CN111741658A

CN111741658A - Automatic radiator capable of being assembled independently

Info

Publication number: CN111741658A
Application number: CN202010647593.6A
Authority: CN
Inventors: 高经
Original assignee: Hangzhou Tebai Electronic Technology Co ltd
Current assignee: Hangzhou Tebai Electronic Technology Co ltd
Priority date: 2020-07-07
Filing date: 2020-07-07
Publication date: 2020-10-02

Abstract

The invention discloses an automatic radiator capable of being assembled independently, which comprises a base, wherein the left side of the upper end surface of the base is provided with a heat dissipation area, a fan box is fixedly arranged on the right side of the upper end surface of the base, a fan transmission cavity is arranged in the fan box, a fan shaft is rotatably connected with the left wall in the fan transmission cavity, a fan rotating area is arranged between the heat dissipation area and the fan box, a power cavity is arranged in the base and below the fan transmission cavity, a rotating shaft is arranged between the fan transmission cavity and the power cavity in a penetrating way, the invention adopts the mode of increasing the radiating fins and enlarging the radiating area, by freely increasing and decreasing the radiating fins to meet the actual radiating requirement and detecting the temperature, therefore, the heat dissipation area is automatically increased, and the air cooling and water cooling modes are automatically carried out on the heat dissipation fins at the same time, so that the effect of rapid heat dissipation is achieved, and various heat dissipation requirements are met.

Description

Automatic radiator capable of being assembled independently

Technical Field

The invention relates to the technical field of electronic radiators, in particular to an automatic radiator capable of being assembled independently.

Background

In daily life, along with the increasing power of electronic devices, the effect of corresponding radiators is more and more non-negligible, the existing radiators are divided into active and passive radiators, the passive radiator is low in price but only simply adds radiating fins for radiating, the radiating effect is not good, the radiating effect of the active radiator is good, but the noise of the air-cooled radiator is large, and the noise of the water-cooled radiator is noiseless, but the price is high, the assembly difficulty is high, and the radiator is not friendly to ordinary people. The present invention sets forth a device that solves the above problems.

Disclosure of Invention

The technical problem is as follows: the passive heat dissipation price is low but the radiating effect is not good, and the active radiator effect is better, but only the radiating effect is considered, and the problems of noise, high cost and even safety are not well solved.

The automatic radiator comprises a base, wherein a heat dissipation area is arranged on the left side of the upper end face of the base, a fan box is fixedly arranged on the right side of the upper end face of the base, a fan transmission cavity is arranged in the fan box, a fan shaft is rotatably connected to the left wall in the fan transmission cavity, a fan rotating area is arranged between the heat dissipation area and the fan box, a power cavity is arranged in the base and below the fan transmission cavity, a rotating shaft is arranged between the fan transmission cavity and the power cavity in a penetrating manner, a transmission cavity is arranged in the base and on the left side of the power cavity, a transmission shaft is rotatably connected between the front wall and the rear wall in the transmission cavity, transmission bevel gears are arranged on the outer circular surface of the transmission shaft in an array manner, and an outer radiating fin is fixedly arranged above each transmission bevel gear, the lower end face of the outer radiating fin is fixedly connected with the upper end face of the base, a lifting cavity with an upward opening is arranged in the outer radiating fin, an inner radiating fin capable of sliding up and down is arranged in the lifting cavity, a screw cavity with a downward opening is arranged in the center of the inner radiating fin, a screw rod connected in the base in a rotating mode is connected in the screw cavity in a threaded mode, the lower end of the screw rod extends downwards to the transmission cavity and is fixedly provided with a screw bevel gear meshed with the transmission bevel gear, an upper pull rope is fixedly connected between the middle outer radiating fin and the inner radiating fin in the middle of the outer radiating fin, a motor is fixedly arranged in the inner wall between the transmission cavity and the power cavity, additional cavities with upward openings are symmetrically arranged at the upper end of the base and above the transmission cavity in a left-right mode, the rear ends of the additional cavities are communicated with openings with the backward openings, the additional cavities at the left side and the, install the gear additional can in install intracavity forward and backward rotation additional, the left and right sides corresponds install the fixed fin that is equipped with in gear top additional, lower extreme bilateral symmetry is equipped with the fixed chamber that the opening is decurrent in the fin, every fixed chamber below all corresponds install the gear additional, install the gear additional can pass through the opening increase is located install the quantity of intracavity additional, along with install the increase of gear additional and then can increase thereby the radiating rate of radiator can be increased to the quantity of fin.

