CN218941651U - Novel solid-state radiator - Google Patents

Abstract

The utility model relates to a novel solid-state radiator, which comprises radiating fins for radiating a solid-state relay, radiating pieces for guiding heat of the radiating fins and clamping seats for installing the radiating pieces on guide rails; one end of the radiating fin is arranged on the radiating piece, and the other end of the radiating fin is arranged on the solid-state relay; the clamping seat is arranged at one end of the heat dissipation piece, which is far away from the solid state relay. The heat dissipation device solves the problems that heat cannot be rapidly dissipated and cannot be guided in the prior art, the heat can be left in the cavity for a long time, and meanwhile, the clamping seat structure clamping the radiator on the guide rail cannot be adapted to guide rails with different widths.

Description

Novel solid-state radiator

Technical Field

The present disclosure relates to heat sinks, and particularly to a solid state heat sink.

Background

The radiator belongs to a part of a solid state relay cooling system, and the structure of the radiator is usually a radiator body and a radiator clamping seat, and the radiator is directly brought into the radiator by high temperature generated during the working of the solid state relay and dissipates heat based on a heat conduction mode. Meanwhile, the radiator is usually arranged inside the power distribution cabinet, and the radiator in the arrangement mode has the effects of high radiating speed in unit space and convenience in disassembly and assembly.

At present, the existing radiator with the same volume generally adopts a hollow mode to radiate heat and a vertical bar grating to radiate heat, no matter which mode is adopted to radiate heat, the heat of the solid state relay is required to be reduced as much as possible, and the purposes of reducing the cost and prolonging the service life are achieved. The heat generated by the solid state relay during working enters the radiator, and the heat can be left in the inner cavity for a long time under the condition of no flow guide, however, the heat dissipation mode increases the local heat of the solid state relay, which is contrary to the purposes of reducing the cost and prolonging the service life. In the prior art, heat cannot be rapidly emitted and cannot be guided, so that the heat can be left in the cavity for a long time, and meanwhile, the clamping seat structure clamping the radiator on the guide rail cannot be adapted to the guide rails with different widths.

Disclosure of Invention

The embodiment of the application solves the problems that heat cannot be rapidly emitted and cannot be guided in the prior art, heat can be left in a cavity for a long time, and meanwhile, the clamping seat structure which clamps the heat radiator on the guide rail cannot be adapted to the guide rail with different widths.

The technical scheme adopted by the embodiment of the application is as follows.

A novel solid-state radiator comprises radiating fins for radiating a solid-state relay, radiating pieces for guiding heat of the radiating fins and clamping seats for installing the radiating pieces on guide rails; one end of the radiating fin is arranged on the radiating piece, and the other end of the radiating fin is arranged on the solid-state relay; the clamping seat is arranged at one end of the heat dissipation piece, which is far away from the solid state relay.

The further technical scheme is as follows: the heat dissipation piece comprises a heat conduction sheet arranged on the heat dissipation sheet and heat dissipation tooth sheets for dissipating heat of the heat conduction sheet; the heat dissipation tooth sheets are arranged along the heat conduction sheets; the radiating tooth plates are obliquely arranged.

The further technical scheme is as follows: the radiating tooth piece is also provided with saw teeth; the saw teeth are arranged along the radiating tooth sheets.

The further technical scheme is as follows: the clamping seat comprises a first clamping piece and a second clamping piece which is connected to the first clamping piece in a sliding manner; the first clamping piece is arranged on the heat conducting fin; a first elastic piece is arranged between the first clamping piece and the second clamping piece; the first elastic piece pulls the second clamping piece to the first clamping piece.

The further technical scheme is as follows: the first clamping piece and the second clamping piece are provided with clamping grooves; when the clamping seat is clamped into the guide rail, the clamping groove is clamped into the guide rail.

The further technical scheme is as follows: the clamping seat comprises a fixed block arranged on the heat conducting fin, a gear rotationally connected in the fixed block, a clamping piece slidingly connected in the fixed block and a driving device for driving the gear to rotate; the clamping pieces are oppositely arranged; the gear is meshed with the clamping piece; the gear is meshed with the driving device; when the driving device drives the gear to rotate, the gear drives the clamping piece to be far away from or close to the guide rail.

The further technical scheme is as follows: the clamping piece comprises a first rack and a clamping block, wherein the first rack is connected in the fixed block in a sliding way, and the clamping block clamps the guide rail; a wedge block is arranged on the first rack; the fixed block is provided with a wedge-shaped groove which is connected with the wedge-shaped block in a sliding way; the wedge-shaped grooves are oppositely arranged; the clamping block is fixedly connected to one end of the first rack.

