CN112620031B

CN112620031B - Device is paintd to CPU radiator copper sheet heat-conducting medium

Info

Publication number: CN112620031B
Application number: CN202011447272.8A
Authority: CN
Inventors: 肖红平
Original assignee: Dongguan Jingsong Hardware Electronics Co ltd
Current assignee: Dongguan Jingsong Hardware Electronics Co ltd
Priority date: 2020-12-09
Filing date: 2020-12-09
Publication date: 2023-01-13
Anticipated expiration: 2040-12-09
Also published as: CN112620031A

Abstract

The invention relates to a smearing device, in particular to a smearing device for a copper sheet heat-conducting medium of a CPU radiator. The technical problem is as follows: the copper sheet heat-conducting medium smearing device for the CPU radiator can achieve automatic production, improve efficiency and reduce cost. The technical scheme of the invention is as follows: a copper sheet heat-conducting medium smearing device of a CPU radiator comprises a bottom plate and support columns, wherein three support columns are arranged on the bottom plate; the workbench is connected between the tops of the supporting columns; the rotary mechanism is arranged on the workbench; the feeding mechanism is arranged on one side of the workbench. Through the cooperation between moving mechanism, rotary mechanism, feeding mechanism and the feed mechanism, can realize pushing out CPU radiator copper sheet automatically, scribble heat-conducting medium along with it.

Description

Device is paintd to CPU radiator copper sheet heat-conducting medium

Technical Field

The invention relates to a smearing device, in particular to a smearing device for a copper sheet heat-conducting medium of a CPU radiator.

Background

At present, in the manufacturing process of the CPU radiator copper sheet, a heat-conducting medium needs to be coated on the surface of the CPU radiator copper sheet, so that the CPU radiator copper sheet can play a role, and after the heat-conducting medium is coated, the heat-conducting medium needs to be dried, so that the CPU radiator copper sheet and the heat-conducting medium are combined into a whole.

The existing method for smearing the heat-conducting medium on the CPU radiator copper sheet is to smear the heat-conducting medium manually, and the manual smearing has some problems: firstly, the coating is not uniform, and the quality of a copper sheet of a CPU radiator is influenced; secondly, the coating engineering amount is large, and the efficiency is low because the coating is carried out only manually; thirdly, the production cost of the factory is increased. Therefore, in order to solve the above problems, a heat conducting medium smearing device for a copper sheet of a CPU heat sink is now developed, which can realize automatic production, improve efficiency and reduce cost.

Disclosure of Invention

In order to overcome the defects of uneven painting, low efficiency and increased production cost of a factory in manual production, the technical problem is as follows: the copper sheet heat-conducting medium smearing device for the CPU radiator can achieve automatic production, improve efficiency and reduce cost.

The technical scheme of the invention is as follows: a smearing device for a heat conducting medium of a CPU radiator copper sheet comprises:

the device comprises a base plate and support columns, wherein three support columns are arranged on the base plate;

the workbench is connected between the tops of the supporting columns;

the rotary mechanism is arranged on the workbench;

the feeding mechanism is arranged on one side of the workbench.

Further, the rotary mechanism includes:

the two sides of the top of one side of the workbench are both connected with the first support frame;

the first rotating shaft is rotatably connected between one sides of the first supporting frames;

the first rotating shaft is provided with a roller.

Further, feed mechanism is including:

two second supporting frames are connected to two sides of the top of the workbench;

the feeding frame is connected between the second supporting frames;

the pressing block is connected with the feeding frame in a sliding mode.

Further, still including moving mechanism, moving mechanism includes:

the upper part of the feeding frame is connected with a first sliding rail;

the first sliding block is connected between two sides of the first sliding rail in a sliding manner and is connected with the pressing block in a sliding manner;

the first springs are arranged between the two sides of the first sliding block and the first sliding rail;

and the second springs are arranged between the two sides of the top of the first sliding block and the upper part of the pressing block.

Further, still including feeding mechanism, feeding mechanism is including:

the bottom of one side of the workbench is provided with a third support frame;

the third support frame is connected with the connecting rod in a sliding manner;

one side of the connecting rod is provided with a first wedge-shaped block;

the pushing block is arranged on one side of the connecting rod and is connected with the feeding frame in a sliding mode;

and a third spring is connected between one side of the first wedge block and the third support frame.

