CN218595444U - Radiator shunting and pairing device - Google Patents

Abstract

The utility model discloses a radiator shunting and pairing device, which comprises a bottom plate, wherein the bottom plate is provided with an inlet guide groove, a first shunting guide groove, a second shunting guide groove, a shunting cylinder group, a first propelling cylinder group, a second propelling cylinder group and a pair-overlapping cylinder; the other end of the first diversion guide groove is intersected with the other end of the second diversion guide groove; the first propelling cylinder group is used for propelling the radiator to move to the opposite folding position along the first split guide groove, and the second propelling cylinder group is used for propelling the radiator to move to the opposite folding position along the second split guide groove; the first diversion guide groove and the second diversion guide groove are provided with turnover mechanisms; the oppositely-overlapped air cylinder is arranged at the position where the oppositely-overlapped position is located. The utility model discloses in can realize two liang of pairs of radiator to accomplish the to folding combination between two radiators, labour saving and time saving has improved the operating efficiency.

Description

Radiator shunting and pairing device

Technical Field

The utility model relates to a hacking machine technical field, in particular to radiator hacking machine.

Background

A conventional heat sink structure is shown in fig. 1, in which a heat sink 1 includes a heat dissipation base plate 2 and a plurality of fins 3 disposed on one side of the heat dissipation base plate 2. After the radiator is manufactured, the radiator needs to be orderly stacked together, so that subsequent packaging and delivery are facilitated.

The conventional stacking mode is shown in the attached figure 2: the heat radiators are manually paired in a mode of forming a group by two heat radiators, the two heat radiators are overlapped together, and then the overlapped heat radiators are placed on the material tray in order to wait for being packaged and delivered.

When the existing radiators are oppositely stacked, manual operation is needed, the manual operation is troublesome, time and labor are wasted, and the efficiency is low.

Disclosure of Invention

The utility model aims at solving current radiator and need manual operation when going on to folding, manual operation is comparatively troublesome, wastes time and energy, and the problem of inefficiency provides a radiator reposition of redundant personnel and pairs the device, can effectively solve above-mentioned problem.

The purpose of the utility model is realized through the following technical scheme: a radiator shunting and pairing device is characterized by comprising a bottom plate, wherein an entering guide groove, a first shunting guide groove, a second shunting guide groove, a shunting cylinder group, a first propelling cylinder group, a second propelling cylinder group and a pairing cylinder are arranged on the bottom plate; the other end of the first diversion guide groove and the other end of the second diversion guide groove are intersected and form a butt-overlapping position at the intersection; the flow dividing cylinder group is used for dividing the radiator entering the guide groove into a first flow dividing guide groove and a second flow dividing guide groove; the first propelling cylinder group is used for propelling the radiator to move to the opposite folding position along the first diversion guide groove, and the second propelling cylinder group is used for propelling the radiator to move to the opposite folding position along the second diversion guide groove; the turnover mechanisms are arranged on the first diversion guide groove and the second diversion guide groove and used for turning over the radiators so that the fins on the two radiators are in an opposite state after the radiators on the first diversion guide groove and the second diversion guide groove reach the opposite overlapping position; the oppositely-overlapped air cylinder is arranged at the position where the oppositely-overlapped position is located.

Preferably, the first diversion guide groove comprises a first diversion section, a first pushing section and a first converging section, the second diversion guide groove comprises a second diversion section, a second pushing section and a second converging section, two ends of the first pushing section are respectively connected with one end of the first diversion section and one end of the first converging section, two ends of the second pushing section are respectively connected with one end of the second diversion section and one end of the second converging section, and one end of the first diversion section, which is far away from the first pushing section, and one end of the second diversion section, which is far away from the second pushing section, are intersected at the diversion position; the end of the first intersection section far away from the first shunt section and the end of the second intersection section far away from the second shunt section are intersected at the opposite overlapping position; turning positions are arranged at the joint of the first shunting section and the first pushing section and the joint of the second shunting section and the second pushing section, and the turning mechanism is arranged on the turning positions; the radiators enter the diversion positions one by one along the entering guide grooves, and the diversion cylinder group pushes the radiators on the diversion positions into the turning positions on the first diversion guide groove and the second diversion guide groove in sequence and alternately.

