Air conditioner refrigerant distributor

By designing the main delivery component and the sub-delivery component in the air conditioning refrigeration distributor, and by using filtration and ultrasonic removal to remove impurities, the problems of uneven refrigerant distribution and impurity blockage are solved, thereby improving the cooling effect and cleanliness of the air conditioning system and extending its service life.

CN224381836UActive Publication Date: 2026-06-19CHINA TOBACCO GUANGXI IND

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
CHINA TOBACCO GUANGXI IND
Filing Date
2025-08-07
Publication Date
2026-06-19

AI Technical Summary

Technical Problem

Uneven refrigerant distribution in traditional air conditioning refrigeration distributors can lead to some air conditioning units having too much or too little refrigerant, affecting the overall cooling effect. Furthermore, the refrigerant can carry impurities or contaminants during circulation, causing pipe blockages and shortening the lifespan of the air conditioning system.

Method used

Design an air conditioning refrigerant distributor, including a main delivery component and multiple branch delivery components. It uses a filter component for filtration, utilizes the Venturi effect to design branch pipelines to ensure uniform refrigerant distribution, removes impurities using an ultrasonic generator, and uses stainless steel to improve transmission efficiency.

Benefits of technology

It improves the uniform distribution of refrigerant, enhances the overall cooling effect and cleanliness of the air conditioning system, and extends the service life of the air conditioning system.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application provides an air conditioner refrigerant distributor, comprising a main conveying assembly, a sub-conveying assembly and a filtering assembly; the main conveying assembly is provided with an input port at one end in a first direction, and a leading-out port is formed in the main body of the main conveying assembly; a plurality of sub-conveying assemblies are arranged; the plurality of sub-conveying assemblies are arranged at intervals along the circumferential direction of the main conveying assembly; the filtering assembly has a first filtering part and a second filtering part; one of the first filtering part and the second filtering part is arranged at the input port, and the other is arranged at the main body of the main conveying assembly and is in communication with the main conveying assembly. The application can improve the problem of uneven distribution of refrigerant in the traditional distributor, improve the overall refrigeration effect of the air conditioning system. In addition, impurities and particulate matters in the refrigerant can be removed, the smooth flow of the refrigerant can be ensured, and the cleanliness and operation efficiency of the air conditioning system can be improved.
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Description

Technical Field

[0001] This application relates to the field of air conditioning technology, and more particularly to air conditioning refrigeration distributors. Background Technology

[0002] In existing air conditioning systems, the distribution and purification of refrigerant are crucial for ensuring efficient and stable operation.

[0003] Traditional air conditioning refrigerant distributors are often designed to be relatively simple, typically consisting of only one main delivery pipe and several branch pipes, used to distribute refrigerant to different air conditioning units.

[0004] However, traditional refrigeration distributors may not distribute refrigerant evenly, resulting in some air conditioning units receiving too much refrigerant while others receive too little, thus affecting the overall cooling effect.

[0005] Secondly, during the refrigerant circulation process, impurities or contaminants carried by the refrigerant can often cause blockages in some pipes, ultimately damaging the air conditioning system and shortening its service life.

[0006] Therefore, there is an urgent need for air conditioning refrigeration distributors to address, to some extent, the technical problems existing in current technologies. Utility Model Content

[0007] The purpose of this application is to provide an air conditioning refrigeration distributor that can, to a certain extent, help improve the problem of uneven refrigerant distribution in traditional distributors and improve the overall cooling effect of the air conditioning system.

[0008] This application provides an air conditioning refrigeration distributor, comprising:

[0009] A main conveying assembly extends along a first direction and has an input port at one end in the first direction and an output port at the main body of the main conveying assembly.

[0010] Multiple sub-conveying components are provided, and the multiple sub-conveying components are arranged at intervals along the circumferential direction of the main conveying component, and all of them are connected to the outlet port of the main conveying component.

[0011] The filter assembly has a first filter section and a second filter section; one of the first filter section and the second filter section is disposed at the input port, and the other is disposed in the body of the main conveying assembly and communicates with the main conveying assembly.

[0012] In the above technical solution, the main conveying assembly further includes a main conveying pipe;

[0013] The main delivery pipe extends along the first direction, and the input port is formed at one end of the first direction, while the output port is formed on the main body of the main delivery pipe.

