CN217226728U - Plastic-aluminum combination radiator make-up machine - Google Patents

Abstract

The utility model provides an aluminum-plastic combined radiator make-up machine, relates to radiator assembly quality technical field, including radiating unit supporting platform and the end supporting platform that is located its both ends respectively, still is equipped with hot melt subassembly between radiating unit supporting platform and the end supporting platform. The utility model solves the problem that the device in the traditional technology can not realize the synchronous hot melting assembly of the ends of a plurality of radiating units simultaneously; the firmness of the assembly among the plurality of radiating units cannot be ensured; and the problem that the integral assembly of the heat dissipation units with different lengths and different numbers cannot be realized, and the assembly efficiency is reduced.

Description

Plastic-aluminum combination radiator make-up machine

Technical Field

The utility model relates to a radiator assembly quality technical field, concretely relates to plastic-aluminum combination radiator make-up machine.

Background

The existing aluminum-plastic composite radiator is more and more widely applied to daily life of people due to the advantages of light weight, corrosion resistance, low manufacturing cost, good thermal stability, long service life and the like. And the plastic-aluminum composite radiator needs to carry out the hot melting of working of plastics to thereby form complete radiator with pipe fitting and tee bend butt fusion together. At present, the hot melting of plastic parts is generally carried out manually by using a portable hot melting machine to melt the pipe fittings, then the pipe fittings are assembled together, and after cooling, the connection of the pipe fittings is realized. The mode can only melt one end, the working efficiency is low, the length and the size of the hot melting forming are different, the deviation is large, the hot melting quality can not be ensured, and the quality problem of products often occurs.

The prior art discloses a patent with publication number CN203580127U, which includes at least two sets of pipe clamping mechanisms capable of moving relatively, and a movable hot melt device is disposed between the pipe clamping mechanisms; the utility model has the advantages of reasonable design, the dependable performance, stability are good, can realize automated production completely, have improved production efficiency greatly. Most importantly, the hot melting angle of the hot melting device and the pipe fitting is accurately controlled, the hot melting quality can be guaranteed, and the service life of a product is prolonged.

The device exposes the defects of the technology along with the production and use processes, and is mainly represented in the following aspects:

first, the device can only realize carrying out the hot melt assembly to single radiating element's tube head when assembling the fin, can't realize carrying out synchronous hot melt assembly to a plurality of radiating element's end simultaneously, and work efficiency is low.

Second, when unifying the assembly to a plurality of radiating element, can't guarantee the fastness of the assembly between a plurality of radiating element for when the radiator later stage was used, the phenomenon of leaking easily appeared.

Thirdly, the device can not realize the integral assembly of the heat dissipation units with different lengths and different numbers, thereby reducing the assembly efficiency.

In view of the foregoing, it is apparent that the prior art has inconvenience and disadvantages in practical use, and thus, needs to be improved.

SUMMERY OF THE UTILITY MODEL

Aiming at the defects in the prior art, the utility model provides an aluminum-plastic combined radiator forming machine, which is used for solving the problem that the device in the traditional technology can not realize the synchronous hot melting assembly of the ends of a plurality of radiating units; the firmness of the assembly among the plurality of radiating units cannot be ensured; and the integral assembly of the heat dissipation units with different lengths and different numbers can not be realized, and the assembly efficiency is reduced.

In order to achieve the above object, the utility model provides a following technical scheme:

the utility model provides an aluminum-plastic combined radiator make-up machine, includes radiating unit supporting platform and the end supporting platform that is located its both ends respectively, radiating unit supporting platform with still be equipped with hot melt subassembly between the end supporting platform.

As an optimized scheme, when the end supporting platform moves towards the heat dissipation unit supporting platform, the end supporting platform firstly abuts against the hot melting assembly through a linkage piece, and the hot melting assembly is pushed to abut against the heat dissipation unit supporting platform.

As an optimized scheme, the hot melting assembly is further arranged in a vertically sliding mode and used for avoiding a heat sealing space between the heat dissipation unit supporting platform and the end head supporting platform.

As an optimized scheme, the heat dissipation unit supporting platform comprises two supporting seats which are horizontally arranged in parallel, wherein one supporting seat is transversely adjusted to be spaced from the other supporting seat through an adjusting piece.

As an optimized scheme, a heat dissipation unit assembling seat used for assembling a plurality of heat dissipation units is detachably arranged between the two supporting seats.

As an optimized scheme, the heat dissipation unit assembling seat comprises a bottom plate, clamping plates are fixedly connected to two ends of the bottom plate respectively, and a plurality of supporting grooves which are supported by end pipes of the heat dissipation units are formed in the clamping plates in parallel.