Preferably, the first propelling cylinder group comprises a first longitudinal propelling cylinder arranged at one end of the first propelling section and a first transverse propelling cylinder arranged at one end of the first intersection section, the first longitudinal propelling cylinder propels the radiator to the intersection of the first propelling section and the first intersection section, and the first transverse propelling cylinder propels the radiator to the opposite overlapping position; the second propelling cylinder group comprises a second longitudinal pushing cylinder arranged at one end of the second propelling section and a second transverse pushing cylinder arranged at one end of the second intersection section, the second longitudinal pushing cylinder pushes the radiator to the intersection of the second propelling section and the second intersection section, and the second transverse pushing cylinder pushes the radiator to the opposite stacking position.

Preferably, the turnover mechanism comprises a mounting substrate, a turnover block and a turnover cylinder, the mounting substrate is fixed below the turnover position, one end of the turnover block is rotatably connected to the mounting substrate, the other end of the turnover block is rotatably connected with one end of the turnover cylinder, and one end of the turnover cylinder, which is far away from the turnover block, is rotatably connected with the mounting substrate; the turnover block has a horizontal state and a turnover state under the driving of the turnover cylinder, and when the turnover block is in the horizontal state, the upper end surface of the turnover block is flush with the bottom surface of the turnover bit; the turnover mechanisms on the first diversion guide groove and the second diversion guide groove respectively turn over the radiator by 90 degrees, and the turnover direction of the turnover mechanism on the first diversion guide groove to the radiator is opposite to the turnover direction of the turnover mechanism on the second diversion guide groove to the radiator.

Preferably, the first split cylinder is arranged in parallel with the first split section, and the second split cylinder is arranged in parallel with the second split section.

Preferably, the first longitudinal pushing cylinder is arranged in parallel with the first pushing section, and the second longitudinal pushing cylinder is arranged in parallel with the second pushing section.

Preferably, the first transverse pushing cylinder is arranged in parallel with the first converging section, and the second transverse pushing cylinder is arranged in parallel with the second converging section.

The beneficial effects of the utility model are that: the utility model discloses in can realize two liang of parings of radiator to accomplish the combination of folding between two radiators, the whole of radiator is paird and is folded the process and need not artifical the participation, has realized the automation mechanized operation, has reduced the cost of labor, and labour saving and time saving has improved the operating efficiency.

Drawings

Fig. 1 is a schematic structural diagram of a conventional heat sink.

Fig. 2 is a schematic view of stacking conventional heat sinks.

Fig. 3 is a schematic structural diagram of the present invention.

Fig. 4 is a schematic structural view of the turnover mechanism.

In the figure: 1. the heat radiator comprises a heat radiator body, 2, a heat radiator bottom plate, 3, fins, 15, a bottom plate, 16, an entering guide groove, 17, a first diversion guide groove, 18, a second diversion guide groove, 19, a butt-stacking position, 20, a turnover mechanism, 21, a first diversion cylinder, 22, a second diversion cylinder, 23, a first longitudinal pushing cylinder, 24, a second longitudinal pushing cylinder, 25, a first transverse pushing cylinder, 26, a second transverse pushing cylinder, 27, a butt-stacking cylinder, 30, an installation substrate, 31, a turnover block, 32 and a turnover cylinder.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art all belong to the protection scope of the present invention.

It will be understood by those skilled in the art that in the present disclosure, the terms "longitudinal," "lateral," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in a generic and descriptive sense only and not for purposes of limitation, as the terms are used in the description to indicate that the referenced device or element must have the specified orientation, be constructed and operated in the specified orientation, and not for the purposes of limitation.

It is understood that the terms "a" and "an" should be interpreted as meaning that a number of one element or element is one in one embodiment, while a number of other elements is one in another embodiment, and the terms "a" and "an" should not be interpreted as limiting the number.

As shown in fig. 3-4, a heat sink flow splitting pair apparatus is used to stack and combine heat sinks 1 together in groups of two. The radiator flow dividing and matching device comprises a bottom plate 15, wherein an inlet guide groove 16, a first flow dividing guide groove 17, a second flow dividing guide groove 18, a flow dividing cylinder group, a first propelling cylinder group, a second propelling cylinder group and a pair-overlapping cylinder 27 are arranged on the bottom plate 15, one end of the first flow dividing guide groove 17 and one end of the second flow dividing guide groove 18 are intersected with one end of the inlet guide groove 16, and a flow dividing position is formed at the intersection. The other end of the first diverging guide groove 17 and the other end of the second diverging guide groove 18 meet and form a butt-lap 19 at the meeting. The branch cylinder group is used to branch the radiator 1 that has entered the guide groove 16 into the first branch guide groove 17 and the second branch guide groove 18. The widths of the entrance guide groove 16, the first diverging guide groove 17, and the second diverging guide groove 18 are slightly larger than the width of the heat sink 1, so that the heat sink 1 can pass only one by one among the entrance guide groove 16, the first diverging guide groove 17, and the second diverging guide groove 18.