[0014] In the above technical solution, the sub-conveying assembly further includes a sub-conveying pipe connected to the outlet port;

[0015] The distribution pipe includes a first section, a second section, and a third section connected sequentially along a second direction perpendicular to the first direction;

[0016] The first segment is connected to the main body of the main delivery pipe and extends along the second direction; the second segment has a tapering structure from the direction close to the first segment to the direction close to the second segment; the third segment has a tapering structure from the direction close to the second segment to the direction away from the second segment.

[0017] In the above technical solution, the axes of the multiple sub-conveying pipes form a dividing interface, and the multiple sub-conveying pipes are respectively divided into an upper sub-conveying section and a lower sub-conveying section by the dividing interface;

[0018] The main conveying pipe is divided into an upper main conveying section and a lower main conveying section by the dividing interface; the upper sub-conveying section is connected to the upper main conveying section, and the lower sub-conveying section is connected to the lower main conveying section;

[0019] The upper and lower conveying sections are connected by a first connecting member; the upper main conveying section and the lower main conveying section are connected by a second connecting member.

[0020] In the above technical solution, the air conditioning refrigeration distributor further includes a sealing strip;

[0021] The sealing strip is provided between the upper main conveying section and the lower main conveying section, as well as between the upper sub-conveying section and the lower sub-conveying section.

[0022] In the above technical solution, the first connecting member further includes a first connecting block, a second connecting block, and a first connecting bolt;

[0023] The first connecting block is disposed on the upper conveying section and corresponds to the connection between the second section and the third section; the second connecting block is disposed on the lower conveying section and corresponds to the connection between the second section and the third section.

[0024] When the upper distribution conveyor and the lower distribution conveyor are fastened together, the first connecting bolt passes through the upper distribution conveyor and the lower distribution conveyor in sequence, so that the upper distribution conveyor and the lower distribution conveyor are fixed together.

[0025] In the above technical solution, the second connecting member is further disposed between adjacent distribution pipes, and the second connecting member includes a third connecting block, a fourth connecting block and a second connecting bolt;

[0026] The third connecting block is disposed on the upper main conveying section; the fourth connecting block is disposed on the lower main conveying section;

[0027] When the third connecting block and the fourth connecting block are mated together, the second connecting bolt passes through the third connecting block and the fourth connecting block to fix the upper main conveying part and the lower main conveying part together.

[0028] In the above technical solution, the first filter is further defined as an ultrasonic generator;

[0029] The main delivery pipe has a mounting hole on its side wall, and the ultrasonic generator is mounted in the mounting hole.

[0030] The ultrasonic generator can emit high-frequency ultrasonic waves into the main delivery pipe and the branch delivery pipe, so as to decompose impurities on the sidewalls of the main delivery pipe and the branch delivery pipe into tiny particles.

[0031] In the above technical solution, the second filter part further includes a fixing base and a filter screen;

[0032] The filter screen is mounted on the input port of the main delivery pipe via the fixed base; the refrigeration fluid is sequentially delivered to the branch delivery pipe through the filter screen and the main delivery pipe.

[0033] In the above technical solution, both the main conveying assembly and the sub-conveying assembly are made of stainless steel.

[0034] Compared with the prior art, this application has the following beneficial effects:

[0035] This application provides an air conditioning refrigeration distributor, comprising:

[0036] A main conveying assembly extends along a first direction and has an input port at one end in the first direction and an output port at the main body of the main conveying assembly.

[0037] Multiple sub-conveying components are provided, and the multiple sub-conveying components are arranged at intervals along the circumferential direction of the main conveying component, and all of them are connected to the outlet port of the main conveying component.

[0038] The filter assembly has a first filter section and a second filter section; one of the first filter section and the second filter section is disposed at the input port, and the other is disposed in the body of the main conveying assembly and communicates with the main conveying assembly.

[0039] In summary, this application, by arranging multiple sub-conveying components at equal intervals at the outlet port of the main conveying component, ensures that the refrigerant is evenly distributed among the sub-conveying components in the main conveying component. Compared to existing refrigerant distributors, which may have uneven refrigerant distribution, resulting in some air conditioning units receiving too much refrigerant while others receive too little, thus affecting the overall cooling effect, this application helps to improve the problem of uneven refrigerant distribution in traditional distributors and improve the overall cooling effect of the air conditioning system.

