CN220462882U - Automatic contact pin assembly and automatic contact pin device for radiating fin - Google Patents

Abstract

The utility model provides an automatic pin assembly and a radiating fin automatic pin device, wherein the radiating fin automatic pin device comprises the automatic pin assembly, the automatic pin assembly comprises a positioning block, a conveying assembly and a pin pushing assembly, the positioning block comprises a first positioning hole and a second positioning hole, the conveying assembly comprises a conveying block and a conveying driving assembly, a third positioning hole is arranged on the conveying block, the conveying driving assembly drives the conveying block to move, the first positioning hole and the second positioning hole are arranged in a collinear way along the moving direction of the conveying block, the pin pushing assembly comprises a push block and a push block moving driving device, the push block moving driving device drives the push block to move towards or away from the third positioning hole through the second positioning hole, the position after pin movement and the moving direction of the push block are limited through the arrangement of a plurality of positioning holes, and the position of the pin mounted on the radiating fin is improved to be more accurate.

Description

Automatic contact pin assembly and automatic contact pin device for radiating fin

Technical Field

The utility model relates to the field of part processing, in particular to an automatic pin assembly and an automatic pin device for a radiating fin.

Background

The radiating fin is used as an accessory part of an electronic product, the application field of the radiating fin is wider and wider, the requirements of the radiating fin are larger and larger along with the continuous increase of the electronic product, the required quantity of the product aimed by the utility model can reach hundreds of millions each year, the quantity of the product is in an increasing trend each year, and people mostly adopt a manual mode to realize the assembly of the radiating fin, so that the radiating fin occupies a large amount of labor force and has very low efficiency, and therefore, an automatic assembly machine is urgently demanded in the market. The patent number is: CN10121055517.8, the chinese patent for pin fin assembly machine, discloses a pin process for automatically completing fin, which implements rapid tooling of pin and fin, and effectively improves working efficiency; however, in this technical solution, it is disclosed that the first pin vibration disc 8 and the second pin vibration disc 9 send pins into the holes of the first pin centering block 33 and the second pin centering block 32 respectively, the first dc motor 23 and the second dc motor 26 drive the first pin centering block 33 and the second pin centering block 32 to rotate 90 degrees, the first small cylinder 20 and the second small cylinder 28 extend out, and insert the pins into the second heat sink 25, and this structure makes the pins driven by the small cylinders to insert into the heat sink after the pin centering block rotates, i.e. the pins are not further positioned after the pins rotate, i.e. the pins are driven to insert into the heat sink, so that the pin insertion position is incorrect, and a high reject ratio is easily generated.

Disclosure of Invention

It is a first object of the present utility model to provide an automatic pin assembly that improves pin insertion accuracy.

A second object of the present utility model is to provide a heat sink automatic pin apparatus including the automatic pin assembly described above.

In order to achieve the first object, the automatic pin assembly provided by the utility model comprises a positioning block, a conveying assembly and a pin pushing assembly, wherein the positioning block comprises a first positioning hole and a second positioning hole, the conveying assembly comprises a conveying block and a conveying driving assembly, a third positioning hole is formed in the conveying block, the conveying driving assembly drives the conveying block to move, the first positioning hole and the second positioning hole are arranged in a collinear way along the moving direction of the conveying block, the pin pushing assembly comprises a pushing block and a pushing block moving driving device, and the pushing block moving driving device drives the pushing block to move towards or away from the third positioning hole through the second positioning hole.

According to the technical scheme, when the contact pin is fed into the first positioning hole of the positioning block, the first positioning hole and the third positioning hole on the conveying block are arranged in a collinear manner, so that the contact pin passes through the first positioning hole and enters the third positioning hole, the conveying driving assembly drives the conveying block to move towards the cooling fin, after the movement is stopped, the third positioning hole of the conveying block and the second positioning hole of the positioning block are arranged in a collinear manner, the pushing block moving driving device drives the pushing block to penetrate through the second positioning hole to push the contact pin positioned in the third positioning hole into the cooling fin, the installation of the contact pin on the cooling fin is completed, in the process, the movement of the conveying block drives the contact pin to change in position, and when the pushing block pushes the contact pin to be installed on the cooling fin, the movement direction of the pushing block is further limited under the premise that the third positioning hole and the second positioning hole are arranged in a collinear manner, the pushing block can accurately pass through the second positioning hole and then more accurately push the contact pin positioned in the third positioning hole into the cooling fin, and the movement direction of the contact pin in the cooling fin is more accurately limited by the arrangement of the plurality of positioning holes.

