CN212687573U - Graphite alkene collection device pottery pipe cooling cycle device - Google Patents

Abstract

The utility model relates to a graphite alkene collection device technical field discloses graphite alkene collection device ceramic pipe cooling cycle device, including high temperature ceramic pipe, fixed the cup jointing has the cooling cavity on the outer pipe wall that high temperature ceramic pipe is close to mouth of pipe position, and refrigerant import hole and refrigerant outlet hole have been seted up to the symmetry on the both sides chamber wall that high temperature ceramic pipe was kept away from to the cooling cavity, installs filter mechanism in the refrigerant import hole, and fixedly connected with guide plate in the cooling cavity is connected with on the cooling cavity and spouts the chamber, spouts chamber and high temperature ceramic pipe and is linked together, and spouts the one end center department that the chamber kept away from high temperature ceramic pipe and be equipped with the. The utility model provides the high radiating effect to ceramic pipe satisfies ceramic pipe's cooling demand, ensures graphite alkene collection device's normal work, has improved graphite alkene collection device's work efficiency, simple structure moreover, and the processing degree of difficulty is low, simple to operate, and the maintenance cost is low, and heat exchange efficiency is high, has guaranteed the long-term stable work of cooling cycle device.

Description

Graphite alkene collection device pottery pipe cooling cycle device

Technical Field

The utility model relates to a graphite alkene collection device technical field especially relates to graphite alkene collection device ceramic pipe cooling cycle device.

Background

Graphene (Graphene) is a two-dimensional carbon nanomaterial consisting of carbon atoms in a hexagonal honeycomb lattice with sp2 hybridized orbitals. The graphene has excellent optical, electrical and mechanical properties, has important application prospects in the aspects of materials science, micro-nano processing, energy, biomedicine, drug delivery and the like, and is considered to be a revolutionary material in the future. Graphene is a two-dimensional carbon nano material, and the expanded graphite mechanical stripping method is the mainstream production method, so that the production cost is low, and the environmental pollution is small. The ceramic tube is an important structural component in the graphene collecting device, and along with the increase of service time, the temperature of the ceramic tube can rise rapidly, the heat dissipation effect of the ceramic tube is poor at present, the ceramic tube at high temperature can directly influence the normal work of the graphene collecting device, and the work efficiency of the graphene collecting device is reduced.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving among the prior art along with the increase of live time, the temperature of ceramic pipe can rise rapidly, and ceramic pipe radiating effect is not good at present, and the ceramic pipe under the high temperature can direct influence graphite alkene collection device's normal work, reduces graphite alkene collection device work efficiency's problem, and the graphite alkene collection device ceramic pipe cooling cycle device that provides.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

graphite alkene collection device ceramic pipe cooling cycle device, including high temperature ceramic pipe, the fixed cover of high temperature ceramic pipe is close to the outer pipe wall of mouth of pipe position and has been connect the cooling cavity, refrigerant inlet hole and refrigerant outlet hole have been seted up to the symmetry on the both sides chamber wall that high temperature ceramic pipe was kept away from to the cooling cavity, install filtering mechanism in the refrigerant inlet hole, fixedly connected with guide plate in the cooling cavity, be connected with on the cooling cavity and spout the chamber, spout chamber and high temperature ceramic pipe and be linked together, and spout the one end center department that high temperature ceramic pipe was kept away from in the chamber and be equipped with the nozzle.

Preferably, filtering mechanism includes the filter screen and is the support frame of "ten" style of calligraphy, support frame and filter screen be fixed connection in proper order on the pore wall in refrigerant import hole, the support frame sets up between guide plate and filter screen, the drive opening has been seted up to the center department of support frame, fixedly connected with bearing on the interior pore wall in drive opening, fixedly connected with drive shaft on the inner circle wall of bearing, and the both ends of drive shaft pass bearing and drive opening in proper order and outwards extend, the drive shaft is close to the one end fixedly connected with cleaning brush of filter screen, the brush hair of cleaning brush sets up on the filter screen, the one end fixedly connected with turbine fan blade of cleaning brush is kept away from to the drive shaft.

Preferably, the spraying cavity is connected with the cooling cavity through two symmetrically arranged fixing bolts.

Preferably, two sealing rings are arranged between the driving hole and the driving shaft, the two sealing rings are fixedly connected to the hole wall of the driving hole, and the two sealing rings are symmetrically arranged around the bearing.