Preferably, the left end of the fan shaft extends leftwards to the inside of the fan rotating area and is fixedly connected with a rotating block, a fan is arranged on the outer circular surface array of the rotating block, a fan bevel gear is fixedly arranged at the right end of the fan shaft and is located at the left end inside the fan transmission cavity, a rotating bevel gear meshed with the fan bevel gear is fixedly arranged at the lower side of the upper end of the rotating shaft and is located at the lower side inside the fan transmission cavity, a driven bevel gear is fixedly arranged at the upper side of the lower end of the rotating shaft and is located at the inner side of the power cavity, a water wheel shaft is rotatably connected to the rear wall inside the power cavity, and a driving bevel gear meshed with the.

Preferably, a water wheel box is fixedly arranged right behind the power cavity, a water wheel cavity is arranged in the water wheel box, a water inlet cavity with a backward opening is communicated with the rear wall of the water wheel cavity, a water inlet pipe is fixedly connected to the rear wall of the water inlet cavity, a water outlet cavity with a leftward opening is communicated with the left wall of the water wheel cavity, a water outlet pipe is fixedly arranged on the left wall of the water outlet cavity, the rear end of the water wheel shaft extends backwards into the water wheel cavity, and water wheel blades are arranged on the outer circular surface in an array mode.

Preferably, a right power shaft is rotatably arranged on the left wall in the power cavity, a power bevel gear meshed with the drive bevel gear is fixedly arranged at one end of the right power shaft positioned in the power cavity, the left end of the right power shaft extends leftwards into the base and is in power connection with the right end face of the motor, a right sliding cavity is arranged between the motor and the transmission cavity, a rotating part capable of sliding leftwards and rightwards is arranged in the right sliding cavity, a first key groove with a right opening is arranged in the inner rotating part, a spline shaft capable of being in rotating fit and sliding leftwards and rightwards is in internal thread connection with the first key groove, the right end of the spline shaft extends rightwards into the base and is in power connection with the left end face of the motor, a spring cavity is arranged on the outer circular face of the right sliding cavity, a slide block capable of sliding leftwards and rightwards in the spring cavity is fixedly connected to the outer circular face of the inner rotating part, and springs are vertically, the upper side the slider right-hand member face fixedly connected with stay cord down, down the stay cord with go up the stay cord and be connected, the outer disc left end of internal rotation piece is fixed with outer rotation piece, be equipped with the second keyway that the opening is right in the outer rotation piece, the inner rotation piece can in second keyway normal running fit and can the horizontal slip, the outer rotation piece left end extends to the transmission intracavity is fixed and is equipped with the centre driven bevel gear that transmission bevel gear engaged with.

Preferably, a liquid pipe is fixedly arranged on the front end face of the outer radiating fin, the lower end of the right side of the liquid pipe is communicated with the water inlet pipe, and the lower end of the left side of the liquid pipe is communicated with the water outlet pipe.

Preferably, a gear shaft is fixedly connected to the center of the additional gear, and the upper end of the gear shaft extends upwards into the fixed cavity and is fixedly connected with the inner circular surface of the fixed cavity.

Preferably, the opening with the intercommunication is equipped with the compression chamber between the loading chamber, be equipped with the sliding block that can the horizontal slip in the compression chamber, the sliding block right-hand member with fixedly connected with reset spring between the compression chamber right wall.

Preferably, a temperature detector is fixedly arranged on the lower side of one end face, close to the fan rotating area, of the middle outer radiating fin.

The invention has the beneficial effects that: the invention can meet the actual heat dissipation requirement by increasing the heat dissipation fins and enlarging the heat dissipation area, can automatically increase the heat dissipation area by freely increasing and decreasing the heat dissipation fins, can achieve the effect of rapid heat dissipation by automatically carrying out air cooling and water cooling on the heat dissipation fins at the same time by detecting the temperature, and can meet various heat dissipation requirements.

Drawings

For ease of illustration, the invention is described in detail by the following specific examples and figures.

FIG. 1 is a schematic view of an automatic heat sink of the present invention;

FIG. 2 is a top view of a self-mountable automotive heat sink;

FIG. 3 is a schematic view of the structure in the direction "A-A" of FIG. 1;

FIG. 4 is a schematic view of the structure in the direction "B-B" of FIG. 2;

FIG. 5 is a schematic view of the structure in the direction "C-C" of FIG. 2;

FIG. 6 is a schematic view of the structure in the direction "D-D" of FIG. 5;

fig. 7 is an enlarged view of the structure of "E" of fig. 6.