Wherein, the branch cylinder group includes a first branch cylinder 21 and a second branch cylinder 22, and the first branch cylinder 21 and the second branch cylinder 22 are respectively located on both sides of the branch position. The radiators 1 enter the inlet guide groove 16 one by one and sequentially reach the split position, the split cylinder group sequentially and alternately pushes the radiators on the split position into the first split guide groove 17 and the second split guide groove 18, the first split cylinder 21 is used for pushing the radiators 1 into the first split guide groove 17, and the second split cylinder 22 is used for pushing the radiators 1 into the second split guide groove 18.

The first cylinder group is used for pushing the radiator 1 to move to the folded position 19 along the first split guide groove, and the second cylinder group is used for pushing the radiator 1 to move to the folded position 19 along the second split guide groove 18. All be equipped with tilting mechanism 20 on first reposition of redundant personnel guide way 17 and the second reposition of redundant personnel guide way 18, tilting mechanism 20 is used for overturning radiator 1 and makes radiator 1 on first reposition of redundant personnel guide way 17 and the second reposition of redundant personnel guide way 18 reach to folding position 19 after, and fin 3 on two radiators 1 is in relative state. The oppositely-overlapping cylinder 27 is arranged at the position of the oppositely-overlapping position 19, when the two radiators 1 reach the oppositely-overlapping position, a piston rod on the oppositely-overlapping cylinder 27 extends out and pushes one radiator 1 to enable the two radiators 1 to be combined in an oppositely-overlapping mode to form a radiator oppositely-overlapping mode, and when the two radiators 1 are overlapped, the fins 3 on the two radiators 1 are mutually inserted in an oppositely-overlapping mode, so that the oppositely-overlapping mode is realized.

Further, the first diversion guide groove 17 comprises a first diversion section, a first pushing section and a first converging section, the second diversion guide groove 18 comprises a second diversion section, a second pushing section and a second converging section, two ends of the first pushing section are respectively connected with one end of the first diversion section and one end of the first converging section, and two ends of the second pushing section are respectively connected with one end of the second diversion section and one end of the second converging section; the first diversion section and the first converging section are perpendicular to the first pushing section, and the second diversion section and the second converging section are perpendicular to the second pushing section. One end of the first shunting section, which is far away from the first pushing section, and one end of the second shunting section, which is far away from the second pushing section, intersect at the shunting position, and when the radiator 1 moves to the shunting position, the radiator 1 is also just at one end of the first shunting section and one end of the second shunting section. The end of the first junction section distal from the first diverging section meets the end of the second junction section distal from the second diverging section at an opposing overlap 19. The joint of the first shunting section and the first pushing section and the joint of the second shunting section and the second pushing section are both provided with turnover positions, and each turnover position is provided with a turnover mechanism. The radiators 1 enter the diversion positions one by one along the entry guide grooves, and the diversion cylinder group pushes the radiators 1 on the diversion positions alternately into the inversion positions on the first diversion guide grooves 17 and the second diversion guide grooves 18 in sequence.

Specifically, the turnover mechanism is including setting up mounting substrate 30, upset piece 31, upset cylinder 32, and mounting substrate 30 is fixed in the below of upset position, and the one end of upset piece 31 is rotated and is connected on mounting substrate 30, and the other end of upset piece 31 rotates with the one end of upset cylinder 32 to be connected, and the one end that upset block 31 was kept away from to upset cylinder 32 rotates with mounting substrate 30 to be connected. The inverting cylinder 32 drives the inverting block 31 to invert. The overturning block 31 has a horizontal state and an overturning state under the driving of the overturning cylinder 32, and when the overturning block 31 is in the horizontal state, the upper end surface of the overturning block 31 is flush with the bottom surface of the overturning position; when the turning block 31 is turned 90 degrees from the horizontal state to the turning state, the turning block is higher than the bottom surface of the turning position. When the radiator 1 enters the overturning position, a radiator bottom plate on the radiator 1 faces downwards, and the radiator bottom plate is positioned above the overturning block; when the radiator is turned over, the turning block 31 is turned over by 90 degrees, so that the radiator is driven to be turned over by 90 degrees towards one side. The turnover mechanisms on the first diversion guide groove 17 and the second diversion guide groove 18 respectively turn over the radiator 1 by 90 degrees, and the turning direction of the turnover mechanism on the first diversion guide groove 17 to the radiator is opposite to the turning direction of the turnover mechanism on the second diversion guide groove to the radiator.