Preferably, the cleaning brush is in a long strip shape, the side walls of the two ends of the cleaning brush are symmetrically and fixedly connected with sliding blocks, an annular sliding groove is formed in the position, corresponding to the two sliding blocks, of the refrigerant inlet hole, and the two sliding blocks are connected in the sliding groove in a sliding mode.

Preferably, the shaft wall of the driving shaft is symmetrically and fixedly connected with reinforcing rods which are obliquely arranged, and one ends of the reinforcing rods, far away from the driving shaft, are fixedly connected to one ends of the cleaning brushes, far away from the filter screen.

Preferably, a rolling groove is formed in one end, away from the cleaning brush, of the sliding block, rolling balls are arranged in the rolling groove, the balls penetrate through notches of the rolling groove, and the balls are connected to the bottom of the sliding groove in a rolling mode.

Preferably, the ball has a ball diameter larger than a groove diameter of the rolling groove opening.

Preferably, the cooling cavity is made of a heat conducting material.

Compared with the prior art, the utility model provides a graphite alkene collection device ceramic pipe cooling cycle device possesses following beneficial effect:

1. this graphite alkene collection device pottery pipe cooling cycle device, through setting up high temperature ceramic pipe, the cooling cavity, the refrigerant import hole, the refrigerant outlet hole, the guide plate, spout chamber and nozzle, in the refrigerant gets into the cooling cavity through the refrigerant import hole, cool down high temperature ceramic pipe, the refrigerant after the absorbed heat passes through refrigerant outlet hole discharge cooling cavity again, improve the radiating effect to ceramic pipe, satisfy the cooling demand of ceramic pipe, ensure graphite alkene collection device's normal work, the work efficiency of graphite alkene collection device has been improved, moreover, the steam generator is simple in structure, the processing degree of difficulty is low, high durability and convenient installation, the maintenance cost is low, and the heat exchange efficiency is high.

2. This graphite alkene collection device pottery pipe cooling cycle device, through setting up the filter screen, the support frame, the bearing, the drive shaft, a filter mechanism is constituteed to cleaning brush and turbine fan blade, filter the refrigerant of process through the filter screen, block impurity on the filter screen, the refrigerant is in the refrigerant inlet during through turbine fan blade, turbine fan blade atress drives the drive shaft at the bearing internal rotation, and then drive cleaning brush and rotate on the filter screen, clean the filter screen, prevent that the impurity that the filter screen blocked from leading to the fact the jam to the filter screen, the long-term stable work of cooling cycle device has been guaranteed.

The device does not relate to the part and all is the same with prior art or can adopt prior art to realize, the utility model provides the high radiating effect to ceramic tube satisfies ceramic tube's cooling demand, ensures graphite alkene collection device's normal work, has improved graphite alkene collection device's work efficiency, simple structure moreover, and the processing degree of difficulty is low, simple to operate, and the maintenance cost is low, and heat exchange efficiency is high, has guaranteed the long-term stable work of cooling cycle device.

Drawings

Fig. 1 is a schematic structural view of a ceramic tube cooling circulation device of a graphene collecting device according to the present invention;

FIG. 2 is an enlarged view of portion A of FIG. 1;

FIG. 3 is an enlarged view of portion B of FIG. 2;

fig. 4 is an enlarged view of a portion C in fig. 2.

In the figure: 1 high-temperature ceramic tube, 2 cooling cavities, 3 refrigerant inlet holes, 4 refrigerant outlet holes, 5 flow guide plates, 6 spray cavities, 7 spray nozzles, 8 filter screens, 9 support frames, 10 bearings, 11 driving shafts, 12 cleaning brushes, 13 turbine fan blades, 14 fixing bolts, 15 sealing rings, 16 sliding blocks, 17 sliding grooves, 18 reinforcing rods, 19 rolling grooves and 20 balls.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention.

Referring to fig. 1-4, a graphene collecting device ceramic tube cooling circulation device comprises a high-temperature ceramic tube 1, a cooling cavity 2 is fixedly sleeved on the outer tube wall of the high-temperature ceramic tube 1 close to the tube opening, a refrigerant inlet hole 3 and a refrigerant outlet hole 4 are symmetrically formed on the two side wall surfaces of the cooling cavity 2 far away from the high-temperature ceramic tube 1, the refrigerant inlet hole 3, the refrigerant outlet hole 4, the cooling cavity 2 and an external refrigeration device form a circulation loop, a filtering mechanism is installed in the refrigerant inlet hole 3, a flow guide plate 5 is fixedly connected in the cooling cavity 2, a spray cavity 6 is connected on the cooling cavity 2, the spray cavity 6 is communicated with the high-temperature ceramic tube 1, a nozzle 7 is arranged at the center of one end of the spray cavity 6 far away from the high-temperature ceramic tube 1, the whole circulation device is made of stainless steel materials, and is polished inside and outside, so that the corrosion, in refrigerant process refrigerant import hole 3 got into cooling cavity 2, cool down high temperature ceramic pipe 1, the refrigerant after the absorbed heat passes through refrigerant outlet hole 4 discharge cooling cavity 2 again, improves the radiating effect to ceramic pipe, satisfies ceramic pipe's cooling demand, ensures graphite alkene collection device's normal work, has improved graphite alkene collection device's work efficiency, simple structure moreover, the processing degree of difficulty is low, simple to operate, the maintenance cost is low, and heat exchange efficiency is high.

