CN220981810U - Hot air drying device for graphene - Google Patents

Abstract

The utility model relates to the technical field of hot air drying, and discloses a graphene hot air drying device, which comprises a drying box, supporting legs fixedly connected to the outer wall of the drying box, and a drying and dehumidifying mechanism arranged in the drying box and at the top end, wherein the drying and dehumidifying mechanism comprises a drying mechanism arranged in the drying box, a dehumidifying mechanism is arranged on one side of the drying mechanism, a starting motor drives a telescopic connecting rod to rotate, a first connecting stirring blade and a second connecting stirring blade are driven to rotate through rotation of the telescopic connecting rod, meanwhile, the telescopic connecting rod rotates to drive a thread groove to rotate, the telescopic connecting rod is driven to move up and down through threaded connection of the thread groove and a threaded sleeve to drive the second connecting stirring blade to move up and down, the stirring range of the graphene hot air drying device is improved, hot air is transmitted to the first connecting stirring blade and the second connecting stirring blade through starting a hot air blower, and finally, the drying operation is completed through spraying of a spraying air pipe.

Description

A hot air drying device for graphene

Technical Field

The utility model relates to the technical field of hot air drying, in particular to a hot air drying device for graphene.

Background technique

Graphene is a two-dimensional carbon nanomaterial composed of carbon atoms in a hexagonal honeycomb lattice with sp2 hybrid orbitals. Graphene has excellent optical, electrical and mechanical properties, and has important application prospects in materials science, micro-nano processing, energy, biomedicine and drug delivery, and is considered to be a revolutionary material of the future.

In the preparation process of graphene, it is often necessary to dry it before it can be collected. However, the existing graphene drying equipment does not have a mechanism to stir and turn it when air-drying it. In this way, drying the graphene in a static state will lead to insufficient drying, so it is necessary to extend the drying time or perform the drying work multiple times, which will reduce the efficiency of the drying work and increase the cost of the drying work.

Utility Model Content

The utility model aims to provide a hot air drying device for graphene, which solves the problem that in the preparation process of graphene, it is often necessary to dry the graphene before collecting it. However, the existing graphene drying equipment does not have a mechanism to stir and turn the graphene when air-drying it. In this way, drying the graphene in a static state will lead to insufficient drying, so it is necessary to extend the drying time or perform the drying work multiple times, which will reduce the efficiency of the drying work and increase the cost of the drying work.

To achieve the above-mentioned purpose, the utility model provides the following technical solutions: a hot air drying device for graphene, comprising a drying box;

Support legs fixedly connected to the outer wall of the drying box;

The invention also comprises a drying and dehumidifying mechanism arranged inside and at the top of the drying box. The drying and dehumidifying mechanism comprises a drying mechanism installed inside the drying box, and a dehumidifying mechanism is installed on one side of the drying mechanism.

Preferably, the drying mechanism treasure house is fixedly connected to a fixed frame at the top of the drying box, the bottom end of the fixed frame is fixedly connected to a motor, the output end of the motor is fixedly connected to a telescopic connecting rod, the outer wall of the telescopic connecting rod is provided with a connecting hole, the outer wall of the telescopic connecting rod is connected and rotatably connected with a rotating sleeve, the outer wall of the rotating sleeve is connected with a first air duct, the first air duct is connected with a hot air blower at one end away from the rotating sleeve, the bottom end of the hot air blower is fixedly connected to the top of the drying box, the outer wall of the telescopic connecting rod is connected with a first connecting stirring blade, the outer wall of the telescopic connecting rod is located below the first connecting stirring blade and is connected with a connecting plate, the bottom end of the connecting plate is connected with a second connecting stirring blade, the outer walls of the first connecting stirring blade and the second connecting stirring blade are both connected with an air spray pipe, and the outer wall of the bottom end of the telescopic connecting rod is provided with a threaded groove. The outer wall of the threaded groove is threadedly connected with a threaded sleeve, and the bottom end of the threaded sleeve is fixedly connected to the bottom end of the inner wall of the drying box. By starting the motor in the drying mechanism to rotate forward and reverse, the telescopic connecting rod can be driven to rotate, and the rotation of the telescopic connecting rod can drive the first connected stirring blade and the second connected stirring blade to rotate, so as to stir and tumble the graphene. At the same time, the rotation of the telescopic connecting rod will drive the threaded groove to rotate, and the threaded groove can be threadedly connected to the threaded sleeve through rotation, so as to drive the telescopic connecting rod to move up and down, thereby driving the second connected stirring blade to move up and down, thereby increasing its stirring range, and by starting the hot air blower, hot air can be transmitted to the telescopic connecting rod through the first air supply pipe, and then transmitted to the first connected stirring blade and the second connected stirring blade, and finally sprayed out through the air spray pipe to complete the drying work.