The first propelling cylinder group comprises a first longitudinal propelling cylinder 23 arranged at one end of the first propelling section and a first transverse propelling cylinder 25 arranged at one end of the first intersection section; when the radiator reaches the turning position and is turned, the first longitudinal pushing cylinder 23 pushes the radiator 1 to the intersection of the first pushing section and the first intersection section, and the first transverse pushing cylinder 25 pushes the radiator 1 to the opposite folding position 19. The second propelling cylinder group comprises a second longitudinal propelling cylinder 24 arranged at one end of the second propelling section and a second transverse propelling cylinder 26 arranged at one end of the second intersection section, when the radiator reaches the overturning position and overturns, the second longitudinal propelling cylinder 24 pushes the radiator 1 to the intersection of the second propelling section and the second intersection section, and the second transverse propelling cylinder 26 pushes the radiator 1 to the opposite folding position 19. The first flow dividing cylinder is arranged in parallel with the first flow dividing section, and the second flow dividing cylinder is arranged in parallel with the second flow dividing section; the first longitudinal pushing cylinder is arranged in parallel with the first pushing section, and the second longitudinal pushing cylinder is arranged in parallel with the second pushing section; the first transverse pushing cylinder is arranged in parallel with the first converging section, and the second transverse pushing cylinder is arranged in parallel with the second converging section. Under the action of the first propelling cylinder group and the second propelling cylinder group, the two radiators are converged in a butt-lap position, and the two radiators 1 are in an opposite state; then, under the pushing action of the opposite-folding cylinder 27, the two radiators 1 are combined together in an opposite-folding way to form a radiator opposite-folding group. When the two radiators reach the opposite-folding position, the two radiators are staggered by the thickness of one fin in the horizontal direction, so that the fins on the two radiators can be ensured to be inserted into each other and be combined in an opposite-folding mode.

The working method of the device is as follows:

and step 1) the radiators reach the shunting positions one by one through entering the guide grooves in a downward posture of the radiating bottom plate, and under the action of the shunting cylinder group, the radiators sequentially enter the first shunting section and the second shunting section and reach the overturning positions. In the step, the placement postures of the radiators on the inlet guide grooves are that the bottom plates of the radiators face downwards and the fins face upwards, and the radiators move forwards one by one along the inlet guide grooves under the action of an external mechanism and sequentially reach the shunting positions; when the radiator is in shunting, the radiator is pushed into the first shunting guide groove and the second shunting guide groove in sequence by means of alternate operation of the first shunting cylinder and the second shunting cylinder.

And 2) turning the radiators by 90 degrees by using the turning mechanisms on the first diversion guide groove and the second diversion guide groove, wherein the turning direction of the radiators on the first diversion guide groove is opposite to that of the radiators on the second diversion guide groove. After the radiators in the first shunting guide groove and the second shunting guide groove are turned over, a radiator bottom plate on the radiator is perpendicular to the bottom surfaces of the first shunting guide groove and the second shunting guide groove, the orientations of fins on the two radiators are opposite, the fins on the radiator on the first shunting guide groove face to the side where the two radiators are located in the oppositely-overlapped mode, and the radiators on the second shunting guide groove are opposite.

Step 3) pushing the turned radiator to an opposite stacking position along the first diversion guide groove under the action of the first longitudinal pushing cylinder and the first transverse pushing cylinder, pushing the turned radiator to the opposite stacking position along the second diversion guide groove under the action of the second longitudinal pushing cylinder and the second transverse pushing cylinder, and converging the two radiators at the opposite stacking position, wherein fins on the two radiators are in a relative state; the overlapping cylinder extends out to push one radiator, so that the two radiators are paired to form a radiator overlapping group.

The utility model discloses in can realize two liang of pairings of radiator to accomplish the combination of folding between two radiators, the whole of radiator is paird and is need not artifical the participation to folding the process, has realized automated operation, has reduced the cost of labor, and labour saving and time saving has improved the operating efficiency.

The present invention is not limited to the above-mentioned preferred embodiments, and any other products in various forms can be obtained by the teaching of the present invention, but any changes in the shape or structure thereof, which have the same or similar technical solutions as the present invention, fall within the protection scope of the present invention.

