CN115823888B - Cooling device is used in graphite alkene production - Google Patents

Abstract

A cooling device for graphene production solves the problem that cooling effect of cooling equipment in the prior art is not obvious. The furnace comprises a support frame and a furnace body, wherein the furnace body is fixedly connected with the support frame; the outer circumference of the furnace body is wound with a condensing pipe which is spirally arranged; the fan which rotates circumferentially is arranged on the supporting frame and swings in the circumferential rotation process.

Description

Cooling device is used in graphite alkene production

Technical Field

The invention relates to the technical field of graphene preparation, in particular to a cooling device for graphene production.

Background

The graphene has excellent optical, electrical and mechanical properties, and can be used in materials science, micro-nano processing and energy sources. The material has important application prospect in biomedical and drug delivery, and is considered as a revolutionary material in the future.

The utility model provides a 202021045236.4, the name is a cooling body of processing equipment of graphite alkene, it includes casing and furnace body, the mounting hole has all been seted up at the top of casing both sides face, the inside of two mounting holes is all through the surface fixed connection of connecting block and furnace body, the right-hand member fixedly connected with coolant tank of diapire in the casing, the bottom fixedly connected with condenser of coolant tank side, this processing equipment cooling body of graphite alkene, through setting up the condenser, the inlet tube, the water pump, the spiral water pipe, filter tank and circulating pipe, graphene cooling rate has been improved, graphene's production efficiency has been accelerated.

But it has the following disadvantages: 1) The condensing pipes of the water inlet pipe are connected through bolts, when the connection is removed, moisture is contained in the condensing pipes and flows out from the joints, so that the condensing pipes are inconvenient; 2) The equipment is cooled by the fan, and the fan is fixed at the moment and only cools the special part, so that the cooling effect is not obvious.

Disclosure of Invention

Aiming at the situation, in order to overcome the defects of the prior art, the invention provides the cooling device for graphene production, which effectively solves the problem that the cooling effect of cooling equipment in the prior art is not obvious.

In order to solve the problems, the cooling device for graphene production comprises a support frame and a furnace body, wherein the furnace body is fixedly connected with the support frame;

the outer circumference of the furnace body is wound with a condensing pipe which is spirally arranged;

the fan which rotates circumferentially is arranged on the supporting frame and swings in the circumferential rotation process.

Preferably, the support frame comprises a support plate, a rotating plate is rotatably arranged on the support plate, a rectangular block horizontally sliding along the rotating plate is arranged on the rotating plate, a gear is rotatably arranged at the upper end of the rectangular block, a rack is fixed at the upper end of the rotating plate, the gear is meshed with the rack, and the rectangular block drives the gear to rotate in the horizontal sliding process;

an expansion plate is fixed at the upper end of the rectangular block, a bottom plate is arranged above the expansion plate, the expansion plate is hinged and fixed with the bottom plate, a threaded rod is coaxially fixed on the gear, a sleeve capable of vertically sliding is connected with the upper end of the threaded rod in a threaded manner, a connecting rod is hinged at the upper end of the sleeve, and the upper end of the connecting rod is hinged and fixed with the bottom plate;

the fan is fixed above the bottom plate.

Preferably, the upper end of the threaded rod penetrates through the expansion plate and is arranged above the expansion plate, and the threaded rod is rotationally connected with the expansion plate.

Preferably, a guide rod is fixed at the upper end of the expansion plate, and the upper end of the guide rod is slidably penetrated through the sleeve.

Preferably, the upper end of the supporting plate is provided with a cam groove, a pulley is slidably arranged in the cam groove, and the upper end of the pulley penetrates through the cam groove and is fixedly connected with the rectangular block.

Preferably, a first spring is fixed on the inner side of the rectangular block, and the inner end of the first spring is fixedly connected with the rotating plate.

Preferably, the inlet and the outlet of the condensing pipe are connected with plug connection equipment, and the plug connection equipment is connected with the water inlet pipe and the water outlet pipe.

Preferably, the plug connection device comprises a first connector fixedly connected with the condenser tube,

the water inlet pipe or the water outlet pipe is connected with the water inlet pipe or the water outlet pipe in a rotating way, and the first connector is connected with the second connector through threads.

Preferably, the first connector is externally provided with external threads, and the second connector is internally provided with internal threads.

Preferably, a conical hole is formed in the first connector, a sliding conical body is arranged in the first connector, and the conical body and the conical hole are matched to form a structure for plugging the first connector;

an inserting rod is fixed in the second connector, the outer end of the inserting rod is arranged at the outer side of the second connector, and the inserting rod is inserted into the first connector to push the conical body to move, so that the first connector is communicated with the second connector.