Detailed Description

The invention will now be described in detail with reference to fig. 1-7, for ease of description, the orientations described below will now be defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The invention relates to an automatic radiator capable of being assembled automatically, which comprises a base 11, wherein a heat dissipation area 53 is arranged on the left side of the upper end surface of the base 11, a fan box 23 is fixedly arranged on the right side of the upper end surface of the base 11, a fan transmission cavity 26 is arranged in the fan box 23, a fan shaft 27 is rotatably connected to the left wall in the fan transmission cavity 26, a fan rotating area 17 is arranged between the heat dissipation area 53 and the fan box 23, a power cavity 18 is arranged in the base 11 and below the fan transmission cavity 26, a rotating shaft 22 is arranged between the fan transmission cavity 26 and the power cavity 18 in a penetrating manner, a transmission cavity 12 is arranged in the base 11 and on the left side of the power cavity 18, a transmission shaft 14 is rotatably connected between the front wall and the rear wall in the transmission cavity 12, transmission bevel gears 13 are arranged on the outer circular surface of the transmission shaft 14 in an array manner, and an outer heat dissipation sheet 34, the lower end face of the outer radiating fin 34 is fixedly connected with the upper end face of the base 11, a lifting cavity 33 with an upward opening is arranged in the outer radiating fin 34, an inner radiating fin 32 capable of sliding up and down is arranged in the lifting cavity 33, a screw cavity 31 with a downward opening is arranged at the center in the inner radiating fin 32, a screw 30 rotatably connected in the base 11 is connected in the screw cavity 31 in a threaded manner, a screw bevel gear 15 meshed with the transmission bevel gear 13 is fixedly arranged in the transmission cavity 12 from the lower end of the screw 30 extending downwards, an upper pull rope 16 is fixedly connected between the middle outer radiating fin 34 and the inner radiating fin 32 therein, a motor 50 is fixedly arranged in the inner wall between the transmission cavity 12 and the power cavity 18, additional cavities 38 with upward openings are symmetrically arranged at the left and right sides above the transmission cavity 12 at the upper end in the base 11, and the rear ends of the additional cavities 38 are communicated with an opening 72 with the backward opening, the left and right sides install the chamber 38 in addition respectively the symmetry and the array be equipped with install gear 64 additional, install gear 64 additional can in install the chamber 38 in the fore-and-aft rotation, the left and right sides corresponds install gear 64 the fixed fin 71 that is equipped with in top additional, lower extreme bilateral symmetry is equipped with the fixed chamber 66 that the opening is decurrent in the fin 71, every fixed chamber 66 below all corresponds install gear 64 additional, install gear 64 additional can pass through opening 72 increases and is located install the quantity in the chamber 38 additional, along with install the increase of gear 64 and then can increase thereby the radiating rate of radiator 71's quantity can increase.

Beneficially, the left end of the fan shaft 27 extends leftwards to the inside of the fan rotating area 17 and is fixedly connected with a rotating block 29, a fan 28 is arranged on the outer circular surface array of the rotating block 29, a fan bevel gear 25 is fixedly arranged at the right end of the fan shaft 27 and located at the left end in the fan transmission cavity 26, a rotating bevel gear 24 meshed with the fan bevel gear 25 is fixedly arranged at the upper end of the rotating shaft 22 and located at the inner lower side of the fan transmission cavity 26, a driven bevel gear 21 is fixedly arranged at the lower end of the rotating shaft 22 and located at the inner upper side of the power cavity 18, a water wheel shaft 20 is rotatably connected to the inner rear wall of the power cavity 18, and a driving bevel gear 19 meshed with the driven bevel gear 21 is fixedly arranged at one end of the water wheel.

Beneficially, a water wheel box 58 is fixedly arranged right behind the power cavity 18, a water wheel cavity 57 is arranged in the water wheel box 58, a water inlet cavity 73 with a backward opening is communicated with the rear wall of the water wheel cavity 57, a water inlet pipe 59 is fixedly connected to the rear wall of the water inlet cavity 73, a water outlet cavity 54 with a leftward opening is communicated with the left wall of the water wheel cavity 57, a water outlet pipe 60 is fixedly arranged on the left wall of the water outlet cavity 54, the rear end of the water wheel shaft 20 extends backwards into the water wheel cavity 57, and water wheel blades 56 are arranged on the outer circumferential surface in an array mode.

