CN218511293U - Silicon-based array nanotube cooling device - Google Patents

Abstract

The utility model discloses a silica-based array nanotube cooling device, including main part pipeline and coupling assembling, the outer wall cover of main part pipeline is equipped with first cooling tube, and the rear end of first cooling tube is connected with the third cooling tube, and the rear end of third cooling tube is connected with the second cooling tube, is used for fixing the cooling tube coupling assembling installs in third cooling tube front end outer wall, coupling assembling includes fixed block, carousel, threaded rod, connecting piece, cardboard and buckle, and the inside threaded connection of fixed block has the threaded rod, and the terminal fixed mounting of threaded rod has the carousel, and the one end that the carousel was kept away from to the threaded rod rotates and is connected with the connecting piece, and the inner wall of connecting piece rotates and installs the cardboard, and the one end block of keeping away from the connecting piece of cardboard is equipped with the buckle. This silicon-based array nanotube cooling device not only can make the cooling tube dock fixedly fast, and liquid leakage when preventing the connector disconnection simultaneously can also carry out the secondary to the liquid after the intensification and cool down, and the practicality is strong.

Description

Silicon-based array nanotube cooling device

Technical Field

The utility model relates to a silica-based array nanotube technical field specifically is a silica-based array nanotube cooling device.

Background

Carbon nanotubes, also known as buckytubes, are one-dimensional quantum materials with a special structure (radial dimension is nanometer magnitude, axial dimension is micrometer magnitude, both ends of the tube are basically sealed). And when the silicon-based array nanotube is cooled and reacted for a long time, blowing nitrogen into the cooling tank, starting the water cooling machine, cooling to 80 ℃, and blowing the nitrogen into the finished product tank.

The existing silicon-based array nanotube cooling device has short heat dissipation stroke, so that the heat dissipation effect is poor and the heat dissipation period is long. And the assembly is complicated, and the multiple sections of silicon-based nanotubes cannot be quickly connected conveniently and quickly to form an alignment relation.

Therefore, the cooling device for silicon-based array nanotubes is provided by improving the existing structure and defects.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a silica-based array nanotube cooling device to solve the problem that proposes among the above-mentioned background art.

In order to achieve the above purpose, the utility model provides a following technical scheme: the utility model provides a silicon-based array nanotube cooling device, includes main part pipeline and coupling assembling, the outer wall cover of main part pipeline is equipped with first cooling tube, and the rear end of first cooling tube is connected with the third cooling tube, the rear end of third cooling tube is connected with the second cooling tube, is used for fixing the cooling tube coupling assembling installs in third cooling tube front end outer wall, coupling assembling includes fixed block, carousel, threaded rod, connecting piece, cardboard and buckle, the inside threaded connection of fixed block has the threaded rod, and the terminal fixed mounting of threaded rod has the carousel, the one end that the carousel was kept away from to the threaded rod rotates and is connected with the connecting piece, the inner wall of connecting piece rotates and installs the cardboard, and the one end block of keeping away from the connecting piece of cardboard is equipped with the buckle, and the end of buckle is fixed with the third cooling tube.

Furthermore, a connecting port is fixedly arranged at the joint of the second radiating pipe and the third radiating pipe, and a slot is arranged at the top of the connecting port in a clamping manner.

Furthermore, a sealing plate is slidably mounted inside the slot, and an annular sealing gasket is fixedly mounted at one end of the sealing plate corresponding to the slot.

Furthermore, a spring is vertically installed at the top of the sealing plate, and the tail end of the spring is fixed with the third radiating pipe.

Furthermore, the top of the slot is connected with a return pipe, and the return pipe surrounds the interior of the third radiating pipe.

Furthermore, the starting end of the return pipe is fixedly connected with a water inlet, and the tail end of the return pipe is connected with a water outlet in a through mode.

Furthermore, the end-to-end connection of water inlet has the water pump, and the end of water pump has the water tank through connection through the drinking-water pipe, the front end fixed mounting of water tank has the refrigerator, and the end of delivery port carries out through connection with the water tank

Compared with the prior art, the beneficial effects of the utility model are that:

this silicon-based array nanotube cooling device not only can make the cooling tube dock fixedly fast, and liquid leakage when preventing the connector disconnection simultaneously can also carry out the secondary to the liquid after the intensification and cool down, and the practicality is strong.