Preferably, a support is fixed in the first connector, a guide rod is fixed at the end, far away from the second connector, of the conical body, the lower end of the guide rod penetrates through the support in a sliding mode, a second spring is sleeved on the outer circumference of the guide rod, one end of the second spring is fixedly connected with the conical body, and the other end of the second spring is fixedly connected with the support.

Compared with the prior art, the invention has the following advantages: 1) The fan performs circumferential rotation and horizontal sliding and swings in the process, so that the furnace body can be more comprehensively blown to dissipate heat, and the cooling efficiency is improved; 2) In the process of connecting the condensing pipe with the water inlet pipe or the water outlet pipe, plug and play can be realized, and in the process of connecting and dismantling, water cooling liquid of the condensing pipe can be prevented from overflowing.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is a schematic diagram of the overall axial structure of the present invention;

FIG. 3 is a schematic diagram of a structure for driving a fan to move according to the present invention;

FIG. 4 is a schematic diagram of a structure for driving a fan to move along a shaft side of the fan;

FIG. 5 is a schematic view of a plug connection apparatus according to the present invention;

FIG. 6 is a schematic view of the plug connection apparatus of the present invention partially in section;

in the figure: 1. a support frame; 2. a furnace body; 3. a condensing tube; 4. a blower; 5. a support plate; 6. a rotating plate; 7. rectangular blocks; 8. a gear; 9. a rack; 10. an expansion plate; 11. a bottom plate; 12. a threaded rod; 13. a sleeve; 14. a connecting rod; 15. cam grooves; 16. a pulley; 17. a plug connection device; 18. a first connector; 19. a second connector; 20. a cone; 21. an insertion rod; 22. a bracket; 23. a guide rod; 24. and a second spring.

Detailed Description

The invention will now be described in further detail with reference to the accompanying drawings. The drawings are simplified schematic views illustrating the basic structure of the present invention by way of illustration only, and thus show only the constitution related to the present invention.

Referring to fig. 1-6, a cooling device for graphene production comprises a support frame 1 and a furnace body 2, wherein the furnace body 2 is fixedly connected with the support frame 1;

the condensing pipe 3 is wound on the outer circumference of the furnace body 2, and the condensing pipe 3 is spirally arranged;

the fan 4 which rotates circumferentially is arranged on the support frame 1, and the fan 4 swings in the circumferential rotation process.

In the invention, the condensing tube 3, the supporting frame 1 and the furnace body 2 are all of the prior art, and the device does not carry out excessive description;

the fan 4 of this device sets up on support frame 1, dispel the heat to furnace body 2 through fan 4, fan 4 self can produce and rotate, then this device still has an external force drive fan 4 to carry out the rotation of a circumference, at this pivoted in-process, fan 4 can carry out a slip, and at gliding in-process, can also adjust fan 4 wobbling angle, fan 4 that this device frequently sees shakes the head, like this can be better with the different positions of blowing to furnace body 2, thereby carry out even omnidirectional cooling to furnace body 2, play a better cooling effect.

In addition, be connected with the outlet pipe in condenser pipe 3 delivery port department, the outlet pipe can be provided with the goose wing board at the outer circumference, can increase the cooling rate of outlet pipe like this, in the in-process that the cooling water circulated, the cooling water that guarantees that can be better is faster cooled.

The support frame 1 comprises a support plate 5, a rotating plate 6 is rotatably arranged on the support plate 5, a rectangular block 7 horizontally sliding along the rotating plate 6 is arranged on the rotating plate 6, a gear 8 is rotatably arranged at the upper end of the rectangular block 7, a rack 9 is fixed at the upper end of the rotating plate 6, the gear 8 is meshed with the rack 9, and the rectangular block 7 drives the gear 8 to rotate in the horizontal sliding process;

an expansion plate 10 is fixed at the upper end of the rectangular block 7, a bottom plate 11 is arranged above the expansion plate 10, the expansion plate 10 is hinged and fixed with the bottom plate 11, a threaded rod 12 is coaxially fixed on the gear 8, a sleeve 13 which vertically slides is connected with the upper end of the threaded rod 12 in a threaded manner, a connecting rod 14 is hinged at the upper end of the sleeve 13, and the upper end of the connecting rod 14 is hinged and fixed with the bottom plate 11;

the fan 4 is fixed above the bottom plate 11.