[0040] In addition, this application provides a first filter section or a second filter section on the top of the main conveying assembly and on the main body of the main conveying assembly. The first filter section or the second filter section can filter the refrigerant. Compared with the existing refrigerant, which may cause blockage of some pipelines due to some impurities or contaminants carried during the circulation process, this application can remove impurities and particulate matter from the refrigerant, ensuring that the refrigerant can flow smoothly and improving the cleanliness and operating efficiency of the air conditioning system. Attached Figure Description

[0041] To more clearly illustrate the technical solutions in the specific embodiments of this application or the prior art, the drawings used in the description of the specific embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are some embodiments of this application. For those skilled in the art, other drawings can be obtained from these drawings without creative effort.

[0042] Figure 1 Exploded view of the air conditioning refrigeration distributor provided in this application;

[0043] Figure 2 A structural schematic diagram of the air conditioning refrigeration distributor provided in this application from a first-view perspective;

[0044] Figure 3 for Figure 2 Enlarged view of point A in the middle;

[0045] Figure 4 A schematic diagram of the air conditioning refrigeration distributor provided in this application from a second perspective;

[0046] Figure 5 for Figure 4 A schematic diagram of the hidden filter component;

[0047] Figure 6A schematic diagram of the filter assembly in the air conditioning refrigeration distributor provided in this application from a first-view perspective;

[0048] Figure 7 This is a schematic diagram of the filter assembly in the air conditioning refrigeration distributor provided in this application from a second perspective.

[0049] Reference numerals: 1-Main conveying assembly; 101-First direction; 102-Input port; 104-Main conveying pipe; 105-Upper main conveying section; 106-Lower main conveying section; 107-Second connecting member; 109-Third connecting block; 110-Fourth connecting block; 111-Second connecting bolt;

[0050] 202-Distribution pipe; 203-Second direction; 204-First section; 205-Second section; 206-Third section; 207-Upper distribution conveyor; 208-Lower distribution conveyor; 209-First connecting member; 210-First connecting block; 211-Second connecting block; 212-First connecting bolt;

[0051] 3-Filter assembly; 301-First filter section; 302-Second filter section; 303-Ultrasonic generator; 304-Mounting hole; 305-Fixing base; 306-Filter screen. Detailed Implementation

[0052] The following detailed embodiments are provided to aid the reader in gaining a comprehensive understanding of the methods, apparatus, and / or systems described herein. However, various changes, modifications, and equivalents of the methods, apparatus, and / or systems described herein will be apparent upon understanding the disclosure of this application. For example, the order of operations described herein is merely illustrative and is not limited to the order presented herein; rather, changes that will be apparent upon understanding the disclosure of this application are possible, except for operations that must occur in a specific order. Furthermore, descriptions of features known in the art may be omitted for clarity and brevity. The features described herein may be implemented in different forms and should not be construed as limited to the examples described herein. Rather, the examples described herein are provided only to illustrate some of the many possible ways of implementing the methods, apparatus, and / or systems described herein that will be apparent upon understanding the disclosure of this application. Throughout this specification, when an element (such as a layer, region, or substrate) is described as being "on" another element, "connected to" another element, "bonded to" another element, "on" another element, or "covering" another element, it may be directly "on" another element, "connected to" another element, "bonded to" another element, "on" another element, or "covering" another element, or there may be one or more other elements in between. Conversely, when an element is described as being "directly on" another element, "directly connected to" another element, "directly bonded to" another element, "directly on" another element, or "directly covering" another element, there may be no other elements in between. As used herein, the term "and / or" includes any one of the relevant items listed and any combination of any two or more of them. Although terms such as "first," "second," and "third" may be used herein to describe individual components, assemblies, regions, layers, or portions, these components, assemblies, regions, layers, or portions are not limited by these terms. More precisely, these terms are used only to distinguish one component, assembly, region, layer, or part from another. Therefore, without departing from the teachings of the examples described herein, the first component, assembly, region, layer, or part referred to as such in the examples may also be referred to as the second component, assembly, region, layer, or part. For ease of description, spatial relational terms such as “above,” “upper,” “below,” and “lower” may be used herein to describe the relationship between one element and another, as shown in the accompanying drawings. Such spatial relational terms are intended to include not only the orientation depicted in the drawings but also the different orientations of the device in use or operation. For example, if the device in the drawings is flipped, an element described as being “above” or “upper” relative to another element will subsequently be “below” or “lower” relative to that other element.Therefore, the term "above" includes both "above" and "below" depending on the spatial orientation of the device. The device may also be positioned in other ways (e.g., oscillating 90 degrees or in other orientations), and the spatial relational terms used herein will be interpreted accordingly. The terminology used herein is for describing various examples only and is not intended to limit this disclosure. Unless the context clearly indicates otherwise, the singular form is also intended to include the plural form. The terms "comprising," "including," and "having" enumerate the stated features, quantities, operations, components, elements, and / or combinations thereof, but do not exclude the presence or addition of one or more other features, quantities, operations, components, elements, and / or combinations thereof. Variations in the shapes shown in the figures may occur due to manufacturing techniques and / or tolerances. Therefore, the examples described herein are not limited to the specific shapes shown in the figures but include changes in shape that occur during manufacturing. The features of the examples described herein may be combined in various ways that will be apparent upon understanding the disclosure of this application. Furthermore, although the examples described herein have a wide variety of constructions, other constructions are possible as will be apparent upon understanding the disclosure of this application.