Preferably, the dehumidification mechanism includes a suction pump fixedly connected to the top of the drying box, a suction pipe is provided on the outer wall of the suction pump, an end of the suction pipe away from the suction pump is connected to the top of the drying box, an end of the suction pump away from the suction pipe is connected to a dehumidification box, a condensation grid is fixedly connected to the inner wall of the dehumidification box, an end of the dehumidification box away from the suction pump is connected to a second air duct, an end of the second air duct away from the dehumidification box is connected to the outer wall of the drying box, and a drain pipe is provided at the bottom end of the dehumidification box. By starting the suction pump in the dehumidification mechanism, the water vapor in the drying box can be sucked out through the suction pipe and then transmitted to the dehumidification box. The water vapor in the hot air can be condensed into water droplets through the condensation grid, so that the water vapor in the hot air can be removed, and the dehumidified hot air will be transmitted back to the drying box through the second air duct, so that the cycle can complete the elimination of water vapor.

Preferably, the number of the connecting holes is five, and the connecting holes are evenly distributed on the outer wall of the telescopic connecting rod.

Preferably, the number of the first connecting stirring blades is four, the number of the second connecting stirring blades is four, and the first connecting stirring blades and the second connecting stirring blades form a group of two and are distributed on the outer wall of the telescopic connecting rod in a symmetrical structure.

Preferably, the inner wall of the rotating sleeve is matched with the outer wall of the telescopic connecting rod.

Preferably, the outer wall of the condensation grid is matched with the inner wall of the dehumidification box.

The utility model provides a hot air drying device for graphene. The hot air drying device for graphene has the following beneficial effects:

(1) The hot air drying device for graphene can drive the telescopic connecting rod to rotate by starting the motor in the drying mechanism to rotate forward and reversely, and the rotation of the telescopic connecting rod can drive the first connected stirring blade and the second connected stirring blade to rotate, so as to stir and tumble the graphene. At the same time, the rotation of the telescopic connecting rod will drive the thread groove to rotate, and the thread groove can be threadedly connected with the thread sleeve through rotation, so as to drive the telescopic connecting rod to move up and down, thereby driving the second connected stirring blade to move up and down, thereby increasing its stirring range. By starting the hot air blower, hot air can be transmitted to the telescopic connecting rod through the first air supply pipe, and then transmitted to the first connected stirring blade and the second connected stirring blade, and finally sprayed out through the spray pipe to complete the drying work;

(2) The graphene hot air drying device can start the suction pump in the dehumidification mechanism to suck out the water vapor in the drying box through the suction tube, and then transfer it to the dehumidification box. The water vapor in the hot air can be condensed into water droplets through the condensation grid, so that the water vapor in the hot air can be removed. The hot air with moisture removed will be transferred back to the drying box through the second air duct. This cycle can complete the elimination of water vapor.

BRIEF DESCRIPTION OF THE DRAWINGS

Figure 1 is a schematic diagram of the overall structure of the utility model;

FIG2 is a schematic diagram of the internal cross-sectional structure of the drying box of the utility model;

FIG3 is a schematic diagram of the structure of the stirring and air-drying mechanism of the utility model;

FIG4 is a schematic diagram of the structure of the dehumidification mechanism of the utility model.

In the figure: 1. drying box; 2. supporting legs; 3. drying and dehumidifying mechanism; 31. drying mechanism; 311. fixing frame; 312. motor; 313. telescopic connecting rod; 314. connecting hole; 315. rotating sleeve; 316. first air duct; 317. hot air blower; 318. first connecting stirring blade; 319. air spray pipe; 3110. connecting plate; 3111. second connecting stirring blade; 3112. threaded groove; 3113. threaded sleeve; 32. dehumidifying mechanism; 321. suction pipe; 322. suction pump; 323. dehumidifying box; 324. condensate grid; 325. second air duct; 326. drain pipe.