As an optimized scheme, the adjusting piece comprises a screw rod horizontally and rotatably mounted on one of the supporting seats, and the other supporting seat is in threaded connection with the screw rod through a traversing seat.

As an optimized scheme, a driving machine for driving the lead screw to rotate is further fixedly connected to the supporting seat.

As an optimized scheme, an end connecting pipe fixing seat used for fixing an end connecting pipe is detachably arranged on the end supporting platform.

As an optimized scheme, the end connecting pipe fixing seat comprises a box shell, and the box shell faces to an opening on one side of the hot melting assembly.

As an optimized scheme, the upper surface of the end head supporting platform is further fixedly connected with a positioning block, and the bottom surface of the box shell is provided with a positioning groove matched with the positioning block.

As an optimized scheme, the hot melting assembly comprises a connecting seat, one side of the connecting seat is fixedly connected with a hot melting head matched with the end connecting pipe, and the other side of the connecting seat is fixedly connected with a hot melting pipe matched with the end pipe of the heat dissipation unit.

As an optimized scheme, the linkage piece comprises a supporting block, the hot melting assembly is installed on the supporting block in a sliding mode along the vertical direction, a long pressure spring and a short pressure spring are horizontally and fixedly connected to the opposite side walls of the supporting block, the long pressure spring abuts against the supporting seat, and the short pressure spring abuts against the end supporting platform.

As an optimized scheme, a supporting plate is slidably mounted on the end supporting platform, a vertical cylinder is fixedly connected to the supporting plate, a sliding hole is further vertically formed in the supporting plate, and a telescopic shaft of the vertical cylinder penetrates through the sliding hole and is fixedly connected with the lower end portion of the connecting seat.

As an optimized scheme, the end head supporting platform is further fixedly connected with a transverse cylinder which horizontally pushes the end head supporting platform to transversely move.

As an optimized scheme, a rack is fixedly connected below the two supporting seats, the supporting seats are fixed in position, the transverse air cylinders on one sides of the supporting seats are fixedly connected onto the rack, the supporting seats are arranged in a sliding mode, the transverse air cylinders on one sides of the supporting seats are fixedly connected onto the transverse moving seat, and the transverse moving seat is slidably mounted on the rack.

As an optimized scheme, the upper end parts of the two supporting seats are fixedly connected with positioning bulges, and the positioning bulges are abutted against the end parts of the bottom plate.

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

the heat dissipation unit assembling seat can be used for placing a plurality of heat dissipation units on the heat dissipation unit assembling seat together, then the heat dissipation unit assembling seat is moved to the two supporting seats, the end connecting pipe is placed in the box shell, then the box shell is moved to the end supporting platform, after the heat dissipation unit end connecting pipe and the end connecting pipe are subjected to hot melting simultaneously by using the hot melting assembly, the end connecting pipe is connected to the heat dissipation unit end connecting pipe in a butt joint mode, synchronous assembling of the plurality of heat dissipation units is completed, and stability and firmness of assembling among the plurality of heat dissipation units are guaranteed;

one supporting seat is transversely adjusted to the other supporting seat through the transverse moving seat, so that the heat dissipation units with different lengths are assembled, and the assembly and use range is enlarged;

the energy consumption of the device is lower than that of 1/50 in the traditional welding mode, only 50 seconds are needed for assembling and molding from a plurality of radiating units to a group of 30 radiators, and 300 connectors can be assembled by using one-hour electricity in normal production;

the manufacturing cost is low, and the maintenance is convenient; the design is reasonable, and the matching among structures is precise; the operation is convenient and quick; the follow-up part is simplified, and the fault rate in the working process is reduced; the stability in the working process is improved; the parts are few, the process is simple and convenient, and the failure rate is low; the structure is simple, and the service life is long; simple and convenient operation and control, easy large-scale manufacture and installation and wide application range.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the technical solutions in the prior art will be briefly described below. Throughout the drawings, like elements or portions are generally identified by like reference numerals. In the drawings, elements or portions are not necessarily drawn to scale.

Fig. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic structural diagram of a second step of the operation process in the embodiment of the present invention;

FIG. 3 is a schematic structural diagram of a fifth working process in the embodiment of the present invention;

fig. 4 is a schematic structural view of the heat dissipating unit assembling base of the present invention;

in the figure: 1-a heat dissipation unit support platform; 2-a hot-melt assembly; 3-an end support platform; 4-a supporting seat; 5-radiating unit end pipe; 6-connecting the end with a pipe; 7-a lead screw; 8-a transverse moving seat; 9-a box shell; 10-a connecting seat; 11-a thermofusion tube; 12-a thermal melting head; 13-positioning blocks; 14-a support block; 15-long pressure spring; 16-short compression spring; 17-a vertical cylinder; 18-a support plate; 19-a transverse cylinder; 20-a frame; 21-a bottom plate; 22-catch plate; 23-a support groove; 24-heat dissipation unit.