Further scheme is, the conveying assembly includes installation piece and briquetting, and conveying piece and briquetting set up respectively on the installation piece, and conveying assembly drive installation piece removes, and conveying piece sets up between briquetting and push pin subassembly.

It can be seen that transport piece and briquetting are installed simultaneously on the installation piece, and when transport subassembly drive a Zhuang Kuai removed, transport piece and briquetting simultaneously, the position between adjustment transport piece and the briquetting, when the third locating hole and the second locating hole intercommunication of transport piece, on the fin of briquetting compress tightly waiting to connect the contact pin, the steadiness of fin when installing the contact pin is improved.

Further, the pressing block is provided with a bending part, and the pressing end of the pressing block extends from the bending part.

Therefore, the shape of the pressing block is a pressing end formed after a part of the pressing block continuously extends after bending, and the shape can be matched with the layout of components in the device, so that the occupied space of the pressing block is reduced.

The length of the pushing block is larger than that of the second positioning hole.

Therefore, in the process of pushing the pins by the push block, the push block needs to be ensured to push the pins in the third positioning holes to the cooling fins after penetrating through the second positioning holes, and the pins installed behind the cooling fins cannot be partially remained in the third positioning holes, so that the cooling fins which are installed are ensured to continuously move for discharging.

The push block comprises a limiting block and a push pin, wherein the limiting block is arranged between the push pin and the push block moving driving device, and the width of the limiting block is larger than that of the push pin along the radial direction of the push pin.

Therefore, the advancing length of the push block is controlled by the driving length of the push block moving driving device and the length of the limiting block in cooperation, so that the contact pin in the third positioning hole is pushed out better.

Further scheme is, automatic contact pin subassembly includes contact pin material loading subassembly, and the material loading subassembly includes loading attachment and receiving block, and loading attachment includes the track, and the receiving block sets up on the locating piece deviates from the lateral wall of carrying the piece, is provided with the fourth locating hole on the receiving block, and orbital discharge gate is connected with the fourth locating hole.

Therefore, the contact pins sequentially enter the fourth positioning hole, the first positioning hole and the third positioning hole along the track, and the contact pins finally reaching the third positioning hole are guaranteed to be accurate in position.

In order to achieve the second objective, the present utility model provides an automatic pin device for a heat sink, which comprises a heat sink feeding component, an automatic pin component, a rail conveying component and a defective product blanking component, wherein the automatic pin component is the automatic pin component.

Therefore, the radiating fin feeding assembly in the radiating fin automatic pin inserting device realizes the feeding and mounting of the radiating fins, the automatic pin inserting assembly realizes the feeding and mounting of the pins, the rail conveying assembly realizes the conveying of the radiating fins, and the defective product discharging assembly realizes the discharging of defective product radiating fins for completing the pin mounting, so that the full-automatic assembly of the pins on the radiating fins is realized, and the working efficiency is effectively improved.

The radiating fin feeding assembly comprises a first conveying rail, the rail conveying assembly comprises a second conveying rail, the conveying direction of the first conveying rail and the conveying direction of the second conveying rail are arranged in a crossing mode, a feeding pushing block and a feeding driving device are arranged on the second conveying rail, and the feeding driving device drives the feeding pushing block to move along the conveying direction of the second conveying rail; the conveying assembly drives the conveying block to move towards or away from the second conveying track, and the moving direction of the pushing block is parallel to the conveying direction of the first conveying track.

Therefore, the first conveying track is used for realizing the feeding of the radiating fins, the second conveying track is used for realizing the conveying of the radiating fins with the completed position adjusted to the mounting positions of the pins, and the conveying directions of the first conveying track and the second conveying track are arranged in a crossed manner, so that the occupied space of the two conveying tracks can be reduced, and the layout of the device is more compact.

The further scheme is, fin material loading subassembly includes rotating base, lifts subassembly and pushing component, lifts the subassembly and includes to lift the piece and lift drive arrangement, lifts the piece setting and lifts between rotating base and first conveying track, lifts drive arrangement and drives to lift the piece and remove, rotating base rotates, pushing component includes pushing block and pushing drive arrangement, pushing drive arrangement drive pushing block is through rotating base towards first conveying track removal.