Detailed ways

Example 1

As shown in Figures 1-4, the utility model provides a technical solution: a hot air drying device for graphene, comprising a drying box 1, a supporting leg 2 fixedly connected to the outer wall of the drying box 1, and a drying and dehumidifying mechanism 3 arranged inside and at the top of the drying box 1, the drying and dehumidifying mechanism 3 comprising a drying mechanism 31 installed inside the drying box 1, a dehumidifying mechanism 32 installed on one side of the drying mechanism 31, the drying mechanism 31 is fixedly connected to a fixed frame 311 at the top of the drying box 1, a motor 312 is fixedly connected to the bottom end of the fixed frame 311, a telescopic connecting rod 313 is fixedly connected to the output end of the motor 312, a connecting hole 314 is opened on the outer wall of the telescopic connecting rod 313, the number of the connecting holes 314 is five, and the connecting holes 314 are evenly distributed on the outer wall of the telescopic connecting rod 313, the outer wall of the telescopic connecting rod 313 is connected and rotatably connected to a rotating sleeve 315, and the inner wall of the rotating sleeve 315 is connected to the telescopic connecting rod 313 The outer wall of the rod 313 is adapted to each other, and the outer wall of the rotating sleeve 315 is connected to a first air duct 316. The first air duct 316 is connected to a hot air blower 317 at one end away from the rotating sleeve 315. The bottom end of the hot air blower 317 is fixedly connected to the top of the drying box 1. The outer wall of the telescopic connecting rod 313 is connected to a first connecting stirring blade 318. The telescopic connecting rod 313 is located below the first connecting stirring blade 318 and is connected to a connecting plate 3110 on the outer wall. The bottom end of the connecting plate 3110 is connected to a second connecting stirring blade 3111. The outer walls of the first connecting stirring blade 318 and the second connecting stirring blade 3111 are both connected to an air injection pipe 319. The number of the first connecting stirring blade 318 is four, and the number of the second connecting stirring blade 3111 is four. The first connecting stirring blade 318 and the second connecting stirring blade 3111 are a group of two and are symmetrically distributed on the outer wall of the telescopic connecting rod 313. A threaded groove 3112 is provided on the outer wall of the bottom end of the connecting rod 313, and a threaded sleeve 3113 is threadedly connected to the outer wall of the threaded groove 3112. The bottom end of the threaded sleeve 3113 is fixedly connected to the bottom end of the inner wall of the drying box 1. First, the graphene material is put into the drying box 1 through the feeding pipe connected to the top of the drying box 1, and then the motor 312 and the hot air blower 317 can be turned on at the same time. The output end of the motor 312 will drive the telescopic connecting rod 313 to rotate. When the telescopic connecting rod 313 rotates, it can drive the first connecting stirring blade 318 and the second connecting stirring blade 3111 connected to its outer wall to rotate, thereby stirring and turning the graphene material. At the same time, the hot air blower 317 will generate hot air, and then the hot air is transmitted to the rotating sleeve 315 through the first air duct 316 connected to its outer wall, and then through the connecting hole 314 opened on the outer wall of the telescopic connecting rod 313 The hot air is transmitted into the first connected stirring blade 318 and the second connected stirring blade 3111, and finally the hot air is ejected through the air jet pipe 319 connected to the outer walls of the two stirring blades, so that the graphene material can be stirred and tumbled while being dried with hot air. At the same time, when the telescopic connecting rod 313 rotates, the thread groove 3112 can also be driven to rotate. When the thread groove 3112 rotates, it can be threadedly rotated with the threaded sleeve 3113, so that the telescopic connecting rod 313 can be driven to move upward, so that the second connected stirring blade 3111 can be driven to move upward, and the starting motor 312 can be reversed to drive the second connected stirring blade 3111 to move downward, so that the second connected stirring blade 3111 can move up and down, thereby increasing its stirring range, so that the graphene can be fully dried with hot air and the drying efficiency is improved.

In this embodiment, by starting the motor 312 in the drying mechanism 31 for forward and reverse rotation, the telescopic connecting rod 313 can be driven to rotate, and the rotation of the telescopic connecting rod 313 can drive the first connecting stirring blade 318 and the second connecting stirring blade 3111 to rotate, thereby stirring and tumbling the graphene. At the same time, the rotation of the telescopic connecting rod 313 will drive the thread groove 3112 to rotate, and the thread groove 3112 can be threadedly connected to the threaded sleeve 3113 through rotation, thereby driving the telescopic connecting rod 313 to move up and down, thereby driving the second connecting stirring blade 3111 to move up and down, thereby increasing its stirring range, and by starting the hot air blower 317, hot air can be transmitted to the telescopic connecting rod 313 through the first air duct 316, and then transmitted to the first connecting stirring blade 318 and the second connecting stirring blade 3111, and finally sprayed out through the air spray pipe 319 to complete the drying work.

Example 2

On the basis of Example 1, a preferred embodiment of the hot air drying device for graphene provided by the utility model is as follows: the dehumidification mechanism 32 includes a suction pump 322 fixedly connected to the top of the drying box 1, the outer wall of the suction pump 322 is connected to a suction pipe 321, the suction pipe 321 is connected to the top of the drying box 1 away from the suction pump 322, the suction pump 322 is connected to the end of the suction pipe 321 away from the dehumidification box 323, the inner wall of the dehumidification box 323 is fixedly connected to a condensation grille 324, the outer wall of the condensation grille 324 is adapted to the inner wall of the dehumidification box 323, the dehumidification box 323 is connected to the end away from the suction pump 322 with a second air duct 325, the second air duct 325 is away from the dehumidification box One end of 323 is connected to the outer wall of the drying box 1, and the bottom end of the dehumidification box 323 is connected to a drain pipe 326. When the graphene is dried, water vapor will be generated. By starting the suction pump 322, suction can be generated. The water vapor inside the drying box 1 can be adsorbed through the suction pipe 321 and then transferred to the dehumidification box 323. After the water vapor is transferred to the dehumidification box 323, the water vapor can be condensed into water droplets through the condensation grid 324 fixedly connected to the inner wall thereof, and then discharged through the drain pipe 326 connected to the bottom end of the dehumidification box 323. The dehumidified hot air is discharged into the drying box 1 again through the second air duct 325, and the cycle is repeated to complete the elimination of water vapor.