The further technical scheme is as follows: a compression block is arranged on the clamping block, and a fourth elastic piece is connected between the compression block and the clamping block; the fourth elastic piece compresses the compression block in the direction of the guide rail; and the compressing block is provided with a chamfer, and the chamfer is arranged on the end face facing the fixed block.

The further technical scheme is as follows: the driving device comprises a second rack and a second elastic piece for tensioning the second rack; the second rack is connected in the fixed block in a sliding way, and is meshed with the gear; the second elastic piece is arranged between the second rack and the fixed block.

The further technical scheme is as follows: the fixed block is provided with a locking component; the locking assembly comprises a support plate, a clamping block for clamping the second rack, a guide rod for guiding the clamping block and a third elastic piece for moving the clamping block; a clamping groove corresponding to the clamping block is formed in the second rack; the clamping block is clamped into the clamping groove; the third elastic piece is sleeved on the guide rod; the guide rod penetrates through the support plate; one end of the third elastic piece abuts against the support plate, and the other end of the third elastic piece abuts against the clamping block.

One or more technical solutions provided in the embodiments of the present application at least have the following technical effects or advantages:

1. because the radiating fins are attached to the solid-state relay, heat on the solid-state relay is guided to the radiating piece, the heat on the radiating piece is rapidly dissipated, and further, the heat is rapidly dissipated and conducted layer by layer, and the radiating efficiency is high.

2. Because the heat conducting fin is arranged on the heat radiating piece to quickly guide heat to the heat conducting fin, the heat is uniformly transferred to the heat radiating tooth fin, the heat radiating area is enlarged, and the good heat radiating effect and quick guide are realized.

3. Due to the fact that the saw teeth are arranged on the radiating tooth plates, radiating area is increased, and therefore good radiating effect and rapid flow guiding are achieved.

4. Because the second clamping piece is slidably connected to the first clamping piece, the second clamping piece is always pulled to the first clamping piece through the elastic piece, the guide rail is clamped between the first clamping piece and the second clamping piece through the elastic piece, and therefore the clamping seat is clamped on the guide rail.

5. Because the first clamping piece and the second clamping piece are adopted, the clamping groove is formed in the clamping piece, and corresponds to the guide rail, so that the clamping seat is more stable when clamped on the guide rail.

6. When the driving device is adopted to drive the gear to rotate, the clamping blocks at two sides of the fixed block are driven to move away from or approach the guide rail, so that the clamping seat is clamped on the guide rail.

7. Due to the fact that the wedge-shaped block is arranged on the first rack, the wedge-shaped groove is formed in the fixing block, the first rack is fixedly connected with the clamping block, the first rack slides in the fixing block, and therefore stable transmission of the first rack in the fixing block is achieved when gear transmission is achieved.

8. Because the clamping block is provided with the compression block, the compression block is provided with the chamfer, the fourth elastic piece is arranged between the compression block and the clamping block, when the clamping block moves towards the guide rail until the guide rail is clamped, the chamfer on the compression block contacts the guide rail and moves downwards until the upper end face of the compression block compresses the lower end face of the guide rail, and further the clamping seat is more stable when clamped on the guide rail.

9. Because the second rack is meshed with the gear, the second elastic piece pulls the second rack towards one direction all the time, so that the clamping blocks at the two ends of the fixed block move towards the direction of the guide rail until the guide rail is clamped, and further, the clamping blocks at the two ends of the second elastic piece are automatically clamped on the guide rail, and the clamping seat is more stable when clamped on the guide rail.

10. Because adopted the chucking piece to block the position of second rack, the guide bar is directed the displacement of chucking piece, and the third elastic component is with chucking piece removal towards the second rack all the time, until chucking piece card goes into the draw-in groove, and then realized when not using the cassette, the position adjustment to the highest department with the second rack, through the position restriction of chucking piece with the second rack, thereby more convenient use cassette, shift out the draw-in groove with the chucking piece when needing to press from both sides tightly, the fixture block at both ends removes to the guide rail direction, until clamping rail.

Drawings

Fig. 1 is a schematic structural diagram of a novel solid state heat sink according to a first embodiment of the present utility model.

Fig. 2 is a schematic diagram of a turnover structure of a novel solid state heat sink according to a first embodiment of the present utility model.

