CN220287723U - Copper-aluminum composite radiator of heating ventilation air conditioner - Google Patents

Abstract

The utility model discloses a copper-aluminum composite radiator for a heating ventilation air conditioner, which relates to the technical field of radiators and solves the problems that the existing copper-aluminum composite radiator adopts an integrated structure, and in normal maintenance work, the copper-aluminum composite radiator comprises a joint rod and a radiating component, wherein the joint rod is provided with two groups, a plurality of groups of support rods are clamped between the two groups of joint rods, the plurality of groups of support rods are clamped with the joint rods through joint bases arranged at the tail ends of the two groups of support rods, friction belts are arranged at the two side areas of the two groups of joint rods, which are far away from the support rods, the two sides of the friction belts are provided with limiting bosses, the radiating component is correspondingly provided with a plurality of groups of support rods, the plurality of groups of radiating components are respectively and limitedly clamped between the support rods, the outer surface of one side of the radiating component, which is far away from the corresponding support rod, of the radiating component is provided with a plurality of groups of radiating fins in parallel, and the plurality of groups of radiating fins are fixedly connected on the radiating component.

Description

Copper-aluminum composite radiator of heating ventilation air conditioner

Technical Field

The utility model relates to the technical field of radiators, in particular to a copper-aluminum composite radiator for a heating ventilation air conditioner.

Background

The copper-aluminium composite radiator for heating air conditioner is a unique radiator, and adopts a composite structure of copper and aluminium. Copper-aluminum composite radiator realizes efficient radiating effect by stacking copper and aluminum sheets together to form a heat exchange surface, copper has good heat conductivity and corrosion resistance, aluminum has light weight and good strength characteristics, and the composite structure ensures that the radiator has good balance between radiating effect and structural strength.

The patent number CN218915361U discloses a copper-aluminum composite radiator of a heating ventilation air conditioner, which comprises a shell, wherein a radiating component is arranged in the shell, one side of the shell is fixedly connected with a mounting component, the other side of the shell is fixedly connected with a first fixing block, one side of the first fixing block is fixedly connected with a fixing plate, and the front surface of the shell is provided with a first connecting plate; through setting up of devices such as installation component, supporting leg and second connecting plate, when the staff need install the radiator, only need remove the assigned position with the radiator, again lead to with second connecting plate and air conditioner shell fixed connection support it, fix fixed plate and air conditioner shell again, rotate the action bars again, make the operation drive installation component and prolong, after the installation component prolonged assigned length, only need be connected the mounting panel with air conditioner shell to reach the effect of installing the air conditioner shell of equidimension not, and then promoted staff's work efficiency.

According to the above patent, the following problems occur: the radiator is moved to a designated position, the fixing plate is fixedly connected with the inner side wall of the air conditioner shell, the second connecting plate is fixedly connected with the air conditioner shell, the shell is supported, the operating rod is rotated, the operating rod moves downwards, and when the radiator needs to be cleaned or a component is replaced in time, the integrated structure is difficult to achieve the effect.

Disclosure of Invention

The utility model aims to provide a copper-aluminum composite radiator for heating ventilation and air conditioning, which aims to solve the problems in the background technology.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a copper aluminium composite radiator of heating ventilation air conditioner, relate to radiator technical field, it is integrated structure to have solved current copper aluminium composite radiator and adopted, in normal maintenance work, cause a great deal of inconvenience, including joint pole and radiating component, the joint pole is provided with two sets of, joint has a plurality of groups bracing pieces between two sets of joint poles, and a plurality of groups bracing pieces pass through the joint base and the joint pole joint that both sides terminal offered, two sets of joint poles are kept away from bracing piece both sides regional to be provided with the friction area, the friction area is kept away from the bracing piece both sides and is provided with spacing protruding mouth;

the heat dissipation assembly and the support rod are correspondingly provided with a plurality of groups, the plurality of groups of heat dissipation assemblies are respectively in limiting clamping connection between the support rods, the heat dissipation assembly is provided with heat dissipation fins far away from the outer surface of one side of the corresponding support rod, the heat dissipation fins are arranged in parallel and are fixedly connected to the heat dissipation assembly.

Preferably, the limit lug is provided with four groups, and the four groups of limit lugs are rotationally connected with a limit cap on the outer surface of one side of the friction belt away from.

Preferably, the heat dissipation assembly is provided with a movable shell close to two groups of outer surfaces of two sides of the connecting rod in a clamping manner, the movable shells are located in the peripheral area of the connecting rod, and a shell holding groove is formed in the outer surface of one side of the movable shell, which is far away from the heat dissipation assembly.

Preferably, grooves are formed in the outer surfaces of two sides, close to the connecting rods, of the plurality of groups of heat dissipation assemblies, convex grooves are respectively formed in two ports, close to the outer surface of one side of each heat dissipation assembly, of the movable shell, and the two groups of the convex grooves are in sliding connection with the corresponding grooves.