Therefore, when the radiating fin is fed and moved to the rotating base, the rotating base rotates to drive the radiating fin to rotate, and after the position of the radiating fin is detected to be correct, the lifting block drives the radiating fin to move upwards, and the pushing block pushes the radiating fin to the first conveying track, so that the feeding of the radiating fin is completed.

The further scheme is that defective product unloading subassembly includes unloading piece and unloading drive arrangement, and unloading drive arrangement drives unloading piece and removes towards track conveying assembly.

Therefore, after the cooling fin is assembled by the pin, the blanking driving device drives the blanking block to move towards the track conveying assembly, so that the cooling fin on the track conveying assembly is pushed away, and blanking of the cooling fin is completed.

Drawings

FIG. 1 is a block diagram of an embodiment of an automatic pin fin apparatus of the present utility model.

Fig. 2 is a block diagram of a fin feeding assembly in an embodiment of an automatic fin pin apparatus of the present utility model.

Fig. 3 is a block diagram of an automatic pin assembly in an embodiment of a heat sink automatic pin apparatus of the present utility model.

Fig. 4 is a schematic diagram illustrating the cooperation among the receiving block, the positioning block and the conveying block in the embodiment of the automatic pin inserting device for the heat sink according to the present utility model.

Fig. 5 is a block diagram of an automatic pin assembly with a positioning block removed in an embodiment of a heat sink automatic pin apparatus according to the present utility model.

Fig. 6 is a block diagram of a push pin assembly in an embodiment of the automatic heat sink pin apparatus of the present utility model.

The utility model is further described below with reference to the drawings and examples.

Detailed Description

The automatic pin assembly is applied to a process for inserting a pin on a component, wherein the component can be a component such as a radiating fin and the like which needs pins. The automatic pin assembly is positioned before and after the movement of the conveying block, so that the position of the pin after the movement and the movement direction of the pushing block are limited, and the position of the pin mounted on the radiating fin is improved to be more accurate.

Referring to fig. 1, the utility model provides an automatic pin inserting device for radiating fins, which comprises a radiating fin feeding assembly 1, an automatic pin inserting assembly 2, a rail conveying assembly 3 and a defective product discharging assembly 4, wherein the radiating fin feeding assembly 1 in the automatic pin inserting device for radiating fins is used for feeding radiating fins, the automatic pin inserting assembly 2 is used for feeding and installing pins, the rail conveying assembly 3 is used for conveying the radiating fins, and the defective product discharging assembly 4 is used for discharging defective product radiating fins for completing pin installation, so that full-automatic assembly of the radiating pins on the radiating fins is realized, and the working efficiency is effectively improved.

Referring to fig. 2, the fin feeding assembly 1 includes a feeding device 11, a rotating assembly 12, a lifting assembly 5, a pushing assembly 13 and a first conveying track 14, and in this embodiment, the feeding device 11 is a vibration feeding device, and the fins are vibrated by vibration to realize movement of the fins. The rotating assembly 12 comprises a rotating base 121 and a rotating motor 122, the rotating base 121 is connected to the outlet of the vibration feeding device, the rotating base 121 is connected with the rotating motor 122 through a connecting rod 123, and the rotating motor 122 drives the rotating base 121 to rotate through the connecting rod 123. In this embodiment, the rotating base 121 is used for placing the heat sink of the pin to be inserted, the rotating base 121 is located above the rotating motor 122, two notches 124 are provided on the top surface of the rotating base 121, the two notches 124 are oppositely arranged, and the two notches 124 are used for matching with the shape of the heat sink, so that the heat sink can be more firmly arranged on the rotating base 121.

The lifting assembly 5 comprises a first mounting block 51, a second mounting block 52, a pressing block 53, a lifting block 54 and a lifting driving device 55, wherein the second mounting block 52 and the pressing block 53 are respectively arranged on the first mounting block 51, the pressing block 53 is positioned above the rotating base 121, the second mounting block 52 is used for mounting the lifting block 54, a through hole 531 is formed in the second mounting block 53, a connecting rod 123 penetrates through the through hole 531, the second mounting block 52 is positioned below the rotating base 121, and the lifting block 54 mounted on the second mounting block 52 is also positioned below the rotating base 121; when the lift driving device 55 drives the first mounting block 51 to move, the pressing block 53 and the second mounting block 52 move simultaneously, the lift block 54 moves away from the rotating base 121 while the pressing block 53 moves towards the rotating base 121, so that the pressing block 53 presses the cooling fins on the rotating base 121 while the lift block 54 moves away from the rotating base 121, and when the pressing block 53 moves away from the rotating base 121 to release the cooling fins on the rotating base 121, the lift block 54 moves towards the rotating base 121 to lift the cooling fins on the rotating base 121. In the present embodiment, the lifting block 54 is disposed between the swivel base 121 and the first conveying rail 14.