Fig. 3 is a schematic diagram of a card holder according to a second embodiment of the utility model.

Fig. 4 is a schematic partial cutaway view of a cartridge according to a second embodiment of the present utility model.

Fig. 5 is a partial enlarged view of a in fig. 3.

In the figure: 1. a heat sink; 2. a heat sink; 21. a heat conductive sheet; 22. radiating tooth sheets; 221. saw teeth; 3. a clamping seat; 31. a first clamping piece; 32. a second clamping piece; 33. a first elastic member; 34. a buckle groove; 35. a fixed block; 351. wedge-shaped grooves; 352. a support plate; 353. a clamping block; 354. a guide rod; 355. a third elastic member; 36. a gear; 37. a clamping member; 371. a first rack; 372. a clamping block; 373. wedge blocks; 374. a compaction block; 375. a fourth elastic member; 376. chamfering; 38. a driving device; 381. a second rack; 382. a second elastic member; 383. a clamping groove; 39. and a locking assembly.

Detailed Description

The embodiment of the application solves the problems that heat cannot be rapidly emitted and cannot be guided in the prior art, heat can be left in a cavity for a long time, and meanwhile, the clamping seat structure which clamps the heat radiator on the guide rail cannot be adapted to the guide rail with different widths.

In order to solve the above problems, the technical solution in the embodiments of the present application is as follows

In order to better understand the above technical solutions, the following detailed description will refer to the accompanying drawings and specific embodiments.

First embodiment:

fig. 1 shows a schematic structural diagram of a novel solid state heatsink of a first embodiment of the present utility model. Fig. 2 shows a schematic structural diagram of a novel solid state heatsink of a first embodiment of the present utility model. As shown in fig. 1 and 2, the present utility model discloses a novel solid state heatsink. The direction of Y in the figure is the right end of the structural schematic diagram of the utility model, and the direction of X in the figure is the upper end of the structural schematic diagram of the utility model.

The novel solid-state radiator comprises a radiating fin 1 for radiating the solid-state relay, a radiating piece 2 for guiding heat of the radiating fin 1 and a clamping seat 3 for installing the radiating piece 2 on a guide rail; one end of the radiating fin 1 is arranged on the radiating piece 2, and the other end of the radiating fin 1 is arranged on the solid-state relay; the cassette 3 is arranged at one end of the heat dissipation element 2 far away from the solid state relay.

The heat sink 1 is placed right and left. The upper surface of the radiating fin 1 is fixedly connected with a solid-state relay. The lower surface of the radiating fin 1 is fixedly connected with a radiating piece 2, and the heat of the solid state relay is conducted to the radiating fin 1. The heat on the radiating fin 1 is conducted to the radiating piece 2, and the radiating piece 2 conducts flow and dissipates the heat rapidly. The lower surface of the heat dissipation piece 2 is fixedly connected with a clamping seat 3. The heat sink 2 is fixed on the guide rail through the clamping seat 3.

Because the radiating fin 1 is attached to the solid-state relay, heat on the solid-state relay is guided to the radiating piece 2, the heat on the radiating piece 2 is rapidly dissipated, and further, the heat is rapidly dissipated and conducted layer by layer, and the radiating efficiency is high.

The heat sink 2 includes a heat conductive sheet 21 provided on the heat sink 1 and heat radiation fins 22 for radiating heat from the heat conductive sheet 21; the heat radiation fins 22 are provided along the heat conductive fins 21; the heat radiating fins 22 are disposed obliquely.

The radiating fins 22 are also provided with saw teeth 221; the serrations 221 are provided along the heat radiating fins 22.

The heat conductive sheet 21 is elongated. The lower end of the heat conductive sheet 21 is provided with a fixing seat. The fixing seat is fixedly connected with the clamping seat 3. The heat conductive sheet 21 is provided with heat dissipation fins 22 on the front and rear sides. The heat dissipation fins 22 are uniformly provided along the heat conduction fins 21. The heat radiating fins 22 are provided downward away from the end face of the heat conducting fin 21. The heat radiating fins 22 are uniformly provided with serrations 221. So that the contact area of the heat radiating fins 22 is increased and the heat radiating effect is good.

Due to the fact that the heat conducting fin 21 is arranged on the heat radiating piece 2 to quickly guide heat to the heat conducting fin 21, then the heat is uniformly transferred to the heat radiating tooth fin 22, the heat radiating area is enlarged, and therefore good heat radiating effect and quick guide are achieved.