Further, still including reciprocating mechanism, reciprocating mechanism includes:

a fourth supporting frame is arranged on one side of the bottom plate;

the motor is arranged on the fourth supporting frame;

the two sides of the bottom plate are provided with fifth supporting frames;

the second rotating shaft is rotatably connected between the fifth supporting frames, and the right side of the second rotating shaft is connected with the output shaft of the motor;

the second rotating shaft is provided with a space cam;

the driving lever is arranged at the bottom of the first wedge-shaped block, and the space cam is connected with the driving lever in a sliding mode.

Further, still including clamping mechanism, clamping mechanism includes:

the two sides of the workbench are both connected with the clamps in a sliding manner;

the clamps are provided with second wedge blocks;

and a fourth spring is arranged between the two sides of the clamp and the workbench.

Further, still including unloading mechanism, unloading mechanism is including:

the blanking frame is arranged on one side of the top of the workbench;

one side of the lower part of the blanking frame is rotatably connected with a third rotating shaft;

the third rotating shaft is provided with a first gear;

a second slide rail is arranged on one side of the blanking frame;

the second sliding rail is connected with a second rack in a sliding way, and the second rack is meshed with the second gear;

a fifth spring is connected between one side of the first rack and the second slide rail;

the left side of the clamp at the front side is provided with a fourth wedge block;

and a third wedge block is arranged on one side of the first rack.

Further, still including the complementary unit, the complementary unit includes:

a sixth supporting frame is arranged on one side of the bottom plate;

the sixth supporting frame is rotatably connected with a fourth rotating shaft;

the bevel gear component is connected between the front side of the fourth rotating shaft and one side of the second rotating shaft;

and a transmission component is connected between one side of the fourth rotating shaft and the first rotating shaft.

The beneficial effects are that: 1. through the cooperation between moving mechanism, rotary mechanism, feeding mechanism and the feed mechanism, can realize pushing out CPU radiator copper sheet automatically, scribble heat-conducting medium along with it.

2. Through the cooperation among the reciprocating mechanism, the clamping mechanism and the blanking mechanism, the effect of automatically clamping the CPU radiator copper sheet and automatically blanking at intervals can be realized.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic perspective view of the rotating mechanism of the present invention.

Fig. 3 is a schematic perspective view of the feeding mechanism of the present invention.

Fig. 4 is a schematic perspective view of the moving mechanism of the present invention.

Fig. 5 is a schematic perspective view of the feeding mechanism of the present invention.

Fig. 6 is a schematic perspective view of the reciprocating mechanism of the present invention.

Fig. 7 is a schematic perspective view of the clamping mechanism of the present invention.

Fig. 8 is a schematic perspective view of the blanking mechanism of the present invention.

Fig. 9 is a schematic perspective view of the auxiliary mechanism of the present invention.

In the reference symbols: 1_ bottom plate, 2_ support column, 3_ workbench, 4_ rotating mechanism, 41_ first support frame, 42_ first rotating shaft, 43_ roller, 5_ feeding mechanism, 51_ second support frame, 52_ feeding frame, 53_ press block, 6_ moving mechanism, 61_ first slide rail, 62_ first slider, 63_ first spring, 64_ second spring, 7_ feeding mechanism, 71_ third support frame, 72_ connecting rod, 73_ push block, 74_ first wedge block, 75_ third spring, 8_ reciprocating mechanism, 81_ fourth support frame, 82_ motor, 83_ fifth support frame, 84_ second rotating shaft, 85_ space cam, 86_ shift lever, 9_ clamping mechanism, 91_ clamp, 92_ second wedge block, 93_ fourth spring, 10_ blanking mechanism, 101_ blanking frame, 102_ third rotating shaft, 103_ first gear, 104_ second gear, 105_ first rack, 106_ fifth spring, 107_ third wedge block, 108_ fourth wedge block, bevel gear assembly, 114_ bevel gear assembly, and sixth rotating shaft assembly.

Detailed Description

The invention is described in detail below with reference to the figures and the embodiments.