Detailed Description

Embodiments of the present invention will be described in detail below with reference to the accompanying drawings. The following examples are only for illustrating the technical solutions of the present invention more clearly, and therefore are only examples, and the protection scope of the present invention is not limited thereby.

As shown in fig. 1 to 4, the aluminum-plastic combined radiator forming machine includes a heat dissipation unit supporting platform 1 and end supporting platforms 3 respectively located at two ends of the heat dissipation unit supporting platform 1, and a hot melt assembly 2 is further disposed between the heat dissipation unit supporting platform 1 and the end supporting platforms 3.

When the end supporting platform 3 moves towards the heat dissipation unit supporting platform 1, the end supporting platform firstly supports against the hot melting assembly 2 through the linkage piece, and pushes the hot melting assembly 2 to support against the heat dissipation unit supporting platform 1.

The hot melting assembly 2 is also arranged in a vertically sliding mode and used for avoiding a heat sealing space between the heat dissipation unit supporting platform 1 and the end supporting platform 3.

The heat dissipation unit supporting platform 1 comprises two supporting seats 4 which are horizontally arranged in parallel, wherein one supporting seat 4 is transversely adjusted to the distance between the other supporting seat 4 through an adjusting piece.

A heat dissipating unit assembling seat for assembling a plurality of heat dissipating units 24 is detachably mounted between the two supporting seats 4.

The heat dissipation unit assembling seat comprises a bottom plate 21, two ends of the bottom plate 21 are respectively and fixedly connected with a clamping plate 22, and a plurality of supporting grooves 23 which are supported with the heat dissipation unit end pipes 5 are arranged on the clamping plates 22 in parallel.

The adjusting piece comprises a lead screw 7 horizontally and rotatably mounted on one of the supporting seats 4, and the other supporting seat 4 is in threaded connection with the lead screw 7 through a traversing seat 8.

A driving machine for driving the screw rod 7 to rotate is also fixedly connected to the supporting seat 4.

An end connecting pipe fixing seat used for fixing the end connecting pipe 6 is detachably arranged on the end supporting platform 3.

The end connecting pipe fixing seat comprises a box shell 9, and the box shell 9 is arranged towards an opening on one side of the hot-melt component 2.

The upper surface of the end supporting platform 3 is also fixedly connected with a positioning block 13, and the bottom surface of the box shell 9 is provided with a positioning groove matched with the positioning block 13.

The hot melting component 2 comprises a connecting seat 10, one side of the connecting seat 10 is fixedly connected with a hot melting head 12 matched with the end head connecting pipe 6, and the other side of the connecting seat 10 is fixedly connected with a hot melting pipe 11 matched with the heat dissipation unit end head pipe 5.

The linkage piece comprises a supporting block 14, the hot-melt component 2 is installed on the supporting block 14 in a vertical sliding mode, a long pressure spring 15 and a short pressure spring 16 are fixedly connected to the opposite side walls of the supporting block 14 horizontally, the long pressure spring 15 abuts against a supporting seat 4, the short pressure spring 16 abuts against an end supporting platform 3, the elasticity of the long pressure spring 15 and the small short pressure spring 16 achieve abutting against the hot-melt component 2 firstly, and the hot-melt component 2 is pushed to abut against the heat dissipation unit supporting platform 1.

A supporting plate 18 is slidably mounted on the end supporting platform 3, a vertical cylinder 17 is fixedly connected to the supporting plate 18, a sliding hole is vertically formed in the supporting block 14, and a telescopic shaft of the vertical cylinder 17 penetrates through the sliding hole and is fixedly connected with the lower end part of the connecting seat 10.

The end head supporting platform 3 is also fixedly connected with a transverse air cylinder 19 which horizontally pushes the end head supporting platform to transversely move.

A frame 20 is fixedly connected below the two supporting seats 4, the supporting seat 4 is fixed in position, a transverse air cylinder 19 on one side of the supporting seat is fixedly connected to the frame 20, the supporting seat 4 is arranged in a sliding mode, a transverse air cylinder 19 on one side of the supporting seat is fixedly connected to the transverse moving seat 8, and the transverse moving seat 8 is installed on the frame 20 in a sliding mode.

The upper ends of the two supporting seats 4 are also fixedly connected with positioning bulges which are propped against the end part of the bottom plate 21.