Due to the adoption of the sawtooth 221 arranged on the radiating tooth piece 22, the radiating area is increased, and further, the good radiating effect and rapid flow guiding are realized.

The clamping seat 3 comprises a first clamping piece 31 and a second clamping piece 32 which is connected to the first clamping piece 31 in a sliding manner; the first clip 31 is provided on the heat conductive sheet 21; a first elastic piece 33 is arranged between the first clamping piece 31 and the second clamping piece 32; the first elastic member 33 pulls the second clip member 32 toward the first clip member 31.

The first clamping piece 31 and the second clamping piece 32 are respectively provided with a clamping groove 34; when the clamping seat 3 is clamped into the guide rail, the clamping groove 34 is clamped into the guide rail.

The upper surface of the first clamping piece 31 is fixedly connected with the lower surface of the heat conducting strip 21, and the second clamping piece 32 is connected to the first clamping piece 31 in a left-right sliding mode. An elastic member is disposed between the first clamping member 31 and the second clamping member 32. The end surface of the first clamping piece 31 facing the guide rail is provided with a clamping groove 34. The second clamping member 32 is provided with a clamping groove 34 towards the end surface of the guide rail.

Due to the fact that the second clamping piece 32 is slidably connected to the first clamping piece 31, the second clamping piece 32 is always pulled to the first clamping piece 31 through the first elastic piece 33, the guide rail is clamped between the first clamping piece 31 and the second clamping piece 32 through the first elastic piece 33, and therefore the clamping seat 3 is clamped on the guide rail.

Because the first clamping piece 31 and the second clamping piece 32 are adopted, the clamping groove 34 is formed, and the clamping groove 34 corresponds to the guide rail, so that the clamping seat 3 is more stable when clamped on the guide rail.

Second embodiment:

fig. 3 is a schematic diagram of a card holder according to a second embodiment of the utility model. Fig. 4 shows a schematic view of a cartridge partially cut away according to a second embodiment of the present utility model. Fig. 5 shows a partial enlarged view of a in fig. 3. The second embodiment differs from the first embodiment in that, as shown in connection with fig. 1, 2, 3, 4 and 5:

the clamping seat 3 comprises a fixed block 35 arranged on the heat conducting fin 21, a gear 36 rotatably connected in the fixed block 35, a clamping piece 37 slidably connected in the fixed block 35 and a driving device 38 for driving the gear 36 to rotate; the clamping members 37 are oppositely arranged; the gear 36 engages the clamping member 37; the gear 36 engages the drive 38; when the driving device 38 drives the gear 36 to rotate, the gear 36 drives the clamping piece 37 to move away from or approach the guide rail.

The fixing block 35 is placed left and right. The upper surface of the fixing block 35 is fixedly connected to the lower surface of the heat conductive sheet 21. A gear 36 is rotatably provided in the fixed block 35. Clamping members 37 are provided at both left and right ends of the fixed block 35. The clamping member 37 engages the gear 36. When the gear 36 rotates, the clamping members 37 at both ends simultaneously move in a direction away from or toward the guide rail. The front end of the fixed block 35 is also provided with a driving device 38. The drive 38 engages the gear 36. When the driving device 38 moves toward the gear 36, the clamping members 37 at both ends move toward the clamping rail. When the driving device 38 moves away from the gear 36, the clamping members 37 at both ends move away from the guide rail.

When the driving device 38 is adopted to drive the gear 36 to rotate, the clamping pieces 37 at the two sides of the fixed block 35 are driven to be far away from or close to the guide rail, so that the clamping seat 3 is clamped on the guide rail.

The clamping piece 37 comprises a first rack 371 and a clamping block 372, wherein the first rack 371 is slidably connected in the fixed block 35; the first rack 371 is provided with a wedge 373; the fixed block 35 is provided with a wedge groove 351 which is connected with the wedge block 373 in a sliding way; the wedge grooves 351 are oppositely arranged; the clamping block 372 is fixedly connected to one end of the first rack 371.

The first rack 371 is slidably coupled within the fixed block 35. The first rack 371 is provided with a wedge 373 toward the end face of the fixed block 35. Wedge grooves 351 are formed in the fixing blocks 35. Wedge 373 is slidably coupled within wedge groove 351. The first rack 371 is engaged with the gear 36. One end of the first rack 371, which is far away from the fixed block 35, is fixedly connected with a clamping block 372.