Preferably, grooves are formed in the outer surfaces of two sides, close to the connecting rods, of the plurality of groups of heat dissipation assemblies, convex grooves are respectively formed in two ports, close to the outer surface of one side of each heat dissipation assembly, of the movable shell, and the two groups of the convex grooves are in sliding connection with the corresponding grooves.

Preferably, the heat dissipation assembly is fixedly connected with two groups of heat dissipation limiting convex seats close to the outer surface of one side of the corresponding support rod, and a plurality of groups of tooth grooves are formed in the outer surfaces of the two groups of heat dissipation limiting convex seats.

Preferably, the support rod is fixedly connected with two groups of clamping openings near the outer surface of one side of the heat dissipation assembly, and the two groups of clamping openings are in limit clamping connection with the corresponding tooth grooves.

Preferably, each group of the support rods corresponds to two groups of the clamping openings, and the clamping openings are made of rubber materials with elastic functions.

Compared with the prior art, the utility model has the beneficial effects that:

the utility model can connect a plurality of groups of support rods and connecting rods through the connection of the support rods and the connecting base. The periphery of each group of supporting rods is provided with clamping openings, the openings correspond to tooth grooves on the radiating components and are used for fixing the radiating components and the supporting rods, the distance between the tooth grooves and the clamping openings can be changed by adjusting the positions of the tooth grooves and the clamping openings, so that the radiating effect is adjusted, the outer surfaces of the upper end and the lower end of each group of radiating components are provided with grooves, and meanwhile, the periphery of the movable shell is provided with convex grooves. Through the sliding connection of the two, the effective disassembly of the heat dissipation assembly can be realized.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

FIG. 2 is a schematic view of the overall structure of the utility model after disassembly;

FIG. 3 is a schematic structural view of a body support according to the present utility model;

FIG. 4 is a detailed view of the slip joint of the present utility model;

fig. 5 is a detailed view of the fixing mode of the heat dissipating assembly according to the present utility model.

In the figure: 1-connecting a rod; 2-supporting rods; 3-clamping the opening; 4-connecting a base; 5-radiating fins; 6-a heat dissipation assembly; 7-friction belt; 8-a movable housing; 9-a limit cap; 10-limiting convex openings; 11-a housing grip; 12-a heat dissipation limit boss; 13-tooth slots; 14-grooves; 15-convex grooves.

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. 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.

Example 1

Referring to fig. 1-4, in the drawings, a copper-aluminum composite radiator of a heating ventilation air conditioner comprises a connecting rod 1 and a radiating component 6, wherein the connecting rod 1 is provided with two groups, a plurality of groups of supporting rods 2 are clamped between the two groups of connecting rods 1, the plurality of groups of supporting rods 2 are clamped with the connecting rods 1 through connecting bases 4 arranged at the tail ends of two sides, friction belts 7 are arranged in areas, away from two sides of the supporting rods 2, of the two groups of connecting rods 1, limiting bosses 10 are arranged on two sides, away from the supporting rods 2, of the friction belts 7, a plurality of groups of radiating components 6 are correspondingly arranged with the supporting rods 2, the plurality of groups of radiating components 6 are respectively clamped between the supporting rods 2 in a limiting manner, radiating fins 5 are arranged on the outer surface, away from one side, corresponding to the supporting rods 2, of the radiating fins 5 are arranged in parallel, and the plurality of groups of radiating fins 5 are fixedly connected to the radiating components 6.

Grooves 14 are formed on the outer surfaces of two sides of the heat dissipation assemblies 6, which are close to the connecting rod 1, two ports of the movable shell 8, which are close to the outer surface of one side of the heat dissipation assemblies 6, are respectively provided with a convex groove 15, and the two groups of convex grooves 15 are in sliding connection with the corresponding grooves 14.

Grooves 14 are formed in the outer surfaces of the upper end and the lower end of each group of heat dissipation components 6, and meanwhile, convex grooves 15 are formed in the periphery of the movable shell 8. Through the sliding connection of the two, the effective disassembly of the heat radiation component can be realized, when the heat radiation component 6 needs to be cleaned or replaced, the movable shell 8 is only required to be separated from the heat radiation component 6, and then the heat radiation component 6 can be easily slid out from the convex groove 15.

Example 2

Referring to fig. 2 and 5, this embodiment further describes example 1: the limit lugs 10 are provided with four groups, and the outer surface of one side of the four groups of limit lugs 10, which is far away from the friction belt 7, is rotatably connected with a limit cap 9.

Two groups of heat dissipation limiting convex seats 12 are fixedly connected to the outer surface of one side of the heat dissipation assembly 6, which is close to the corresponding support rod 2, and a plurality of groups of tooth grooves 13 are formed in the outer surfaces of the two groups of heat dissipation limiting convex seats 12.

Two groups of clamping openings 3 are fixedly connected to the outer surface of the side, close to the corresponding radiating component 6, of the supporting rod 2, and the two groups of clamping openings 3 are in limit clamping connection with the corresponding tooth grooves 13.