In the invention, a driving device is fixed at the lower end of a supporting plate 5, the shaft end of the driving device is connected with a rotating plate 6, the rotating plate 6 is driven to rotate by the driving device, the rotating plate 6 can drive a rectangular block 7 to perform circular motion in the process of performing circular rotation, and a fan 4 is connected with the rectangular block 7, so that the fan 4 can be driven to perform circular rotation;

in addition, the rectangular block 7 can also horizontally slide along the rotating plate 6 in the circumferential rotating process, and the fan 4 can also generate a horizontal sliding effect at the moment;

in addition, in the horizontal sliding process of the rectangular block 7, the threaded rod 12 can be rotated due to the gear 8 and the rack 9, and in the rotating process of the threaded rod 12, the driving sleeve 13 slides, so that the fan 4 is driven to swing.

Like this, fan 4 self rotates, and fan 4 carries out the circumference along with rotating plate 6, carries out horizontal slip at circumference pivoted in-process, and can swing, can carry out comprehensive blowing like this to furnace body 2, cools off furnace body 2 better.

The upper end of the threaded rod 12 penetrates through the expansion plate 10 and is arranged above the expansion plate 10, and the threaded rod 12 is rotatably connected with the expansion plate 10.

The upper end of the threaded rod 12 is rotatably connected with the expansion plate 10, and the threaded rod 12 is supported once.

A guide rod is fixed at the upper end of the expansion plate 10, and the upper end of the guide rod penetrates through the sleeve 13 in a sliding manner.

Under the effect of guide bar to guaranteed the slip effect of sleeve pipe 13, when threaded rod 12 rotated, made sleeve pipe 13 slide, this device utilized threaded connection's auto-lock nature in addition, thereby can guarantee sleeve pipe 13 motion's stability.

The upper end of the supporting plate 5 is provided with a cam groove 15, a pulley 16 is slidably arranged in the cam groove 15, and the upper end of the pulley 16 penetrates through the cam groove 15 and is fixedly connected with the rectangular block 7.

In the present invention, when the rotating plate 6 rotates, the pulley 16 slides along the cam groove 15, and the rectangular block 7 is driven to slide.

The track shape of the cam groove 15 may be an ellipse or an irregular shape other than a circle.

The inner side of the rectangular block 7 is fixedly provided with a first spring, and the inner end of the first spring is fixedly connected with the rotating plate 6.

The first spring acts to ensure stability of the rectangular block 7.

The inlet and the outlet of the condensing tube 3 are connected with a plug connection device 17, and the plug connection device 17 is connected with a water inlet pipe and a water outlet pipe.

The plug connection device 17 comprises a first connection head 18 fixedly connected to the condenser tube 3,

the water inlet pipe or the water outlet pipe is rotatably connected with the first connector 18, and the second connector 19 is connected with the first connector 18 through threads.

The first connector 18 is externally provided with external threads, and the second connector 19 is internally provided with internal threads.

In the invention, the first connector 18 and the second connector 19 are connected together through threads, so that the two connectors are integrated, and the threaded connection has a good self-locking effect and ensures stability.

The first connector 18 is internally provided with a conical hole, the first connector 18 is internally provided with a sliding conical body 20, and the conical body 20 and the conical hole are matched to form a structure for sealing the first connector 18;

an insertion rod 21 is fixed in the second connector 19, the outer end of the insertion rod 21 is arranged at the outer side of the second connector 19, the outer end part of the insertion rod 21 protrudes out of the second connector 19, and the insertion rod 21 is inserted into the first connector 18 to push the cone 20 to move, so that the first connector 18 and the second connector 19 are communicated.

In the present invention, the small end of the tapered hole is near the second connector 19, when the tapered body 20 is inserted into the tapered hole to seal the tapered hole, a seal of the first connector 18 can be formed, and the first connector 18 is not connected;

when the first connector 18 and the second connector 19 are in threaded fit, the insertion rod 21 is not in contact with the conical body 20, when the first connector 18 and the connectors are connected with three wires, the insertion rod 21 is in contact with the conical body 20, then the second connector 19 is rotated, at the moment, the insertion rod 21 is continuously inserted into the first connector 18, so that the conical body 20 is matched with the conical hole, at the moment, the first connector 18 and the second connector 19 are communicated, the liquid in the condenser tube 3 can be prevented from overflowing in the whole process, the sealing effect of the condenser tube 3 can be guaranteed in the dismantling process, and the plugging effect after the dismantling is realized.