The filtering mechanism comprises a filtering net 8 and a cross-shaped supporting frame 9, the supporting frame 9 and the filtering net 8 are sequentially and fixedly connected on the wall of a refrigerant inlet hole 3, the supporting frame 9 is arranged between a guide plate 5 and the filtering net 8, a driving hole is arranged at the center of the supporting frame 9, a bearing 10 is fixedly connected on the inner wall of the driving hole, a driving shaft 11 is fixedly connected on the inner ring wall of the bearing 10, two ends of the driving shaft 11 sequentially penetrate through the bearing 10 and the driving hole and extend outwards, a cleaning brush 12 is fixedly connected at one end of the driving shaft 11 close to the filtering net 8, bristles of the cleaning brush 12 are arranged on the filtering net 8, a turbine fan blade 13 is fixedly connected at one end of the driving shaft 11 far away from the cleaning brush 12, the passing refrigerant is filtered by the filtering net 8, impurities are blocked on the filtering net 8, when the refrigerant passes through the turbine fan blade 13 in the refrigerant inlet hole 3, the turbine, and then drive cleaning brush 12 and rotate on filter screen 8, clean filter screen 8, prevent that the impurity that filter screen 8 blocked from causing the jam to filter screen 8, guaranteed the long-term stable work of cooling cycle device.

The spray cavity 6 is connected with the cooling cavity 2 through two symmetrically arranged fixing bolts 14, and the cooling cavity 2 and the spray cavity 6 are detachably connected through the fixing bolts 14.

Be equipped with two sealing washer 15 between drive hole and the drive shaft 11, two sealing washer 15 fixed connection are on the pore wall of drive hole, and two sealing washer 15 set up about bearing 10 symmetry, prevent that the refrigerant from contacting with bearing 10, have improved the life of refrigerant.

Cleaning brush 12 is rectangular form, and symmetry fixedly connected with slider 16 on the both ends lateral wall of cleaning brush 12, and annular spout 17 has been seted up to refrigerant import hole 3 corresponding two slider 16's position, and two common sliding connection of slider 16 are in spout 17, and cleaning brush 12 atress takes place to drive slider 16 synchronous rotation in spout 17 when rotating, and is spacing to cleaning brush 12's rotation direction for cleaning brush 12 atress pivoted is more stable.

The reinforcing rods 18 which are obliquely arranged are symmetrically and fixedly connected to the shaft wall of the driving shaft 11, one end, far away from the driving shaft 11, of each reinforcing rod 18 is fixedly connected to one end, far away from the filter screen 8, of the cleaning brush 12, and the reinforcing rods 18, the driving shaft 11 and the cleaning brush 12 form a triangular area, so that the stability of the cleaning brush 12 is improved.

The rolling groove 19 has been seted up to the one end of slider 16 far away from cleaning brush 12, is equipped with rolling ball 20 in the rolling groove 19, and ball 20 passes the notch setting of rolling groove 19, and ball 20 roll connection is at the tank bottom of spout 17, and slider 16 atress drives ball 20 in the rolling groove 19 and rolls in spout 17 when rotating in spout 17 for cleaning brush 12 motion reduces the frictional force when slider 16 rotates in spout 17 more stably.

The ball 20 has a larger spherical diameter than the groove diameter of the notch of the rolling groove 19, preventing the ball 20 from slipping out of the rolling groove 19.

The cooling cavity 2 is made of heat conducting materials and is easy to dissipate heat.