Each group of support rods 2 corresponds to two groups of clamping openings 3, and the clamping openings 3 are made of rubber materials with elastic functions.

Through the linking of bracing piece 2 and linking base 4, can connect multiunit bracing piece 2 and linking pole 1, every group bracing piece 2 periphery has set up joint opening 3, and these openings correspond with tooth's socket 13 on the radiator unit 6 for fixed radiator unit and bracing piece, simultaneously, through adjusting the position of tooth's socket 13 and joint opening 3, can change the distance between them, thereby adjust the radiating effect.

Example 3

Referring to fig. 2-4, this embodiment further illustrates example 1: the outer surfaces of the two sides of the two groups of connecting rods 1, which are close to the two groups of radiating assemblies 6, are clamped with movable shells 8, the plurality of groups of movable shells 8 are positioned in the peripheral area of the connecting rods 1, and the outer surfaces of one side, far away from the radiating assemblies 6, of the movable shells 8 are provided with shell holding grooves 11.

Grooves 14 are formed on the outer surfaces of two sides of the heat dissipation assemblies 6, which are close to the connecting rod 1, two ports of the movable shell 8, which are close to the outer surface of one side of the heat dissipation assemblies 6, are respectively provided with a convex groove 15, and the two groups of convex grooves 15 are in sliding connection with the corresponding grooves 14.

Two groups of clamping openings 3 are fixedly connected to the outer surface of one side of the support rod 2, which is close to the corresponding heat dissipation assembly 6, and the two groups of clamping openings 3 are in limit clamping connection with the corresponding tooth grooves 13.

Through being provided with the casing at movable housing 8 and keeping away from radiating component 6 one side surface and holding groove 11, such design makes maintainer conveniently clean and change work, has reduced the time and the effort of maintaining, simultaneously, this kind of sliding connection's design has also ensured radiating component 6 stability when normal operating, can not influence the radiating effect because of not hard up or rocking.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. A copper-aluminum composite radiator for heating ventilation air conditioner, comprising:

the connecting rod (1), connecting rod (1) is provided with two groups, two groups connect rod (1) between the joint have a plurality of groups bracing piece (2), and a plurality of groups bracing piece (2) through the terminal joint base (4) of seting up in both sides with connecting rod (1) joint, two groups connecting rod (1) keep away from bracing piece (2) both sides regional be provided with friction area (7), friction area (7) keep away from bracing piece (2) both sides are provided with spacing tang (10);

the cooling assembly (6), cooling assembly (6) with bracing piece (2) correspond and are provided with a plurality of groups, and a plurality of groups cooling assembly (6) are spacing joint respectively between bracing piece (2), cooling assembly (6) keep away from corresponding bracing piece (2) one side surface is provided with fin (5), fin (5) parallel arrangement has a plurality of groups, and a plurality of groups fin (5) fixed connection is in on cooling assembly (6).

2. The copper-aluminum composite radiator for heating ventilation and air conditioning according to claim 1, wherein: the limiting convex openings (10) are provided with four groups, and the outer surfaces of the four groups of limiting convex openings (10) far away from one side of the friction belt (7) are rotatably connected with limiting caps (9).

3. The copper-aluminum composite radiator for heating ventilation and air conditioning according to claim 1, wherein: a plurality of groups radiating component (6) are close to two groups the joint of the outer surface of the two sides of the connecting rod (1) is provided with a movable shell (8), and a plurality of groups of movable shells (8) are located in the peripheral area of the connecting rod (1), and the outer surface of one side of the movable shell (8) far away from the radiating component (6) is provided with a shell holding groove (11).

4. A copper-aluminum composite radiator for heating ventilation and air conditioning according to claim 3, wherein: the two outer surfaces of the plurality of groups of heat dissipation components (6) close to the connecting rod (1) are provided with grooves (14), two ports of the movable shell (8) close to the outer surface of one side of the heat dissipation components (6) are respectively provided with a convex groove (15), and the two groups of convex grooves (15) are in sliding connection with the corresponding grooves (14).

5. A copper-aluminum composite radiator for heating ventilation and air conditioning according to claim 3, wherein: two groups of heat dissipation limiting convex seats (12) are fixedly connected to the outer surface of one side of the heat dissipation assembly (6) close to the corresponding support rod (2), and a plurality of groups of tooth grooves (13) are formed in the outer surfaces of the two groups of heat dissipation limiting convex seats (12).

6. The copper-aluminum composite radiator for heating ventilation and air conditioning according to claim 5, wherein: two groups of clamping openings (3) are fixedly connected to the outer surface of one side of the support rod (2) close to the corresponding radiating component (6), and the two groups of clamping openings (3) are in limit clamping connection with the corresponding tooth grooves (13).

7. The copper-aluminum composite radiator for heating ventilation and air conditioning according to claim 6, wherein: each group of supporting rods (2) corresponds to two groups of clamping openings (3), and the clamping openings (3) are made of rubber materials with elastic functions.