The working principle of the device is as follows:

firstly, a plurality of radiating units 24 can be jointly placed on the radiating unit assembling seat through the radiating unit assembling seat, and then the radiating unit assembling seat is moved to the two supporting seats 4; placing the end connecting pipe 6 in the box shell 9, and then moving the box shell 9 to the end supporting platform 3;

secondly, the transverse cylinder 19 acts to push the end head supporting platform 3 to move, the end head connecting pipe 6 is in contact with the hot melting head 12 before the end head connecting pipe 6 is melted to form a mounting hole, then the end head supporting platform 3 pushes the hot melting assembly 2 to move continuously, and the hot melting pipe 11 is in hot melting with the outer wall of the heat dissipation unit end head pipe 5 for a plurality of seconds;

thirdly, the transverse cylinder 19 acts to drive the end supporting platform 3 to return, and the hot melting assembly 2 resets under the elasticity of the long pressure spring 15 and the short pressure spring 16;

fourthly, the vertical cylinder 17 acts to drive the hot melting assembly 2 to move downwards to avoid a thermal combination space;

fifthly, the transverse cylinder 19 acts to push the end head supporting platform 3 to move, the mounting hole of the end head connecting pipe 6 is connected to the heat dissipation unit end head pipe 5 in a butt joint mode, the operation is kept for a plurality of seconds, and the end head connecting pipe 6 is solidified on the heat dissipation unit end head pipe 5;

sixthly, after the transverse cylinder 19 acts to drive the end head supporting platform 3 to return, the vertical cylinder 17 acts to drive the hot melting assembly 2 to move downwards between the supporting seat 4 and the end head supporting platform 3, and hot melting work is finished;

and seventhly, after the heat dissipation unit assembling seat and the box shell 9 are disassembled, the next round of work is carried out.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; such modifications and substitutions do not substantially depart from the scope of the embodiments of the present invention, and are intended to be covered by the claims and the specification.

Claims (8)

1. The utility model provides an aluminum-plastic composite radiator make-up machine which characterized in that: including heat dissipation unit supporting platform (1) and end supporting platform (3) that are located its both ends respectively, heat dissipation unit supporting platform (1) with still be equipped with hot melt subassembly (2) between end supporting platform (3), heat dissipation unit supporting platform (1) includes supporting seat (4) that two levels set up side by side, one of them supporting seat (4) are followed horizontal regulation its and another through the regulating part the interval of supporting seat (4), two it is used for carrying out the heat dissipation unit equipment seat of assembling to a plurality of heat dissipation unit (24) to go back detachable the installing between supporting seat (4).

2. The aluminum-plastic combined radiator forming machine of claim 1, characterized in that: when the end supporting platform (3) moves towards the heat dissipation unit supporting platform (1), the end supporting platform firstly abuts against the hot melting assembly (2) through a linkage piece, and the hot melting assembly (2) is pushed to abut against the heat dissipation unit supporting platform (1).

3. The aluminum-plastic combined radiator forming machine of claim 1, characterized in that: the hot melting assembly (2) is arranged in a sliding mode vertically and used for avoiding a heat sealing space between the heat dissipation unit supporting platform (1) and the end head supporting platform (3).

4. The aluminum-plastic combined radiator forming machine according to claim 1, characterized in that: an end connecting pipe fixing seat used for fixing the end connecting pipe (6) is detachably arranged on the end supporting platform (3).

5. The aluminum-plastic combined radiator forming machine as claimed in claim 2, wherein: the hot melt assembly (2) comprises a connecting seat (10), one side of the connecting seat (10) is fixedly connected with a hot melt head (12) matched with the end connecting pipe (6), and the other side of the connecting seat (10) is fixedly connected with a hot melt pipe (11) matched with the heat dissipation unit end connecting pipe (5).

6. The aluminum-plastic combined radiator forming machine according to claim 5, characterized in that: the linkage piece comprises a supporting block (14), the hot-melting assembly (2) is installed on the supporting block (14) in a sliding mode along the vertical direction, a long pressure spring (15) and a short pressure spring (16) are fixedly connected to the opposite side walls of the supporting block (14) horizontally, the long pressure spring (15) abuts against the supporting seat (4), and the short pressure spring (16) abuts against the end supporting platform (3).

7. The aluminum-plastic combined radiator forming machine of claim 6, wherein: the end supporting platform (3) is provided with a supporting plate (18) in a sliding mode, a vertical air cylinder (17) is fixedly connected to the supporting plate (18), a sliding hole is formed in the supporting block (14) in the vertical direction, and a telescopic shaft of the vertical air cylinder (17) penetrates through the sliding hole and is fixedly connected with the lower end portion of the connecting seat (10).

8. The aluminum-plastic combined radiator forming machine of claim 1, characterized in that: the end head supporting platform (3) is further fixedly connected with a transverse cylinder (19) which horizontally pushes the end head supporting platform to transversely move.

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