In the utility model, the refrigerant enters the cooling cavity 2 through the refrigerant inlet hole 3, cools the high-temperature ceramic tube 1, and the refrigerant absorbing heat is discharged out of the cooling cavity 2 through the refrigerant outlet hole 4, so that the heat dissipation effect of the ceramic tube is improved, the cooling requirement of the ceramic tube is met, the normal work of the graphene collecting device is ensured, the work efficiency of the graphene collecting device is improved, the structure is simple, the processing difficulty is low, the installation is convenient, the maintenance cost is low, and the heat exchange efficiency is high; through filter screen 8 to the refrigerant of process, stop impurity on filter screen 8, when the refrigerant passes through turbine blade 13 in refrigerant inlet hole 3, turbine blade 13 atress drives drive shaft 11 at bearing 10 internal rotation, and then drives cleaning brush 12 and rotate on filter screen 8, cleans filter screen 8, prevents that the impurity that filter screen 8 stopped from causing the jam to filter screen 8, has guaranteed the long-term stable work of cooling cycle device.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (9)

1. Graphite alkene collection device ceramic pipe cooling cycle device, including high temperature ceramic pipe (1), its characterized in that, fixed the cup jointing has cooling cavity (2) on the outer pipe wall that high temperature ceramic pipe (1) is close to the mouth of pipe position, cooling cavity (2) are kept away from on the both sides chamber wall of high temperature ceramic pipe (1) the symmetry and have been seted up refrigerant import hole (3) and refrigerant outlet hole (4), install filter mechanism in refrigerant import hole (3), fixedly connected with guide plate (5) in cooling cavity (2), be connected with on cooling cavity (2) and spout chamber (6), spout chamber (6) and high temperature ceramic pipe (1) and be linked together, and spout chamber (6) and keep away from the one end center department of high temperature ceramic pipe (1) and be equipped with nozzle (7).

2. The graphene collecting device ceramic tube cooling and circulating device according to claim 1, wherein the filtering mechanism comprises a filtering net (8) and a cross-shaped supporting frame (9), the supporting frame (9) and the filtering net (8) are sequentially and fixedly connected to the wall of a refrigerant inlet hole (3), the supporting frame (9) is arranged between the guide plate (5) and the filtering net (8), a driving hole is formed in the center of the supporting frame (9), a bearing (10) is fixedly connected to the inner wall of the driving hole, a driving shaft (11) is fixedly connected to the inner ring wall of the bearing (10), two ends of the driving shaft (11) sequentially penetrate through the bearing (10) and the driving hole and extend outwards, a cleaning brush (12) is fixedly connected to one end of the driving shaft (11) close to the filtering net (8), and bristles of the cleaning brush (12) are arranged on the filtering net (8), one end of the driving shaft (11) far away from the cleaning brush (12) is fixedly connected with a turbine fan blade (13).

3. The graphene collection device ceramic tube cooling circulation device according to claim 1, wherein the spray chamber (6) is connected with the cooling chamber (2) through two symmetrically arranged fixing bolts (14).

4. The graphene collecting device ceramic pipe cooling circulation device according to claim 2, wherein two sealing rings (15) are arranged between the driving hole and the driving shaft (11), the two sealing rings (15) are fixedly connected to the wall of the driving hole, and the two sealing rings (15) are symmetrically arranged about the bearing (10).

5. The graphene collecting device ceramic tube cooling and circulating device according to claim 2, wherein the cleaning brush (12) is long, sliding blocks (16) are symmetrically and fixedly connected to side walls of two ends of the cleaning brush (12), an annular sliding groove (17) is formed in the position, corresponding to the two sliding blocks (16), of the refrigerant inlet hole (3), and the two sliding blocks (16) are jointly slidably connected in the sliding groove (17).

6. The graphene collecting device ceramic pipe cooling and circulating device according to claim 2, wherein reinforcing rods (18) are symmetrically and fixedly connected to the shaft wall of the driving shaft (11) and are obliquely arranged, and one ends of the reinforcing rods (18) far away from the driving shaft (11) are fixedly connected to one ends of the cleaning brushes (12) far away from the filter screen (8).

7. The graphene collecting device ceramic tube cooling and circulating device according to claim 5, wherein a rolling groove (19) is formed in one end, away from the cleaning brush (12), of the sliding block (16), a rolling ball (20) is arranged in the rolling groove (19), the rolling ball (20) penetrates through a notch of the rolling groove (19), and the rolling ball (20) is connected to the bottom of the sliding groove (17) in a rolling mode.

8. The graphene collecting device ceramic tube cooling cycle device according to claim 7, wherein a spherical diameter of the ball (20) is larger than a groove diameter of a notch of the rolling groove (19).

9. The graphene collecting device ceramic pipe cooling circulation device according to claim 1, wherein the temperature reduction cavity (2) is made of a heat conducting material.

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