat exchanger.

10. The air conditioner according to claim 8 or 9, wherein when the indoor heat exchanger is the heat exchanger, the header of the heat exchanger is in communication with the compressor, and the second flow dividing element is in communication with the outdoor heat exchanger.

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