The pushing assembly 13 includes a pushing block 131 and a pushing driving device 132, and the pushing driving device 132 drives the pushing block 131 to move toward the conveying direction of the first conveying track 14 via the rotating base 121. When the lifting block 54 lifts the heat sink on the rotating base 121, the pushing driving device 132 drives the pushing block 131 to move, so as to drive the heat sink to move onto the first conveying track 14. The first conveying track 14 is used for conveying the heat sink which completes rotation, and the first conveying track 14 can adopt a driving mode of driving the articles in the track to move in the prior art, for example, a vibrator drives the first conveying track to vibrate so as to enable the articles to move, or a driving belt or the like is arranged in the track.

When the heat sink is fed and moved to the rotating base 121, the rotating base 121 rotates to drive the heat sink to rotate, the position of the heat sink is adjusted by utilizing the difference of the length and the width of the heat sink, and the detector is used for detecting whether the position of the heat sink is correct or not, so that the welding needle can be accurately inserted into the fixed position of the heat sink. After the detection is finished, the lifting block 54 drives the cooling fin to move upwards, and meanwhile the pushing block 131 pushes the cooling fin to the first conveying track 14, so that the feeding of the cooling fin is finished.

Referring to fig. 3, the rail transport assembly 3 includes a second transport rail 31, a feed pusher 32, and a feed drive 33, the feed drive 33 driving the feed pusher 32 to move in the transport direction of the second transport rail. The conveying direction of the first conveying track 14 is perpendicular to the conveying direction of the second conveying track 31, the cooling fins in the first conveying track 14 move into the second conveying track 31, and the feeding driving device 33 drives the feeding pushing block 32 to move so as to push the cooling fins on the second conveying track 31 to the contact pins more quickly. The second conveying track 31 drives the cooling fin to move, so that the cooling fin can conveniently complete the pin inserting and blanking process.

The automatic pin assembly 2 comprises a pin feeding assembly 21, a positioning block 22, a conveying assembly 23 and a push pin assembly 24, wherein the feeding assembly 21 comprises a feeding device 211 and a receiving block 212, in the embodiment, the feeding device 211 is a vibration feeding device, pins are placed in the vibration feeding device 211, the feeding device 211 comprises a track, the pins are driven to move along the track through vibration, and the track of the feeding device is connected with the receiving block 212, as shown in fig. 4. The receiving block 212 is arranged on the side wall of the positioning block, which is away from the conveying block, a fourth positioning hole 213 is arranged on the receiving block 212, a discharge hole of the track is connected with and communicated with the fourth positioning hole 213, and welding needles in the track enter the fourth positioning hole 213 of the receiving block 212 through vibration.

The positioning block 22 includes a first positioning hole 221 and a second positioning hole 222, and in the present embodiment, the first positioning hole 221 and the second positioning hole 222 are disposed in line in the vertical direction. The first positioning hole 221 and the fourth positioning hole 213 are disposed in line and communicate in the horizontal direction.

Referring to fig. 5, the transport assembly 23 includes a mounting block 231, a transport block 232, a transport driving assembly 234, and a pressing block 233, and the transport block 232 and the pressing block 233 are respectively disposed on the mounting block 231. The third positioning hole 235 is provided on the conveying block 232, and the conveying driving assembly 234 drives the mounting block 231 to move, so that the conveying block 232 and the pressing block 233 move toward or away from the second conveying track 31 at the same time, and in this embodiment, the mounting block 231 moves in the vertical direction, and the first positioning hole 221 and the second positioning hole 222 are arranged in a collinear manner along the moving direction of the mounting block 231. When the conveying block 232 is not moved toward the second conveying rail 31, the first positioning hole 221 on the positioning block 22 is arranged in line with and communicates with the third positioning hole 235 on the conveying block 232, so that the pin positioned in the first positioning hole 221 enters into the third positioning hole 235. After the conveying driving assembly 234 drives the conveying block 232 to stop moving toward the second conveying track 31, the third positioning hole 235 on the conveying block 232 and the third positioning hole 235 on the positioning block 22 are arranged in line and communicated. In this embodiment, the sidewall of the positioning block 22 facing the conveying block 232 is provided with a positioning step 223, the conveying block 232 is located above the positioning step 223, the positioning step 223 is used to limit the moving distance of the conveying block 232, so as to avoid the situation that the moving distance of the conveying block 232 is too long, and the second positioning hole 222 and the third positioning hole 235 cannot be communicated.