Example 1

A device is paintd to CPU radiator copper sheet heat-conducting medium, as shown in fig. 1-3, including bottom plate 1, support column 2, workstation 3, rotary mechanism 4 and feed mechanism 5, is equipped with three support column 2 on the bottom plate 1, is connected with workstation 3 between the support column 2 top, is equipped with rotary mechanism 4 on the workstation 3, and the right side of workstation 3 is equipped with feed mechanism 5.

The rotating mechanism 4 comprises a first support frame 41, a first rotating shaft 42 and a roller 43, the front side and the rear side of the top of the left side of the workbench 3 are both connected with the first support frame 41, the first rotating shaft 42 is rotatably connected between the left sides of the first support frames 41, and the roller 43 is arranged on the first rotating shaft 42.

Feed mechanism 5 is including second support frame 51, material loading frame 52 and briquetting 53, and both sides all are connected with two second support frames 51 around the top of workstation 3 right side, are connected with material loading frame 52 between the second support frame 51, and the sliding connection has briquetting 53 on material loading frame 52.

When people need to smear heat-conducting media on the CPU radiator copper sheet, the pressing block 53 is moved upwards and taken out, the CPU radiator copper sheet is placed in the loading frame 52, then the pressing block 53 is placed back, the CPU radiator copper sheet is extruded downwards, people can push the CPU radiator copper sheet leftwards, the heat-conducting media are smeared on the CPU radiator copper sheet, then the CPU radiator copper sheet is moved leftwards, and the heat-conducting media on the CPU radiator copper sheet are smeared evenly under the action of the roller 43.

Example 2

On the basis of embodiment 1, as shown in fig. 4 to 9, the device further includes a moving mechanism 6, the moving mechanism 6 includes a first slide rail 61, a first slide block 62, a first spring 63 and a second spring 64, the upper portion of the feeding frame 52 is connected with the first slide rail 61, the first slide block 62 is slidably connected between the front side and the rear side of the first slide rail 61, the first slide block 62 is slidably connected with the pressing block 53, the first spring 63 is disposed between the front side and the rear side of the right portion of the first slide block 62 and the first slide rail 61, and the second spring 64 is disposed between the left side and the right side of the top of the first slide block 62 and the upper portion of the pressing block 53.

When the CPU radiator copper sheets need to be placed, the pressing block 53 moves upwards firstly, so that the second spring 64 is stretched, then the pressing block 53 and the first sliding block 62 move rightwards, so that the first spring 63 is compressed, after the CPU radiator copper sheets are placed, the pressing block 53 and the first sliding block 62 are driven to move leftwards to reset under the action of the first spring 63, the pressing block 53 is driven to move downwards to reset under the action of the second spring 64, so that the pressing block 53 presses the CPU radiator copper sheets, and along with the reduction of the CPU radiator copper sheets, the pressing block 53 is driven to move downwards to reset under the action of the second spring 64.

The automatic feeding device is characterized by further comprising a feeding mechanism 7, wherein the feeding mechanism 7 comprises a third supporting frame 71, a connecting rod 72, a pushing block 73, a first wedge block 74 and a third spring 75, the third supporting frame 71 is arranged at the bottom of the right side of the workbench 3, the connecting rod 72 is connected onto the third supporting frame 71 in a sliding mode, the first wedge block 74 is arranged on the left side of the connecting rod 72, the pushing block 73 is arranged on the right side of the connecting rod 72, the pushing block 73 is connected with the feeding frame 52 in a sliding mode, and the third spring 75 is connected between the left side of the first wedge block 74 and the third supporting frame 71.

When pushing is needed, the connecting rod 72 is moved leftwards to drive the pushing block 73 and the first wedge-shaped block 74 to move leftwards, so that the third spring 75 is stretched, the pushing block 73 pushes the CPU radiator copper sheet leftwards, then the hand is loosened, and under the action of the third spring 75, the connecting rod 72, the pushing block 73 and the first wedge-shaped block 74 are driven to move rightwards to reset.

Still including reciprocating mechanism 8, reciprocating mechanism 8 is including fourth support frame 81, motor 82, fifth support frame 83, second pivot 84, space cam 85 and driving

lever

86, 1 right side of bottom plate is equipped with fourth support frame 81, be equipped with motor 82 on the fourth support frame 81, the bottom plate 1 left and right sides all is equipped with fifth support frame 83, the rotary type is connected with second pivot 84 between the fifth support frame 83, second pivot 84 right side and motor 82 output shaft, be equipped with space cam 85 on the second pivot 84, first wedge 74 bottom is equipped with driving lever 86, space cam 85 and driving lever 86 sliding type connection.