1. The utility model discloses a setting of coupling assembling, make the control cardboard inwards overturn around the connecting piece and carry out the block with the buckle and be connected, rethread rotation connecting piece bottom installation threaded rod, the cardboard is pulled downwards under the control of carousel, make cardboard one side vertically fixed third cooling tube bottom and second cooling tube top closed, make the connection port insert inside the slot that the third cooling tube bottom was seted up, and jack-up the closing plate inside the slot makes the inside back flow that sets up of third cooling tube link up with the inside back flow of second cooling tube, thereby reach the quick butt joint fixed purpose of cooling tube;

2. the utility model discloses through the setting of closing plate cooperation spring, when connection port and slot disconnection, the spring that the slot was inside set up promotes the closing plate and moves down and seals the junction of back flow and slot through the sealed pad that sets up below the closing plate, prevents that liquid from leaking when connection port disconnects, makes it can freely control the number and the length of cooling tube;

3. the utility model discloses a setting of refrigerator for the coolant liquid after the refrigerator is to the intensification of pump return water tank cools down, makes the coolant liquid keep balanced state, guarantees the cooling effect behind the coolant liquid inflow reflux pipe.

Drawings

Fig. 1 is a schematic diagram of an overall three-dimensional structure of a silicon-based array nanotube cooling device of the present invention;

fig. 2 is a schematic view of a connection structure between the second heat pipe and the third heat pipe of the silicon-based array nanotube cooling device of the present invention;

fig. 3 is an enlarged schematic structural view of a portion a in fig. 2 of a silicon-based array nanotube cooling device according to the present invention;

fig. 4 is a schematic view of a three-dimensional structure of the silicon-based array nanotube cooling device according to the present invention, in which a main pipe and a water tank are connected;

fig. 5 is a schematic view of a planar expansion structure of a reflux pipe of a silicon-based array nanotube cooling device of the present invention.

In the figure: 1. a main body duct; 2. a first radiating pipe; 3. a second heat dissipation pipe; 4. a third radiating pipe; 5. a connection assembly; 501. a fixed block; 502. a turntable; 503. a threaded rod; 504. a connecting member; 505. clamping a plate; 506. buckling; 6. a connection port; 7. a slot; 8. sealing plates; 9. a gasket; 10. a spring; 11. a return pipe; 12. a water inlet; 13. a water outlet; 14. a water pump; 15. a water pumping pipe; 16. a water tank; 17. a refrigerator.

Detailed Description

As shown in fig. 1 to 3, a silicon-based array nanotube cooling device includes a main pipe 1 and a connection assembly 5, wherein an outer wall of the main pipe 1 is sleeved with a first heat pipe 2, and a rear end of the first heat pipe 2 is connected with a third heat pipe 4, a rear end of the third heat pipe 4 is connected with a second heat pipe 3, the connection assembly 5 for fixing the heat pipe is installed on an outer wall of a front end of the third heat pipe 4, the connection assembly 5 includes a fixing block 501, a turn plate 502, a threaded rod 503, a connector 504, a snap plate 505 and a buckle 506, the threaded block 501 is internally and threadedly connected with the threaded rod 503, the threaded rod 503 is fixedly installed at a terminal thereof with the turn plate 502, the connector 504 is rotatably connected to one end of the threaded rod 503 far away from the turn plate 502, the snap plate 505 is rotatably installed on an inner wall of the connector 504, the snap plate 505 is provided with the buckle 506 at one end far away from the connector 504, and the terminal of the buckle 506 is fixed to the third heat pipe 4, the snap plate 505 is turned inwards around the connector 504 and is snap-connected to the buckle 506, the threaded rod 503 installed at a backflow pipe 503 at the bottom of the connector 504, the backflow pipe 505 is pulled downwards under the control of the snap plate 505, the heat pipe 505 vertically fixed to enable the heat pipe 505 to be inserted into a top of the heat pipe 7 of the heat pipe 11, and the heat pipe is connected to be quickly connected to the heat pipe, and the heat pipe 11 is connected to the heat pipe.

As shown in fig. 3, a connection port 6 is fixedly installed at a butt joint of the second heat dissipation tube 3 and the third heat dissipation tube 4, and a slot 7 is provided at a top of the connection port 6, a sealing plate 8 is slidably installed inside the slot 7, and an annular sealing gasket 9 is fixedly installed at one end of the sealing plate 8 corresponding to the slot 7, a spring 10 is vertically installed at a top of the sealing plate 8, and a terminal of the spring 10 is fixed to the third heat dissipation tube 4, a return pipe 11 is connected to a top of the slot 7, and the return pipe 11 surrounds an inside of the third heat dissipation tube 4, when the connection port 6 is disconnected from the slot 7, the spring 10 installed inside the slot 7 pushes the sealing plate 8 to move down and seals a joint of the return pipe 11 and the slot 7 through the sealing gasket 9 installed below the sealing plate 8, thereby preventing liquid leakage when the connection port 6 is disconnected, and enabling the number and length of the heat dissipation tubes to be freely controlled.