In this embodiment, by starting the suction pump 322 in the dehumidification mechanism 32, the water vapor in the drying box 1 can be sucked out through the suction pipe 321 and then transmitted to the dehumidification box 323. The water vapor in the hot air can be condensed into water droplets through the condensation grid 324, so that the water vapor in the hot air can be removed. The hot air with moisture removed will be transmitted back to the drying box 1 through the second air duct 325. This cycle can complete the elimination of water vapor.

Claims (7)

1. A hot air drying device for graphene, comprising a drying oven (1); A support leg (2) fixedly connected to the outer wall of the drying box (1); The invention also comprises a drying and dehumidifying mechanism (3) arranged inside and at the top of the drying box (1), characterized in that the drying and dehumidifying mechanism (3) comprises a drying mechanism (31) installed inside the drying box (1), and a dehumidifying mechanism (32) is installed on one side of the drying mechanism (31). 2. A hot air drying device for graphene according to claim 1, characterized in that: the drying mechanism (31) is fixedly connected to a fixed frame (311) at the top of the drying box (1), the bottom end of the fixed frame (311) is fixedly connected to a motor (312), the output end of the motor (312) is fixedly connected to a telescopic connecting rod (313), the outer wall of the telescopic connecting rod (313) is provided with a connecting hole (314), the outer wall of the telescopic connecting rod (313) is connected and rotatably connected to a rotating sleeve (315), the outer wall of the rotating sleeve (315) is connected and provided with a first air supply pipe (316), the first air supply pipe (316) is connected and provided with a hot air blower (317) at one end away from the rotating sleeve (315), the bottom end of the hot air blower (317) is fixed The telescopic connecting rod (313) is connected to the top of the drying box (1); the outer wall of the telescopic connecting rod (313) is connected to a first connecting stirring blade (318); the outer wall of the telescopic connecting rod (313) below the first connecting stirring blade (318) is connected to a connecting plate (3110); the bottom end of the connecting plate (3110) is connected to a second connecting stirring blade (3111); the outer walls of the first connecting stirring blade (318) and the second connecting stirring blade (3111) are both connected to an air injection pipe (319); the outer wall of the bottom end of the telescopic connecting rod (313) is provided with a threaded groove (3112); the outer wall of the threaded groove (3112) is threadedly connected to a threaded sleeve (3113); the bottom end of the threaded sleeve (3113) is fixedly connected to the bottom end of the inner wall of the drying box (1). 3. A hot air drying device for graphene according to claim 1, characterized in that: the dehumidification mechanism (32) comprises a suction pump (322) fixedly connected to the top of the drying box (1), the outer wall of the suction pump (322) is connected to a suction pipe (321), the end of the suction pipe (321) away from the suction pump (322) is connected to the top of the drying box (1), the end of the suction pump (322) away from the suction pipe (321) is connected to a dehumidification box (323), the inner wall of the dehumidification box (323) is fixedly connected to a condensation grid (324), the end of the dehumidification box (323) away from the suction pump (322) is connected to a second air supply pipe (325), the end of the second air supply pipe (325) away from the dehumidification box (323) is connected to the outer wall of the drying box (1), and the bottom of the dehumidification box (323) is connected to a drain pipe (326). 4. A hot air drying device for graphene according to claim 2, characterized in that: the number of the connecting holes (314) is five, and the connecting holes (314) are evenly distributed on the outer wall of the telescopic connecting rod (313). 5. A hot air drying device for graphene according to claim 2, characterized in that: the number of the first connected stirring blades (318) is four, the number of the second connected stirring blades (3111) is four, and the first connected stirring blades (318) and the second connected stirring blades (3111) are a group of two and are symmetrically distributed on the outer wall of the telescopic connecting rod (313). 6. A hot air drying device for graphene according to claim 2, characterized in that the inner wall of the rotating sleeve (315) is adapted to the outer wall of the telescopic connecting rod (313). 7. A hot air drying device for graphene according to claim 3, characterized in that the outer wall of the condensation grid (324) is adapted to the inner wall of the dehumidification box (323).