The motor 82 is started, the output shaft of the motor 82 rotates to drive the second rotating shaft 84 and the space cam 85 to rotate, the driving lever 86 is driven to move left and right, the pushing block 73 is driven to move left and right to push materials, and the motor 82 is turned off when the device is not used.

Still including clamping mechanism 9, clamping mechanism 9 is including anchor clamps 91, second wedge 92 and fourth spring 93, and the equal sliding connection in both sides has anchor clamps 91 around the left part of workstation 3, and anchor clamps 91 lower part all is equipped with second wedge 92, all is equipped with fourth spring 93 between the anchor clamps 91 left and right sides and the workstation 3.

The first wedge-shaped block 74 moves leftwards to drive the second wedge-shaped block 92 and the clamp 91 to move outwards, so that the fourth spring 93 is stretched, the first wedge-shaped block 74 moves rightwards, and under the action of the fourth spring 93, the second wedge-shaped block 92 and the clamp 91 are driven to move inwards to clamp the CPU radiator copper sheet.

Still including unloading mechanism 10, unloading mechanism 10 is including unloading frame 101, third pivot 102, first gear 103, second slide rail 104, first rack 105, fifth spring 106, third wedge 107 and

fourth wedge

108, 3 top left sides of workstation are equipped with unloading frame 101, unloading frame 101 lower part left side rotary type is connected with third pivot 102, be equipped with first gear 103 on the third pivot 102, unloading frame 101 left side is equipped with second slide rail 104, the gliding style of second slide rail 104 is connected with first rack 105, first rack 105 and the meshing of first gear 103, be connected with fifth spring 106 between first rack 105 front side and the second slide rail 104, the anchor clamps 91 left side of front side is equipped with fourth wedge 108, first rack 105 left side is equipped with third wedge 107.

When people need to paint a heat-conducting medium on a copper sheet of a CPU (Central processing Unit) radiator, the heat-conducting medium is poured onto the blanking frame 101, the clamp 91 on the front side moves backwards to drive the fourth wedge-shaped block 108 to move backwards and drive the third wedge-shaped block 107 and the first rack 105 to move backwards, so that the fifth spring 106 is stretched to drive the first gear 103 and the third rotating shaft 102 to rotate, the heat-conducting medium slides downwards to fall onto the copper sheet of the CPU radiator, and when the clamp 91 on the front side moves forwards to drive the fourth wedge-shaped block 108 to move forwards to reset, the third wedge-shaped block 107 and the first rack 105 are driven to move forwards to reset under the action of the fifth spring 106, the first gear 103 and the third rotating shaft 102 are driven to rotate reversely, so that the effect of interval blanking can be realized.

The auxiliary mechanism 11 is further included, the auxiliary mechanism 11 includes a sixth support frame 111, a fourth rotating shaft 112, a bevel gear component 113 and a transmission component 114, the sixth support frame 111 is arranged on the left rear side of the bottom plate 1, the sixth support frame 111 is connected with the fourth rotating shaft 112 in a rotating mode, the bevel gear component 113 is connected between the front side of the fourth rotating shaft 112 and the left side of the second rotating shaft 84, and the transmission component 114 is connected between the rear side of the fourth rotating shaft 112 and the first rotating shaft 42.

The second rotating shaft 84 rotates to drive the bevel gear assembly 113, the fourth rotating shaft 112, the transmission assembly 114 and the first rotating shaft 42 to rotate, and further drive the roller 43 to rotate to uniformly coat the CPU heat sink copper sheet.