The first connector 18 is internally fixed with a support 22, the end of the conical body 20 far away from the second connector 19 is fixed with a guide rod 23, the lower end of the guide rod 23 is slidably penetrated through the support 22, the outer circumference of the guide rod 23 is sleeved with a second spring 24, one end of the second spring 24 is fixedly connected with the conical body 20, and the other end of the second spring 24 is fixedly connected with the support 22.

In the invention, the second spring 24 pushes the cone 20 to move towards the direction approaching the second connector 19, so that the cone 20 seals the conical hole, and the guide rod 23 plays a guiding role to ensure the sliding effect of the cone 20.

The examples are given solely for the purpose of clarity of illustration and are not intended to be limiting of the embodiments. Other variations or modifications of the above teachings will be apparent to those of ordinary skill in the art. It is not necessary here nor is it exhaustive of all embodiments. While still being apparent from variations or modifications that may be made by those skilled in the art are within the scope of the invention.

Claims (7)

1. The cooling device for graphene production comprises a support frame (1) and a furnace body (2), wherein the furnace body (2) is fixedly connected with the support frame (1);

the condensing pipe (3) is wound on the outer circumference of the furnace body (2), and the condensing pipe (3) is spirally arranged; it is characterized in that the method comprises the steps of,

a fan (4) which rotates circumferentially is arranged on the support frame (1), and the fan (4) swings in the circumferential rotation process;

the support frame (1) comprises a support plate (5), a rotating plate (6) is rotatably arranged on the support plate (5), a rectangular block (7) horizontally sliding along the rotating plate (6) is arranged on the rotating plate (6), a gear (8) is rotatably arranged at the upper end of the rectangular block (7), a rack (9) is fixed at the upper end of the rotating plate (6), the gear (8) is meshed with the rack (9), and the rectangular block (7) drives the gear (8) to rotate in the horizontal sliding process;

an expansion plate (10) is fixed at the upper end of the rectangular block (7), a bottom plate (11) is arranged above the expansion plate (10), the expansion plate (10) is hinged and fixed with the bottom plate (11), a threaded rod (12) is coaxially fixed on the gear (8), a sleeve (13) which vertically slides is connected with the upper end of the threaded rod (12) in a threaded manner, a connecting rod (14) is hinged at the upper end of the sleeve (13), and the upper end of the connecting rod (14) is hinged and fixed with the bottom plate (11);

the fan (4) is fixed above the bottom plate (11);

the upper end of the supporting plate (5) is provided with a cam groove (15), a pulley (16) is slidably arranged in the cam groove (15), and the upper end of the pulley (16) penetrates through the cam groove (15) to be fixedly connected with the rectangular block (7);

the track shape of the cam groove (15) is an irregular shape other than a circle.

2. The cooling device for graphene production according to claim 1, wherein a guide rod is fixed at the upper end of the expansion plate (10), and a penetrating sleeve (13) with the upper end being slidable is fixed at the upper end of the guide rod.

3. The cooling device for graphene production according to claim 1, wherein a first spring is fixed on the inner side of the rectangular block (7), and the inner end of the first spring is fixedly connected with the rotating plate (6).

4. The cooling device for graphene production according to claim 1, wherein the inlet and the outlet of the condenser tube (3) are connected with a plug connection device (17), and the plug connection device (17) is connected with a water inlet tube and a water outlet tube;

the plug connection device (17) comprises a first connector (18) fixedly connected with the condenser tube (3),

the water inlet pipe or the water outlet pipe is rotatably connected with the first connecting head (18) and the second connecting head (19) through threads.

5. The cooling device for graphene production according to claim 4, wherein the first connector (18) is externally provided with external threads, and the second connector (19) is internally provided with internal threads.

6. The cooling device for graphene production according to claim 5, wherein a tapered hole is formed in the first connector (18), a sliding cone (20) is arranged in the first connector (18), and the cone (20) and the tapered hole are matched to form a structure for plugging the first connector (18);

an inserting rod (21) is fixed in the second connector (19), the outer end of the inserting rod (21) is arranged on the outer side of the second connector (19), and the inserting rod (21) is inserted into the first connector (18) to push the conical body (20) to move, so that the first connector (18) and the second connector (19) are communicated.

7. The cooling device for graphene production according to claim 6, wherein a support (22) is fixed in the first connector (18), a guide rod (23) is fixed at the end, far away from the second connector (19), of the conical body (20), the lower end of the guide rod (23) is slidably penetrated through the support (22), a second spring (24) is sleeved on the outer circumference of the guide rod (23), one end of the second spring (24) is fixedly connected with the conical body (20), and the other end of the second spring (24) is fixedly connected with the support (22).