[0053] To address the technical problems of uneven refrigerant distribution in traditional refrigerant distributors, resulting in some air conditioning units receiving too much refrigerant while others receive too little, thus affecting the overall cooling effect, and the potential for impurities or contaminants carried by the refrigerant during circulation to cause blockages in some pipes, ultimately damaging the air conditioning system and shortening its lifespan, this application provides an air conditioning refrigerant distributor. The following section discusses... Figures 1-7 This section provides a detailed explanation of the air conditioner refrigerant distributor.

[0054] The air conditioning refrigeration distributor includes a main conveying assembly 1, the axis of which is along a first direction 101, according to... Figure 1 Taking the direction shown above as an example, the first direction 101 refers to the vertical direction, that is, the main conveying assembly 1 extends along the vertical direction. Furthermore, an input port 102 is formed at one end of the main conveying assembly 1 along the vertical direction, that is, in... Figure 1 The main delivery assembly 1 has an input port 102 formed on its top, which serves as the refrigerant input port 102. Additionally, an output port is formed on the main body of the main delivery assembly 1 for refrigerant output.

[0055] Specifically, combined Figure 1 As shown, the main conveying assembly 1 includes a main conveying pipe 104, which is optionally a cylindrical pipe. The main conveying pipe 104 extends vertically and has an input port 102 at the top and an output port on the main body of the main conveying pipe 104.

[0056] The air conditioning refrigeration distributor also includes a distribution conveying assembly, which is connected to the outlet port. Furthermore, multiple distribution conveying assemblies are provided, optionally in combination with... Figure 1 As shown, there are four sub-distribution components, which are arranged at equal intervals along the circumferential sidewall of the main distribution pipe 104. This arrangement ensures that the refrigerant is evenly distributed to each sub-distribution component in the main distribution pipe 104, which helps to improve the problem of uneven refrigerant distribution in traditional distributors and improves the overall cooling effect of the air conditioning system.

[0057] The air conditioning refrigeration distributor also includes a filter assembly 3, which has a first filter section 301 and a second filter section 302. One of the first filter section 301 and the second filter section 302 is disposed at the input port 102 and is used to filter the refrigerant at the input port 102, removing impurities and particulate matter from the refrigerant. Furthermore, the other of the first filter section 301 and the second filter section 302 is disposed in the main body of the main conveying assembly 1 and communicates with the main conveying assembly 1.

[0058] In summary, this application, by arranging multiple sub-conveying components at equal intervals at the outlet port of the main conveying component 1, ensures that the refrigerant is evenly distributed among the sub-conveying components in the main conveying component 1. Compared with existing refrigerant distributors, which may have uneven refrigerant distribution, resulting in some air conditioning units receiving too much refrigerant while others receive too little, thus affecting the overall cooling effect, this application helps to improve the problem of uneven refrigerant distribution in traditional distributors and improve the overall cooling effect of the air conditioning system.