The above description is only for the specific embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily think of the changes or substitutions within the technical scope of the present invention, and shall cover the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims

1. A device is paintd to CPU radiator copper sheet heat-conducting medium, its characterized in that, including:

the device comprises a bottom plate (1) and support columns (2), wherein the bottom plate (1) is provided with three support columns (2);

the workbench (3) is connected between the tops of the supporting columns (2);

the rotary mechanism (4) is arranged on the workbench (3);

the feeding mechanism (5) is arranged on one side of the workbench (3);

the rotating mechanism (4) comprises:

the two sides of the top of one side of the workbench (3) are connected with the first support frame (41);

a first rotating shaft (42) is rotatably connected between one sides of the first supporting frames (41);

a roller (43), wherein the roller (43) is arranged on the first rotating shaft (42);

still including feeding mechanism (7), feeding mechanism (7) including:

a third support frame (71), wherein the bottom of one side of the workbench (3) is provided with the third support frame (71);

the third support frame (71) is connected with the connecting rod (72) in a sliding manner;

the first wedge block (74) is arranged on one side of the connecting rod (72);

the pushing block (73) is arranged on one side of the connecting rod (72), and the pushing block (73) is connected with the feeding frame (52) in a sliding mode;

a third spring (75), wherein the third spring (75) is connected between one side of the first wedge block (74) and the third support frame (71);

still including reciprocating mechanism (8), reciprocating mechanism (8) including:

a fourth supporting frame (81), wherein the fourth supporting frame (81) is arranged on one side of the bottom plate (1);

the motor (82) is arranged on the fourth supporting frame (81);

the fifth supporting frames (83), and the fifth supporting frames (83) are arranged on the two sides of the bottom plate (1);

the second rotating shaft (84) is rotatably connected between the fifth supporting frames (83), and the right side of the second rotating shaft (84) is connected with an output shaft of the motor (82);

the space cam (85) is arranged on the second rotating shaft (84);

the shifting rod (86) is arranged at the bottom of the first wedge-shaped block (74), and the space cam (85) is connected with the shifting rod (86) in a sliding manner;

still including clamping mechanism (9), clamping mechanism (9) including:

the two sides of the workbench (3) are both connected with the clamps (91) in a sliding manner;

the clamps (91) are provided with second wedge-shaped blocks (92);

the fourth spring (93) is arranged between the two sides of the clamp (91) and the workbench (3);

still including unloading mechanism (10), unloading mechanism (10) including:

a blanking frame (101), wherein the blanking frame (101) is arranged on one side of the top of the workbench (3);

a third rotating shaft (102), wherein one side of the lower part of the blanking frame (101) is rotatably connected with the third rotating shaft (102);

the first gear (103) is arranged on the third rotating shaft (102);

a second sliding rail (104), wherein the second sliding rail (104) is arranged on one side of the blanking frame (101);

the first rack (105) is connected to the second sliding rail (104) in a sliding mode, and the first rack (105) is meshed with the first gear (103);

a fifth spring (106), wherein the fifth spring (106) is connected between one side of the first rack (105) and the second sliding rail (104);

a fourth wedge block (108), wherein the left side of the front clamp (91) is provided with the fourth wedge block (108);

a third wedge block (107), wherein the third wedge block (107) is arranged on one side of the first rack (105);

still including complementary unit (11), complementary unit (11) including:

a sixth supporting frame (111), wherein the sixth supporting frame (111) is arranged on one side of the bottom plate (1);

the sixth supporting frame (111) is rotatably connected with a fourth rotating shaft (112);

a bevel gear component (113), wherein the bevel gear component (113) is connected between the front side of the fourth rotating shaft (112) and one side of the second rotating shaft (84);

and a transmission assembly (114) is connected between one side of the fourth rotating shaft (112) and the first rotating shaft (42).

2. The smearing device for the heat-conducting medium of the copper sheet of the CPU radiator as claimed in claim 1, wherein the feeding mechanism (5) comprises:

two second supporting frames (51) are connected to two sides of the top of the workbench (3);

the feeding frame (52) is connected between the second supporting frames (51);

the pressing block (53) is connected on the feeding frame (52) in a sliding way.

3. The smearing device for the heat-conducting medium of the copper sheet of the CPU radiator as claimed in claim 2, further comprising a moving mechanism (6), wherein the moving mechanism (6) comprises:

the upper part of the feeding frame (52) is connected with the first sliding rail (61);

the first sliding block (62) is connected between two sides of the first sliding rail (61) in a sliding manner, and the first sliding block (62) is connected with the pressing block (53) in a sliding manner;

the first spring (63) is arranged between the two sides of the first sliding block (62) and the first sliding rail (61);

and the second springs (64) are arranged between the two sides of the top of the first sliding block (62) and the upper part of the pressing block (53).