Since the pressing block 233 is provided on the mounting block 231 simultaneously with the conveying block 232, when the conveying block 232 moves toward the second conveying rail 31, the pressing block 233 also moves toward the second conveying rail 31, and the downward movement of the pressing block 233 serves to press the heat sink on the second conveying rail 31. When the conveying block 232 moves towards the second conveying track 31, it represents the pin inserting process of the heat sink to be performed, and at the same time, the pressing block 233 moves downward to compress the heat sink to be performed with pins on the second conveying track 31, so as to improve the stability of the heat sink in the pin inserting process. The conveying block 232 and the pressing block 233 are respectively arranged on the mounting block 231, and the conveying driving assembly drives the mounting block 231 or the conveying block 232 to move, so that the conveying block 232 and the pressing block 233 move simultaneously, and the conveying block 232 is arranged between the pressing block 233 and the push pin assembly 24. In the present embodiment, the pressing block 233 is provided with a bent portion 236, and a pressing end 237 of the pressing block 233 extends from the bent portion 236 such that the pressing block 233 is in an inverted "7" row. The shape of the pressing block 233 is that a part of the pressing block 233 continuously extends after being bent to form a pressing end 237, and the shape can be matched with the layout of components in the device, so that the space occupied by the pressing block 233 is reduced, and meanwhile, the shape of the cooling fin is adapted to the shape of the cooling fin, and the cooling fin is pressed more tightly. In the present embodiment, the transport driving assembly 234 includes a driving cylinder 2341 and a moving rail 2342, and the driving cylinder 2341 drives the transport block 232 to move in the extending direction of the moving rail 2342.

Referring to fig. 6, the push pin assembly 24 includes a push block 241 and a push block driving device 242, the push block driving device 242 driving the push block 241 to move along the extending direction of the first conveying track 14, the push block driving device 242 driving the push block 241 to push the pins in the third positioning holes 235 into the heat sink. In this embodiment, the pushing block 241 includes a limiting block 243 and a pushing pin 244, the limiting block 243 is disposed between the pushing pin 244 and the pushing block moving driver 242, and the width of the limiting block 243 is greater than the width of the pushing pin 244 along the radial direction of the pushing pin 244. The length of the push pin 244 is greater than the length of the second positioning hole 222 from the limiting block 243 toward the side wall of the push pin 244, so that the push pin 244 in the third positioning hole 235 can be pushed out completely from the third positioning hole 235 after the push pin 244 can penetrate through the second positioning hole 222.

When the contact pin is fed into the first positioning hole 221 of the positioning block 22, the first positioning hole 221 and the third positioning hole 235 on the conveying block 232 are arranged in a collinear manner, so that the contact pin passes through the first positioning hole 221 and enters the third positioning hole 235, the conveying driving component 234 drives the conveying block 232 to move towards the cooling fin, after the movement is stopped, the third positioning hole 23522 of the conveying block 232 and the second positioning hole 222 of the positioning block 22 are arranged in a collinear manner, the pushing block movement driving device 242 drives the pushing block 241 to penetrate through the second positioning hole 222 to push the contact pin positioned in the third positioning hole 235 into the cooling fin, the installation of the contact pin on the cooling fin is completed, in the process, the movement of the conveying block 232 drives the contact pin to change in position, and when the pushing block 241 pushes the contact pin to be installed on the cooling fin, the movement direction of the pushing block 241 is further limited on the premise that the third positioning hole 235 is arranged in a collinear manner, the movement direction of the pushing block 241 can accurately pass through the second positioning hole 222, and the contact pin can be more accurately positioned in the direction of the cooling fin after the pushing block 241 is more accurately moved through the second positioning hole 222, and the installation position of the contact pin is more accurately limited. In this embodiment, the conveying block 232 is provided with a detection avoidance step 238 on a side wall deviating from the positioning block 22, and the detection avoidance step 238 is communicated with the third positioning hole 235, so that the length of the third positioning hole 235 is smaller than the thickness of the conveying block 232, and the detector performs the pushing needle action after detecting whether the third positioning hole 235 has a contact needle or not by detecting the avoidance step.