Due to the fact that the wedge-shaped block 373 is arranged on the first rack 371, the wedge-shaped groove 351 is formed in the fixed block 35, the first rack 371 is fixedly connected with the clamping block 372, the first rack 371 slides in the fixed block 35, and therefore stable transmission of the first rack 371 in the fixed block 35 is achieved when the gear 36 is in transmission.

The clamping block 372 is provided with a compression block 374, and a fourth elastic piece 375 is connected between the compression block 374 and the clamping block 372; the fourth elastic member 375 compresses the compression block 374 in the direction of the guide rail; the pressing block 374 is provided with a chamfer 376, and the chamfer 376 is provided on the end face facing the fixed block 35.

The clamp 372 is C-shaped. The clamping block 372 is provided with a plurality of fourth elastic members 375. The upper surface of the fourth elastic member 375 is fixedly connected with a pressing block 374. The lower surface of the fourth elastic member 375 is fixedly connected to the clamping block 372. The end surface of the fourth elastic member 375 facing the fixed block 35 is provided with a chamfer 376.

Because the clamping block 372 is provided with the pressing block 374, the pressing block 374 is provided with the chamfer 376, the fourth elastic piece 375 is arranged between the pressing block 374 and the clamping block 372, when the clamping block 372 moves towards the guide rail until the guide rail is clamped, the chamfer 376 on the pressing block 374 contacts the guide rail and moves downwards until the upper end face of the pressing block 374 presses the lower end face of the guide rail, and further the clamping seat 3 is more stable when clamped on the guide rail.

The driving device 38 includes a second rack 381 and a second elastic member 382 for tensioning the second rack 381; a second rack 381 slidably coupled within the fixed block 35, the second rack 381 engaging the gear 36; the second elastic member 382 is disposed between the second rack 381 and the fixed block 35.

The second rack 381 is slidably coupled within the fixed block 35. The second rack 381 engages the gear 36. A second elastic member 382 is provided between the second rack 381 and the fixed block 35. The second elastic member 382 pulls the second rack 381 toward the fixed block 35. Thereby causing the gear 36 to rotate. The clamping blocks 372 at the two ends of the fixed block 35 are driven to move towards the guide rail direction. Until the rail is clamped.

Because the second rack 381 is meshed with the gear 36, the second elastic piece 382 pulls the second rack 381 towards one direction all the time, so that the clamping blocks 372 at the two ends of the fixed block 35 move towards the direction until the guide rail is clamped, and further the second elastic piece 382 automatically clamps the clamping blocks 372 at the two ends of the guide rail, so that the clamping seat 3 is more stable when clamped on the guide rail.

The fixed block 35 is provided with a locking assembly 39; the locking assembly 39 includes a support plate 352, a clamping block 353 clamping the second rack 381, a guide rod 354 guiding the clamping block 353, and a third elastic member 355 moving the clamping block 353; the second rack 381 is provided with a clamping groove 383 corresponding to the clamping block 353; the clamping block 353 is clamped into the clamping groove 383; the third elastic piece 355 is sleeved on the guide rod 354; the guide rod 354 is arranged on the support plate 352 in a penetrating way; one end of the third elastic member 355 abuts against the support plate 352, and the other end of the third elastic member 355 abuts against the clamping block 353.

The second rack 381 is provided with a slot 383. The support plate 352 is fixedly connected to the fixing block 35. Guide rods 354 are provided on the support plate 352. The guide rod 354 is provided with a clamping block 353 toward one end of the second rack 381. The guide rod 354 is provided with a pulling plate at one end thereof remote from the second rack 381. A third elastic member 355 is provided between the clamping block 353 and the support plate 352. The third elastic member 355 is sleeved on the guide rod 354. The third elastic member 355 always moves the clamping block 353 toward the second rack 381 until the clamping block 353 is clamped into the clamping groove 383.

Because the clamping block 353 is adopted to clamp the position of the second rack 381, the guide rod 354 guides the displacement of the clamping block 353, the third elastic piece 355 always moves the clamping block 353 towards the second rack 381 until the clamping block 353 is clamped into the clamping groove 383, and then the position of the second rack 381 is adjusted to the highest position when the clamping seat 3 is not used, the clamping seat 3 is more conveniently used by limiting the position of the second rack 381 through the clamping block 353, the clamping block 353 is moved out of the clamping groove 383 when the clamping is needed, and the clamping blocks 372 at the two ends move towards the guide rail until the guide rail is clamped.

While preferred embodiments of the present utility model have been described, additional variations and modifications in those embodiments may occur to those skilled in the art once they learn of the basic inventive concepts. It is therefore intended that the following claims be interpreted as including the preferred embodiments and all such alterations and modifications as fall within the scope of the utility model.