Beneficially, a right power shaft 51 is rotatably disposed on the left wall in the power cavity 18, a power bevel gear 52 engaged with the driving bevel gear 19 is fixedly disposed at one end of the right power shaft 51 located in the power cavity 18, the left end of the right power shaft 51 extends leftwards into the base 11 and is in power connection with the right end face of the motor 50, a right sliding cavity 48 is disposed between the motor 50 and the transmission cavity 12, an inner rotating member 42 capable of sliding leftwards and rightwards is disposed in the right sliding cavity 48, a first key slot 45 with a right opening is disposed in the inner rotating member 42, a spline shaft 49 capable of rotatably matching and sliding leftwards and rightwards is screwed into the first key slot 45, the right end of the spline shaft 49 extends rightwards into the base 11 and is in power connection with the left end face of the motor 50, a spring cavity 47 is disposed on the outer circumferential face of the right sliding cavity 48, a slider 46 capable of sliding leftwards and rightwards in the spring cavity 47 is fixedly connected to the outer circumferential face, the spring 40 is vertically and symmetrically and fixedly arranged between the right end face of the sliding block 46 and the right wall in the spring cavity 47, the right end face of the sliding block 46 is fixedly connected with a lower pull rope 61, the lower pull rope 61 is connected with the upper pull rope 16, the outer circular face left end of the inner rotating part 42 is fixedly provided with an outer rotating part 41, a second key groove 43 with a right opening is arranged in the outer rotating part 41, the inner rotating part 42 can be in rotating fit in the second key groove 43 and can slide left and right, and the left end of the outer rotating part 41 extends into the transmission cavity 12 and is fixedly provided with a driven bevel gear 44 meshed with the middle transmission bevel gear 13.

Advantageously, a liquid pipe 37 is fixedly arranged on the front end face of the outer heat dissipation plate 34, the lower right end of the liquid pipe 37 is communicated with the water inlet pipe 59, and the lower left end of the liquid pipe 37 is communicated with the water outlet pipe 60.

Advantageously, a gear shaft 65 is fixedly connected to the center of the additional gear 64, and the upper end of the gear shaft 65 extends upwards into the fixed cavity 66 and is fixedly connected with the inner circular surface of the fixed cavity 66.

Advantageously, a compression cavity 69 is arranged between the opening 72 and the loading cavity 38 in a communication mode, a sliding block 68 capable of sliding left and right is arranged in the compression cavity 69, and a return spring 70 is fixedly connected between the right end of the sliding block 68 and the right wall of the compression cavity 69.

Advantageously, a temperature detector 35 is fixedly arranged on the lower side of one end face of the middle outer radiating fin 34 close to the fan rotating area 17.

The following describes in detail the use steps of an autonomous assembled automatic radiator in the present text with reference to fig. 1 to 7: in the initial state, the temperature detector 35 is started to detect the temperature of the lower end of the outer heat dissipation plate 34, the motor 50 is stopped, the driven bevel gear 44 is meshed with the transmission bevel gear 13, the water wheel blades 56 are stopped, the liquid in the liquid pipe 37 is still, the fan 28 is stopped, and the inner heat dissipation plate 32 is located in the lifting cavity 33.