[0059] Furthermore, this application provides a first filter section 301 or a second filter section 302 on the top of the main conveying assembly 1 and on the main body of the main conveying assembly 1. The first filter section 301 or the second filter section 302 can filter the refrigerant. Compared with the existing refrigerant, which may cause blockage of some pipelines due to some impurities or contaminants carried during the circulation process, this application can remove impurities and particulate matter from the refrigerant, ensuring that the refrigerant can flow smoothly and improving the cleanliness and operating efficiency of the air conditioning system.

[0060] In this embodiment, further, combined with Figure 4 As shown, the sub-conveying assembly includes a sub-conveying pipe 202 communicating with the outlet port; the sub-conveying pipe 202 extends along a second direction 203 perpendicular to the first direction 101, according to... Figure 1 The direction shown in the figure, the second direction 203 refers to the horizontal direction.

[0061] Specifically, the branch delivery pipe 202 includes a first section 204, a second section 205, and a third section 206 connected sequentially. The first section 204 is connected to the main body of the main delivery pipe 104 and extends along the second direction 203. The second section 205 has a gradually narrowing structure from near the first section 204 to near the second section 205. The third section 206 has a gradually expanding structure from near the second section 205 to away from the second section 205. This arrangement ensures that the refrigerant can be evenly distributed to each refrigeration zone. The branch pipe design utilizes the Venturi effect to increase the refrigerant flow rate and improve refrigeration efficiency.

[0062] Furthermore, in combination Figure 1 As shown, the axes of multiple sub-conveying pipes 202 form a dividing interface, which divides the multiple sub-conveying pipes 202 into an upper sub-conveying section 207 and a lower sub-conveying section 208. The main conveying pipe 104 is divided into an upper main conveying section 105 and a lower main conveying section 106 by the dividing interface. The upper sub-conveying section 207 is connected to the upper main conveying section 105, and the lower sub-conveying section 208 is connected to the lower main conveying section 106. Preferably, the upper sub-conveying section 207 and the upper main conveying section 105 are integrally formed, and the lower sub-conveying section 208 and the lower main conveying section 106 are integrally formed.

[0063] Furthermore, the upper conveying section 207 and the lower conveying section 208 are connected by a first connecting member 209; the upper main conveying section 105 and the lower main conveying section 106 are connected by a second connecting member 107.

[0064] Optionally, combined Figure 3 As shown, the first connecting member 209 includes a first connecting block 210, a second connecting block 211, and a first connecting bolt 212; wherein, the first connecting block 210 is disposed on the upper distributing conveyor 207 and corresponds to the connection between the second segment 205 and the third segment 206, and the second connecting block 211 is disposed on the lower distributing conveyor 208 and corresponds to the connection between the second segment 205 and the third segment 206; when the upper distributing conveyor 207 and the lower distributing conveyor 208 are fastened together, the first connecting bolt 212 passes through the upper distributing conveyor 207 and the lower distributing conveyor 208 in sequence, and a nut is screwed onto the first connecting bolt 212 to fix the upper distributing conveyor 207 and the lower distributing conveyor 208 together.

[0065] Preferably, the first connecting block 210 and the second connecting block 211 are strip-shaped, and two first connecting bolts 212 are provided on the same first connecting block 210 and the same second connecting block 211. The two first connecting bolts 212 are spaced apart to ensure a balanced connection between the first connecting block 210 and the second connecting block 211.

[0066] Preferably, combined with Figure 3As shown, the second connecting member 107 is disposed between adjacent sub-conveying pipes 202. The second connecting member 107 includes a third connecting block 109, a fourth connecting block 110, and a second connecting bolt 111. The third connecting block 109 is disposed on the upper main conveying section 105, and the fourth connecting block 110 is disposed on the lower main conveying section 106. When the third connecting block 109 and the fourth connecting block 110 are mated together, the second connecting bolt 111 passes through the third connecting block 109 and the fourth connecting block 110, and a nut is screwed onto the second connecting bolt 111 to fix the upper main conveying section 105 and the lower main conveying section 106 together.