It will be apparent to those skilled in the art that various modifications and variations can be made to the present utility model without departing from the spirit or scope of the utility model. Thus, it is intended that the present utility model also include such modifications and alterations insofar as they come within the scope of the appended claims or the equivalents thereof.

Claims (10)

1. The novel solid-state radiator is characterized by comprising radiating fins (1) for radiating the solid-state relay, radiating pieces (2) for guiding heat of the radiating fins (1) and clamping seats (3) for installing the radiating pieces (2) on guide rails; one end of the radiating fin (1) is arranged on the radiating piece (2), and the other end of the radiating fin (1) is arranged on the solid state relay; the clamping seat (3) is arranged at one end, far away from the solid-state relay, of the heat radiating piece (2).

2. The novel solid state heat sink according to claim 1, wherein the heat sink (2) comprises a heat conducting fin (21) provided on the heat sink (1) and heat radiating fins (22) radiating the heat conducting fin (21); the heat dissipation tooth plates (22) are arranged along the heat conduction plates (21); the radiating fins (22) are obliquely arranged.

3. The novel solid state heat sink of claim 2, wherein the heat dissipating teeth (22) are further provided with serrations (221); the serrations (221) are provided along the heat radiating fins (22).

4. The novel solid state heat sink according to claim 2, wherein the cartridge (3) comprises a first clip (31) and a second clip (32) slidingly connected to the first clip (31); the first clamping piece (31) is arranged on the heat conducting sheet (21); a first elastic piece (33) is arranged between the first clamping piece (31) and the second clamping piece (32); the first elastic member (33) pulls the second clamping member (32) toward the first clamping member (31).

5. The novel solid state heat sink according to claim 4, wherein the first clamping piece (31) and the second clamping piece (32) are provided with clamping grooves (34); when the clamping seat (3) is clamped into the guide rail, the clamping groove (34) is clamped into the guide rail.

6. A new solid state heat sink according to claim 2, characterized in that the cartridge (3) comprises a fixed block (35) provided on the thermally conductive sheet (21), a gear (36) rotatably connected in the fixed block (35), a clamping member (37) slidably connected in the fixed block (35) and a driving device (38) driving the gear (36) to rotate; the clamping pieces (37) are oppositely arranged; the gear (36) engages the clamping member (37); the gear wheel (36) engages the drive device (38); when the driving device (38) drives the gear (36) to rotate, the gear (36) drives the clamping piece (37) to be far away from or close to the guide rail.

7. The novel solid state heat sink of claim 6 wherein the clamp (37) comprises a first rack (371) slidably coupled within the fixed block (35) and a clamp block (372) clamping the rail; a wedge block (373) is arranged on the first rack (371); a wedge-shaped groove (351) which is connected with the wedge-shaped block (373) in a sliding way is formed in the fixed block (35); the wedge-shaped grooves (351) are oppositely arranged; the clamping block (372) is fixedly connected to one end of the first rack (371).

8. The novel solid state heat sink of claim 7, wherein a compression block (374) is provided on the clamping block (372), and a fourth elastic member (375) is connected between the compression block (374) and the clamping block (372); the fourth elastic piece (375) compresses the compression block (374) towards the direction of the guide rail; a chamfer (376) is formed on the compression block (374), and the chamfer (376) is formed on the end face facing the fixed block (35).

9. The new solid state heat sink according to claim 8, characterized in that the driving means (38) comprise a second rack (381) and a second elastic member (382) tensioning the second rack (381); the second rack (381) is slidably connected in the fixed block (35), and the second rack (381) is meshed with the gear (36); the second elastic member (382) is disposed between the second rack (381) and the fixed block (35).

10. The novel solid state heat sink of claim 9, wherein the fixed block (35) is provided with a locking assembly (39); the locking assembly (39) comprises a support plate (352), a clamping block (353) for clamping the second rack (381), a guide rod (354) for guiding the clamping block (353), and a third elastic member (355) for moving the clamping block (353); a clamping groove (383) corresponding to the clamping block (353) is formed in the second rack (381); the clamping block (353) is clamped into the clamping groove (383); the third elastic piece (355) is sleeved on the guide rod (354); the guide rod (354) penetrates through the support plate (352); one end of the third elastic piece (355) abuts against the support plate (352), and the other end of the third elastic piece (355) abuts against the clamping block (353).

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