During assembly, the additional gear 64 is additionally arranged in the additional cavity 38 according to actual conditions, the radiating fins 71 are increased according to the number of the additional gear 64, the fixed cavities 66 on the left side and the right side of the lower end in the radiating fins 71 are connected with the gear shafts 65 which are symmetrical left and right in the additional cavity 38, and the lower end face of the radiating fins 71 is connected with the upper end face of the base 11; meanwhile, the number of the outer radiating fins 34 and the inner radiating fins 32 is increased by increasing the transmission bevel gear 13 on the outer circular surface of the transmission shaft 14; when the cooling device works, the base 11 is connected with a machine needing cooling to start cooling, the temperature detector 35 detects the temperature of the lower end of the outer cooling fin 34, when the temperature detector 35 detects that the temperature of the outer cooling fin 34 reaches a preset value, the motor 50 is started to drive the right power shaft 51 to rotate, the right power shaft 51 drives the power bevel gear 52 to rotate so as to rotate the driving bevel gear 19, the driving bevel gear 19 drives the water wheel shaft 20 to rotate so as to drive the water wheel blades 56 to rotate in the water wheel cavity 57, the water wheel blades 56 drive the liquid in the water wheel cavity 57 to rotate so as to suck the liquid in the water inlet pipe 59 into the water wheel cavity 57 through the water inlet cavity 73, and the liquid in the liquid pipe 37 is driven to start circulating through the water outlet cavity 54 by the rotation; meanwhile, the driving bevel gear 19 drives the driven bevel gear 21 to rotate so as to drive the rotating shaft 22 to rotate, the rotating shaft 22 drives the rotating bevel gear 24 so as to drive the fan bevel gear 25 to rotate, the fan bevel gear 25 drives the fan shaft 27 to rotate so as to drive the rotating block 29 so as to drive the fan 28 to rotate, and the fan 28 starts to supply air to the left side for cooling; the motor 50 rotates the right power shaft 51 and simultaneously rotates the spline shaft 49, the spline shaft 49 drives the inner rotor 42 to rotate and further drives the outer rotor 41 to rotate, the outer rotor 41 drives the driven bevel gear 44 to rotate and further drives the bevel drive gear 13 engaged with the driven bevel drive gear to rotate, the bevel drive gear 13 drives the transmission shaft 14 to rotate in the transmission cavity 12 and further drives the other bevel drive gears 13 connected with the outer circumferential surface of the transmission shaft 14 to rotate, the bevel drive gear 13 drives the bevel screw gear 15 to rotate and further drives the inner heat sink 32 to ascend in the ascending and descending cavity 33, the inner heat sink 32 drives the upper pull rope 16 and further drives the lower pull rope 61, the lower pull rope 61 drives the slider 46 to slide to the right in the spring cavity 47 and further drives the inner rotor 42 to slide to the right in the right sliding cavity 48, when the inner heat sink 32 ascends to the vertex, the left end of the spline shaft 49 is located in the left end of the first key groove, further, the inner rotor 42 stops rotating to drive the driven bevel gear 44 to stop rotating, the driven bevel gear 44 stops driving the transmission shaft 14 to stop, and further the inner heat sink 32 stops rising to be kept still, and the heat dissipation area is increased.

After the temperature drops, the temperature detector 35 detects the temperature drop and controls the motor 50 to stop, the spline shaft 49 and the right power shaft 51 stop rotating, the fan 28 stops, the water wheel blade 56 stops, the sliding block 46 is reset under the drive of the spring 40 and drives the upper pull rope 16 through the lower pull rope 61, so that the inner rotating piece 42 is driven to drop back to the initial position.

In the above manner, a person skilled in the art can make various changes depending on the operation mode within the scope of the present invention.

Claims

1. The utility model provides an automatic radiator that can independently assembled, includes the base, its characterized in that: the left side of the upper end face of the base is provided with a heat dissipation area, the right side of the upper end face of the base is fixedly provided with a fan box, a fan transmission cavity is arranged in the fan box, the left wall in the fan transmission cavity is rotatably connected with a fan shaft, a fan rotating area is arranged between the heat dissipation area and the fan box, a power cavity is arranged in the base and below the fan transmission cavity, a rotating shaft is arranged between the fan transmission cavity and the power cavity in a penetrating manner, a transmission cavity is arranged in the base and at the left side of the power cavity, a transmission shaft is rotatably connected between the front wall and the rear wall in the transmission cavity, an outer circular surface array of the transmission shaft is provided with transmission bevel gears, an outer heat dissipation sheet is fixedly arranged above each transmission bevel gear, the lower end face of each outer heat dissipation sheet is fixedly connected with the upper end face of the base, a lifting cavity with an upward opening is arranged, a screw cavity with a downward opening is formed in the center of the inner radiating fin, a screw rod which is rotatably connected into the base is connected in the screw rod cavity in a threaded manner, the lower end of the screw rod extends downwards into the transmission cavity and is fixedly provided with a screw bevel gear meshed with the transmission bevel gear, an upper pull rope is fixedly connected between the middle outer radiating fin and the inner radiating fin, an upper pull rope is fixedly connected between the transmission cavity and the power cavity, a motor is fixedly arranged in the inner wall between the transmission cavity and the power cavity, additional cavities with upward openings are symmetrically arranged at the upper end in the base and above the transmission cavity in a bilateral manner, the rear ends of the additional cavities are communicated and provided with openings with backward openings, additional gears are symmetrically arranged in the additional cavities at the left side and the right side respectively and are arrayed, the additional gears can rotate forwards and backwards in the additional cavities, radiating fins are fixedly arranged at the left side and the right side corresponding to the upper portions of the, every fixed chamber below all corresponds install the gear additional, install the gear additional can pass through the opening increases to be located install the quantity of intracavity additional, along with install the increase of gear additional and then can increase thereby the radiating rate of the quantity of fin can increase the radiator.