[0067] Preferably, the third connecting block 109 and the fourth connecting block 110 are triangular, and the third connecting block 109 and the fourth connecting block 110 serve to connect and strengthen the connection.

[0068] It is worth noting that the above-mentioned sub-conveying pipe 202 is divided into upper sub-conveying section 207 and lower sub-conveying section 208 according to the dividing interface; the main conveying pipe 104 is divided into upper main conveying section 105 and lower main conveying section 106 according to the dividing interface. This arrangement facilitates installation, disassembly and replacement.

[0069] In this embodiment, the air conditioning refrigeration distributor further includes sealing strips; sealing strips are provided between the upper main conveying section 105 and the lower main conveying section 106, and between the upper distribution conveying section 207 and the lower distribution conveying section 208. Preferably, the sealing strips are made of a highly elastic material, possessing good sealing performance and corrosion resistance, and are able to prevent refrigerant leakage between the upper main conveying section 105 and the lower main conveying section 106, and between the upper distribution conveying section 207 and the lower distribution conveying section 208, thereby preventing refrigerant waste and safety accidents.

[0070] In this embodiment, further, combined with Figure 1 As shown, the first filter section 301 is an ultrasonic generator 303. Specifically, a mounting hole 304 is provided on the side wall of the main body of the main delivery pipe 104. Preferably, the mounting hole 304 is a circular hole, and the ultrasonic generator 303 is installed in the mounting hole 304. In the actual installation process, an interference fit can be used, that is, firstly, the ultrasonic generator 303 is inserted into the mounting hole 304; then, bolts or clamps are used to fix the ultrasonic generator 303 to the main body of the main delivery pipe 104.

[0071] In practical use, the ultrasonic generator 303 emits high-frequency ultrasonic waves into the main delivery pipe 104 and the branch delivery pipe 202, causing impurities on the sidewalls of the main delivery pipe 104 and the branch delivery pipe 202 to decompose into tiny particles. Specifically, when the ultrasonic generator 303 is working, it emits high-frequency ultrasonic waves into the refrigerant. When the ultrasonic waves propagate in the refrigerant, tiny bubbles (cavitation nuclei) in the liquid rapidly expand under the negative pressure cycle of the ultrasonic waves and then rapidly contract until they collapse under the positive pressure cycle. The instant of bubble collapse generates local high temperature and high pressure. These extreme conditions can decompose dirt, grease, rust and other impurities adhering to the inner wall and internal components of the distributor into tiny particles. Furthermore, the continuous ultrasonic action can create a dynamic "clean environment" on the inner wall of the distributor, making it difficult for dirt to accumulate on the wall surface, thereby keeping the inside of the distributor clean.

[0072] In this embodiment, further, combined with Figure 4 , Figure 6 as well as Figure 7 As shown, the second filter section 302 includes a fixed base 305 and a filter screen 306; wherein, the filter screen 306 is disposed at the input port 102 of the main conveying pipe 104 via the fixed base 305; the refrigeration is sequentially conveyed to the branch conveying pipe 202 via the filter screen 306 and the main conveying pipe 104.

[0073] In actual use, the second filtration section performs preliminary filtration of the refrigerant to remove impurities and particulate matter. When cleaning and maintenance are required, the ultrasonic generator is activated to vibrate and remove the dirt attached to the inner wall. Then, the distributor is disassembled and cleaned module by module.

[0074] In this embodiment, both the main conveying assembly 1 and the sub-conveying assemblies are made of stainless steel. Stainless steel has excellent corrosion resistance and pressure resistance, and its smooth inner wall reduces resistance to refrigerant flow and improves transmission efficiency.

[0075] Finally, it should be noted that the above embodiments are only used to illustrate the technical solutions of this application, and are not intended to limit them. Although this application has been described in detail with reference to the foregoing embodiments, those skilled in the art should understand that modifications can still be made to the technical solutions described in the foregoing embodiments, or equivalent substitutions can be made to some or all of the technical features therein. Such modifications or substitutions do not cause the essence of the corresponding technical solutions to deviate from the scope of the technical solutions of the embodiments of this application.