The defective product blanking assembly 4 comprises a blanking block 41 and a blanking driving device 42, and the blanking driving device 42 drives the blanking block 41 to move towards the track conveying assembly 3. After the pin assembly is completed, the radiating fin moves to the defective product blanking component 4, the blanking driving device 42 drives the blanking block 41 to move towards the track conveying component 3, and the defective radiating fin on the track conveying component 3 is pushed away, so that the blanking of the radiating fin is completed. The cooling fin as a qualified product continues to move, slides into the blanking slide 6 at the end point of the second conveying track 31, and slides down into the collecting box.

Finally, it should be emphasized that the foregoing description is merely illustrative of the preferred embodiments of the utility model, and that various changes and modifications can be made by those skilled in the art without departing from the spirit and principles of the utility model, and any such modifications, equivalents, improvements, etc. are intended to be included within the scope of the utility model.

Claims (10)

1. Automatic contact pin subassembly, its characterized in that: including locating piece, conveying component and push pin assembly, the locating piece includes first locating hole and second locating hole, conveying component is including carrying the piece and carrying drive assembly, be provided with the third locating hole on the piece that carries, carry drive assembly drive carry the piece to remove, first locating hole with the second locating hole is followed carry the direction collineation setting of piece, the push pin assembly includes ejector pad and ejector pad removal drive arrangement, ejector pad removal drive arrangement drive the ejector pad passes the second locating hole orientation or keep away from the third locating hole removes.

2. The automatic pin assembly of claim 1, wherein:

the conveying assembly comprises a mounting block and a pressing block, the conveying block and the pressing block are respectively arranged on the mounting block, the conveying assembly drives the mounting block to move, and the conveying block is arranged between the pressing block and the push pin assembly.

3. The automatic pin assembly of claim 2, wherein:

the pressing block is provided with a bending part, and the pressing end of the pressing block extends from the bending part.

4. The automatic pin assembly of claim 1, wherein:

the length of the pushing block is greater than that of the second positioning hole.

5. The automatic pin assembly of claim 4, wherein:

the push block comprises a limiting block and a push pin, the limiting block is arranged between the push pin and the push block moving driving device, and the width of the limiting block is larger than that of the push pin along the radial direction of the push pin.

6. The automatic pin assembly of any one of claims 1 to 5, wherein:

the automatic contact pin assembly comprises a contact pin feeding assembly, the feeding assembly comprises a feeding device and a receiving block, the feeding device comprises a track, the receiving block is arranged on the side wall of the positioning block, which is away from the conveying block, a fourth positioning hole is formed in the receiving block, and a discharge hole of the track is connected with the fourth positioning hole.

7. Automatic pin device of fin, its characterized in that: the automatic pin assembly comprises a radiating fin feeding assembly, an automatic pin assembly, a rail conveying assembly and a defective product blanking assembly, wherein the automatic pin assembly is the automatic pin assembly according to any one of claims 1 to 6.

8. The automatic pin fin inserting apparatus according to claim 7, wherein:

the cooling fin feeding assembly comprises a first conveying rail, the rail conveying assembly comprises a second conveying rail, the conveying direction of the first conveying rail and the conveying direction of the second conveying rail are arranged in a crossing mode, a feeding pushing block and a feeding driving device are arranged on the second conveying rail, and the feeding driving device drives the feeding pushing block to move along the conveying direction of the second conveying rail;

the conveying assembly drives the conveying block to move towards or away from the second conveying track, and the moving direction of the pushing block is parallel to the conveying direction of the first conveying track.

9. The automatic pin fin inserting apparatus according to claim 8, wherein:

the radiating fin feeding assembly comprises a rotating base, a lifting assembly and a pushing assembly, the lifting assembly comprises a lifting block and a lifting driving device, the lifting block is arranged between the rotating base and the first conveying track, the lifting driving device drives the lifting block to move, the rotating base rotates, the pushing assembly comprises a pushing block and a pushing driving device, and the pushing driving device drives the pushing block to move towards the first conveying track through the rotating base.

10. The automatic pin fin setting device according to any one of claims 7 to 9, wherein:

the defective product blanking assembly comprises a blanking block and a blanking driving device, and the blanking driving device drives the blanking block to move towards the track conveying assembly.