2. The self-assemblable automatic heat sink of claim 1, wherein: the fan transmission device comprises a fan shaft, a fan transmission cavity, a rotating block, a fan bevel gear, a rotating shaft, a water wheel shaft, a driving bevel gear, a driven bevel gear, a water wheel shaft and a water wheel shaft, wherein the left end of the fan shaft extends leftwards to the inside of the fan rotation area and is fixedly connected with the rotating block, the outer circular surface array of the rotating block is provided with the fan, the right end of the fan shaft is located at the left end inside the fan transmission cavity, the fan bevel gear is fixedly arranged at the upper side inside the fan transmission cavity, the rotating bevel gear is fixedly meshed with the lower.

3. The self-assemblable automatic heat sink of claim 1, wherein: the hydraulic turbine is characterized in that a water wheel box is fixedly arranged right behind the power cavity, a water wheel cavity is arranged in the water wheel box, a water inlet cavity with a backward opening is communicated with the rear wall of the water wheel cavity, a water inlet pipe is fixedly connected to the rear wall of the water inlet cavity, a water outlet cavity with a leftward opening is communicated with the left wall of the water wheel cavity, a water outlet pipe is fixedly arranged on the left wall of the water outlet cavity, and the rear end of the water wheel shaft extends backwards to the inside of the water wheel cavity and the outer circular surface array of the water wheel shaft is provided.

4. An automatically self-assemblable heat sink as set forth in claim 2, wherein: a right power shaft is rotatably arranged on the left wall in the power cavity, a power bevel gear meshed with the driving bevel gear is fixedly arranged at one end of the right power shaft positioned in the power cavity, the left end of the right power shaft extends leftwards into the base and is in power connection with the right end face of the motor, a right sliding cavity is arranged between the motor and the transmission cavity, a rotating part capable of sliding leftwards and rightwards is arranged in the right sliding cavity, a first key groove with a right opening is formed in the inner rotating part, a spline shaft capable of being in rotating fit and sliding leftwards and rightwards is in internal thread connection with the first key groove, the right end of the spline shaft extends rightwards into the base and is in power connection with the left end face of the motor, a spring cavity is arranged on the outer circular face of the right sliding cavity, a slider capable of sliding leftwards and rightwards in the spring cavity is fixedly connected to the outer circular face of the inner rotating part, and springs are, the upper side the slider right-hand member face fixedly connected with stay cord down, down the stay cord with go up the stay cord and be connected, the outer disc left end of internal rotation piece is fixed with outer rotation piece, be equipped with the second keyway that the opening is right in the outer rotation piece, the inner rotation piece can in second keyway normal running fit and can the horizontal slip, the outer rotation piece left end extends to the transmission intracavity is fixed and is equipped with the centre driven bevel gear that transmission bevel gear engaged with.

5. The self-assemblable automatic heat sink of claim 1, wherein: the front end face of the outer radiating fin is fixedly provided with a liquid pipe, the lower end of the right side of the liquid pipe is communicated with the water inlet pipe, and the lower end of the left side of the liquid pipe is communicated with the water outlet pipe.

6. The self-assemblable automatic heat sink of claim 1, wherein: the center of the additional gear is fixedly connected with a gear shaft, and the upper end of the gear shaft upwards extends into the fixed cavity and is fixedly connected with the round surface in the fixed cavity.

7. The self-assemblable automatic heat sink of claim 1, wherein: the opening with it is equipped with the compression chamber to add to communicate between the dress chamber, be equipped with the sliding block that can the horizontal slip in the compression chamber, the sliding block right-hand member with fixedly connected with reset spring between the compression chamber right side wall.

8. The self-assemblable automatic heat sink of claim 1, wherein: and a temperature detector is fixedly arranged at the lower side of one end face of the middle outer radiating fin close to the fan rotating area.