Claims

1. An air conditioning refrigeration distributor, characterized in that, include: A main conveying assembly extends along a first direction and has an input port at one end in the first direction and an output port at the main body of the main conveying assembly. Multiple sub-conveying components are provided, and the multiple sub-conveying components are arranged at intervals along the circumferential direction of the main conveying component, and all of them are connected to the outlet port of the main conveying component. The filter assembly has a first filter section and a second filter section; one of the first filter section and the second filter section is disposed at the input port, and the other is disposed in the body of the main conveying assembly and communicates with the main conveying assembly.

2. The air conditioning refrigeration distributor according to claim 1, characterized in that, The main delivery assembly includes a main delivery pipe; The main delivery pipe extends along the first direction, and the input port is formed at one end of the first direction, while the output port is formed on the main body of the main delivery pipe.

3. The air conditioning refrigeration distributor according to claim 2, characterized in that, The sub-conveying assembly includes a sub-conveying pipe connected to the outlet port; The distribution pipe includes a first section, a second section, and a third section connected sequentially along a second direction perpendicular to the first direction; The first segment is connected to the main body of the main delivery pipe and extends along the second direction; the second segment has a tapering structure from the direction close to the first segment to the direction close to the second segment; the third segment has a tapering structure from the direction close to the second segment to the direction away from the second segment.

4. The air conditioning refrigeration distributor according to claim 3, characterized in that, The axes of the multiple sub-conveying pipes form a dividing interface, and the multiple sub-conveying pipes are respectively divided into an upper sub-conveying section and a lower sub-conveying section by the dividing interface; The main conveying pipe is divided into an upper main conveying section and a lower main conveying section by the dividing interface; the upper sub-conveying section is connected to the upper main conveying section, and the lower sub-conveying section is connected to the lower main conveying section; The upper and lower conveying sections are connected by a first connecting member; the upper main conveying section and the lower main conveying section are connected by a second connecting member.

5. The air conditioning refrigeration distributor according to claim 4, characterized in that, The air conditioning refrigeration distributor also includes a sealing strip; The sealing strip is provided between the upper main conveying section and the lower main conveying section, as well as between the upper sub-conveying section and the lower sub-conveying section.

6. The air conditioning refrigeration distributor according to claim 4, characterized in that, The first connecting component includes a first connecting block, a second connecting block, and a first connecting bolt; The first connecting block is disposed on the upper conveying section and corresponds to the connection between the second section and the third section; the second connecting block is disposed on the lower conveying section and corresponds to the connection between the second section and the third section. When the upper distribution conveyor and the lower distribution conveyor are fastened together, the first connecting bolt passes through the upper distribution conveyor and the lower distribution conveyor in sequence, so that the upper distribution conveyor and the lower distribution conveyor are fixed together.

7. The air conditioning refrigeration distributor according to claim 4, characterized in that, The second connecting member is disposed between adjacent distribution pipes, and the second connecting member includes a third connecting block, a fourth connecting block, and a second connecting bolt; The third connecting block is disposed on the upper main conveying section; the fourth connecting block is disposed on the lower main conveying section; When the third connecting block and the fourth connecting block are mated together, the second connecting bolt passes through the third connecting block and the fourth connecting block to fix the upper main conveying part and the lower main conveying part together.

8. The air conditioning refrigeration distributor according to claim 3, characterized in that, The first filter section is an ultrasonic generator; The main delivery pipe has a mounting hole on its side wall, and the ultrasonic generator is mounted in the mounting hole. The ultrasonic generator can emit high-frequency ultrasonic waves into the main delivery pipe and the branch delivery pipe, so as to decompose impurities on the sidewalls of the main delivery pipe and the branch delivery pipe into tiny particles.

9. The air conditioning refrigeration distributor according to claim 3, characterized in that, The second filter section includes a mounting base and a filter screen; The filter screen is mounted on the input port of the main delivery pipe via the fixed base; the refrigeration fluid is sequentially delivered to the branch delivery pipe through the filter screen and the main delivery pipe.

10. The air conditioning refrigeration distributor according to claim 1, characterized in that, Both the main conveying assembly and the sub-conveying assembly are made of stainless steel.