Claims (7)

1. A radiator shunting and pairing device is characterized by comprising a bottom plate, wherein an entering guide groove, a first shunting guide groove, a second shunting guide groove, a shunting cylinder group, a first propelling cylinder group, a second propelling cylinder group and a pairing cylinder are arranged on the bottom plate; the other end of the first diversion guide groove and the other end of the second diversion guide groove are intersected and form a butt-overlapping position at the intersection; the flow dividing cylinder group is used for dividing the radiator entering the guide groove into a first flow dividing guide groove and a second flow dividing guide groove; the first propelling cylinder group is used for propelling the radiator to move to the opposite folding position along the first diversion guide groove, and the second propelling cylinder group is used for propelling the radiator to move to the opposite folding position along the second diversion guide groove; the turnover mechanisms are arranged on the first diversion guide groove and the second diversion guide groove and used for turning over the radiators so that the fins on the two radiators are in an opposite state after the radiators on the first diversion guide groove and the second diversion guide groove reach the opposite overlapping position; the oppositely-overlapped air cylinder is arranged at the position where the oppositely-overlapped position is located.

2. The heat sink flow splitting and pairing device according to claim 1, wherein the first flow splitting guide groove comprises a first flow splitting section, a first pushing section and a first merging section, the second flow splitting guide groove comprises a second flow splitting section, a second pushing section and a second merging section, two ends of the first pushing section are respectively connected with one end of the first flow splitting section and one end of the first merging section, two ends of the second pushing section are respectively connected with one end of the second flow splitting section and one end of the second merging section, one end of the first flow splitting section, which is far away from the first pushing section, and one end of the second flow splitting section, which is far away from the second pushing section, meet at a flow splitting position; one end of the first intersection section, which is far away from the first shunt section, and one end of the second intersection section, which is far away from the second shunt section, are intersected at the opposite overlapping position; turning positions are arranged at the joint of the first shunting section and the first pushing section and the joint of the second shunting section and the second pushing section, and the turning mechanism is arranged on the turning positions; the radiators enter the diversion positions one by one along the entering guide grooves, and the diversion cylinder group pushes the radiators on the diversion positions into the turning positions on the first diversion guide groove and the second diversion guide groove in sequence and alternately.

3. The radiator flow dividing and pairing device according to claim 2, wherein the first propelling cylinder group comprises a first longitudinal pushing cylinder arranged at one end of the first propelling section and a first transverse pushing cylinder arranged at one end of the first intersection section, the first longitudinal pushing cylinder pushes the radiator to the intersection of the first propelling section and the first intersection section, and the first transverse pushing cylinder pushes the radiator to the opposite overlapping position; the second propelling cylinder group comprises a second longitudinal pushing cylinder arranged at one end of the second propelling section and a second transverse pushing cylinder arranged at one end of the second intersection section, the second longitudinal pushing cylinder pushes the radiator to the intersection of the second propelling section and the second intersection section, and the second transverse pushing cylinder pushes the radiator to the opposite stacking position.

4. The heat sink shunting pair device of claim 2, wherein the turnover mechanism comprises a mounting substrate, a turnover block, and a turnover cylinder, the mounting substrate is fixed below the turnover bit, one end of the turnover block is rotatably connected to the mounting substrate, the other end of the turnover block is rotatably connected to one end of the turnover cylinder, and one end of the turnover cylinder, which is far away from the turnover block, is rotatably connected to the mounting substrate; the turnover block has a horizontal state and a turnover state under the driving of the turnover cylinder, and when the turnover block is in the horizontal state, the upper end surface of the turnover block is flush with the bottom surface of the turnover bit; the turnover mechanisms on the first diversion guide groove and the second diversion guide groove respectively turn over the radiator by 90 degrees, and the turnover direction of the turnover mechanism on the first diversion guide groove to the radiator is opposite to the turnover direction of the turnover mechanism on the second diversion guide groove to the radiator.

5. The heat sink split pairing device according to claim 2, wherein the first split cylinder is disposed in parallel with the first split section, and the second split cylinder is disposed in parallel with the second split section.

6. The heat sink flow distribution matching device according to claim 3, wherein the first push cylinder is disposed in parallel with the first push section, and the second push cylinder is disposed in parallel with the second push section.

7. A radiator splitting and mating apparatus according to claim 3, wherein said first thrust cylinder is disposed in parallel with said first merging section, and said second thrust cylinder is disposed in parallel with said second merging section.

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