As shown in fig. 4-5, a water inlet 12 is fixedly connected to a start end of the return pipe 11, a water outlet 13 is connected to a tail end of the return pipe 11 in a penetrating manner, a water pump 14 is connected to a tail end of the water inlet 12, a water tank 16 is connected to a tail end of the water pump 14 in a penetrating manner through a water pumping pipe 15, a refrigerator 17 is fixedly mounted at a front end of the water tank 16, the tail end of the water outlet 13 is connected to the water tank 16 in a penetrating manner, the refrigerator 17 cools down the heated coolant in the pump return water tank 16, so that the coolant is kept in a balanced state, and a cooling effect after the coolant flows into the return pipe 11 is ensured.

The working principle is as follows: when the silicon-based array nanotube cooling device is used, firstly, the control clamping plate 505 is turned inwards around the connecting piece 504 and is clamped and connected with the buckle 506, then the threaded rod 503 arranged at the bottom of the connecting piece 504 is rotated, the clamping plate 505 is pulled downwards under the control of the rotary table 502, so that the bottom of the third radiating pipe 4 vertically fixed on one side of the clamping plate 505 is closed with the top of the second radiating pipe 3, the connecting port 6 is inserted into the slot 7 formed in the bottom of the third radiating pipe 4, the sealing plate 8 in the slot 7 is jacked up, so that the return pipe 11 arranged in the third radiating pipe 4 is communicated with the return pipe 11 in the second radiating pipe 3, the warmed cooling liquid of the pump return water tank 16 is cooled through the refrigerator 17, when the connecting port 6 is disconnected with the slot 7, the spring 10 arranged in the slot 7 pushes the sealing plate 8 to move downwards, the joint of the return pipe 11 and the slot 7 is sealed through the sealing gasket 9 arranged below the sealing plate 8, and liquid leakage when the connecting port 6 is disconnected.

The embodiments of the present invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiment was chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.

Claims (7)

1. The utility model provides a silicon-based array nanotube cooling device, includes main part pipeline (1) and coupling assembling (5), a serial communication port, the outer wall cover of main part pipeline (1) is equipped with first cooling tube (2), and the rear end of first cooling tube (2) is connected with third cooling tube (4), the rear end of third cooling tube (4) is connected with second cooling tube (3), is used for fixing the cooling tube coupling assembling (5) are installed in third cooling tube (4) front end outer wall, coupling assembling (5) are including fixed block (501), carousel (502), threaded rod (503), connecting piece (504), cardboard (505) and buckle (506), fixed block (501) internal thread is connected with threaded rod (503), and the terminal fixed mounting of threaded rod (503) has carousel (502), the one end rotation that carousel (502) were kept away from in threaded rod (503) is connected with connecting piece (504), and the inner wall rotation of connecting piece (504) installs cardboard (505), cardboard (505) are kept away from the one end block of connecting piece (504) and are equipped with buckle (506), and the end and third cooling tube (4) fixed connection of buckle (506).

2. The cooling device of silicon-based array nanotube according to claim 1, wherein a connection port (6) is fixedly installed at a joint of the second heat pipe (3) and the third heat pipe (4), and a slot (7) is formed at a top of the connection port (6) in a snap-fit manner.

3. The silicon-based array nanotube cooling device according to claim 2, wherein a sealing plate (8) is slidably installed inside the slot (7), and an annular sealing gasket (9) is fixedly installed at one end of the sealing plate (8) corresponding to the slot (7).

4. The cooling device for silicon-based array nanotubes of claim 3, wherein the top of the sealing plate (8) is vertically installed with a spring (10), and the end of the spring (10) is fixed with the third heat dissipation tube (4).

5. The silicon-based array nanotube cooling device as defined in claim 3, wherein a return pipe (11) is connected to the top of the slot (7), and the return pipe (11) surrounds the interior of the third heat pipe (4).

6. The silicon-based array nanotube cooling device according to claim 5, wherein a water inlet (12) is fixedly connected to the beginning of the return pipe (11), and a water outlet (13) is connected to the end of the return pipe (11).

7. The silicon-based array nanotube cooling device according to claim 6, wherein a water pump (14) is connected to an end of the water inlet (12), a water tank (16) is connected to an end of the water pump (14) through a water pumping pipe (15), a refrigerator (17) is fixedly installed at a front end of the water tank (16), and an end of the water outlet (13) is connected to the water tank (16) through.

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