CN115682663B

CN115682663B - Nanometer material production drying device

Info

Publication number: CN115682663B
Application number: CN202211196299.3A
Authority: CN
Inventors: 孙明烨; 杨钦友
Original assignee: Mudanjiang Normal University
Current assignee: Mudanjiang Normal University
Priority date: 2022-09-29
Filing date: 2022-09-29
Publication date: 2024-04-26
Anticipated expiration: 2042-09-29
Also published as: CN115682663A

Abstract

The invention is suitable for the technical field of nano material production, and provides a nano material production drying device, which comprises a bottom plate, a first supporting plate and a second supporting plate fixed on the bottom plate, and further comprises: the drying device comprises a drying cylinder, a collecting cylinder, a heating cylinder, a motor, an electric heating wire and a connecting groove; the two ends of the drying cylinder are respectively fixed with a connecting sleeve, the two connecting sleeves are respectively connected to the first supporting plate and the second supporting plate in a rotating mode, the heating cylinder is connected in the drying cylinder in a rotating mode, and the electric heating wire is fixed in the heating cylinder. The nanometer material in the drying cylinder enters the collecting cylinder, when the drying cylinder drives the collecting cylinder to move to the upper side, the nanometer material in the collecting cylinder falls onto the heating cylinder from the connecting groove, and the heating cylinder heats and dries the nanometer material, so that the nanometer material falls downwards along the outer wall of the heating cylinder, and then the nanometer material uniformly contacts with the outer wall of the heating cylinder.

Description

Nanometer material production drying device

Technical Field

The invention belongs to the technical field of nano material production, and particularly relates to a nano material production drying device.

Background

Nanomaterial refers to a material having at least one dimension in three dimensions in the nanometer size (1-100 nm) or consisting of them as basic units, which corresponds to a dimension of 10 to 1000 atoms closely arranged together.

The prior drying device for producing the nano material has the publication number of CN215490779U, and in order to uniformly dry the nano material, the nano material is stirred by a stirring blade, so that the uneven drying caused by the accumulation of the nano material is avoided.

However, the stirring method can drive the nano material to flow, but the stirring range of the stirring blade is limited, and the stirring cannot be performed on each part in the drying oven, so that the defects are caused, and the condition of uneven drying still exists.

Disclosure of Invention

The embodiment of the invention aims to provide a nano material production drying device, which aims to solve the problems that the existing stirring mode improves the drying of nano materials and the drying is not uniform.

The invention is realized in that the nano material production drying device comprises a bottom plate, a first supporting plate and a second supporting plate fixed on the bottom plate, and further comprises:

the drying device comprises a drying cylinder, a collecting cylinder, a heating cylinder, a motor, an electric heating wire and a connecting groove;

The two ends of the drying cylinder are respectively fixed with connecting sleeves, the two connecting sleeves are respectively connected onto the first supporting plate and the second supporting plate in a rotating way, the heating cylinder is connected into the drying cylinder in a rotating way, the electric heating wire is fixed into the heating cylinder, the two ends of the heating cylinder are respectively fixed with connecting shafts, the connecting shafts penetrate through the drying cylinder, the two connecting shafts are respectively connected onto the first supporting plate and the second supporting plate in a rotating way, the connecting shafts are arranged in the connecting sleeves, four collecting cylinders are fixed onto the drying cylinder, the drying cylinder and the collecting cylinders are communicated through connecting grooves, the motor is fixed onto the second supporting plate, the rotating end of the motor is connected with the connecting shafts, a material opening is formed in the drying cylinder, the material opening is connected with a sealing cover in a threaded way, and a scraping rod is fixed into the drying cylinder;

the transmission assembly drives the drying cylinder to reversely rotate in a connecting shaft rotating mode, and is arranged in the connecting sleeve;

the crushing assembly is used for crushing the nano materials in a manner of rotating the drying cylinder and is arranged in the collecting cylinder;

And the closing component is used for controlling the opening and closing of the connecting groove and is arranged in the connecting groove.

Further technical scheme, the drive assembly includes first gear, second gear and first ring gear, first gear rotates to be connected in the second backup pad, the second gear is fixed on the connecting axle, and first gear and second gear meshing cooperation, first ring gear is fixed in the adapter sleeve, and second gear and first ring gear meshing cooperation.

Further technical scheme, broken subassembly includes axis of rotation, blade, third gear and second ring gear, the axis of rotation rotates to be connected in the collection section of thick bamboo, the blade is fixed in the axis of rotation, the third gear is fixed in the axis of rotation, the second ring gear is fixed in first backup pad, and the meshing cooperation of third gear and second ring gear.

According to a further technical scheme, a plurality of blades are arranged, and the blades are uniformly fixed on the rotating shaft.

Further technical scheme, closure assembly includes push ring, fixed sleeve, pressure spring, push rod, sliding block, slide damper, fixed plate and bolt, push ring sliding connection is in first backup pad, fixed sleeve is fixed on the cylinder, sliding block sliding connection is in fixed sleeve, the push rod is fixed on the sliding block, and the one end and the slide damper fixed connection of push rod, the both ends of pressure spring are connected with sliding block and cylinder respectively, the fixed plate is fixed in the spread groove, slide damper sliding connection is on the fixed plate, all be provided with a plurality of through-holes on slide damper and the fixed plate, bolt threaded connection is in first backup pad, and the one end and the push ring rotation of bolt are connected.

Further technical scheme, it is connected with the mounting panel to rotate on the bottom plate, be provided with the direction spout on the mounting panel, sliding connection has the slider in the direction spout, it is connected with the connecting plate to rotate on the slider, the end of connecting plate rotates to be connected on the bottom plate, direction spout swivelling joint has the lead screw, and lead screw and slider threaded connection, the mounting panel is stretched out to the one end of lead screw.

According to a further technical scheme, the mounting plate is fixedly provided with a supporting block.

According to the nano material production drying device provided by the embodiment of the invention, nano materials in the drying cylinder enter the collecting cylinder, the drying cylinder drives the collecting cylinder to move to the upper side, the nano materials in the collecting cylinder drop onto the heating cylinder from the connecting groove, the heating cylinder heats and dries the nano materials, the nano materials drop downwards along the outer wall of the heating cylinder, the nano materials are further uniformly contacted with the outer wall of the heating cylinder, the nano materials are uniformly dried, the four collecting cylinders sequentially collect and pour the nano materials along with the rotation of the drying cylinder, meanwhile, the crushing assembly crushes the nano materials in a manner of rotating the drying cylinder, so that agglomeration of the nano materials is avoided when the drying cylinder is rotated, the scraping rod is driven to rotate in the opposite direction with the heating cylinder, the scraping rod is driven to scrape and clean the outer wall of the heating cylinder, the nano materials are prevented from being attached onto the heating cylinder, after the drying of the nano materials is finished, the connecting groove at the lower end is controlled by the closing assembly, the nano materials are prevented from entering the collecting cylinder after the drying cylinder, and then the nano materials are discharged from the opening.

Drawings

Fig. 1 is a schematic structural diagram of a drying device for producing nano materials according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of the internal structure of FIG. 1 according to an embodiment of the present invention;

fig. 3 is a schematic view illustrating an internal structure of the drying drum of fig. 1 according to an embodiment of the present invention;

FIG. 4 is an enlarged schematic view of the structure of FIG. 2A according to an embodiment of the present invention;

FIG. 5 is an enlarged schematic view of structure B in FIG. 2 according to an embodiment of the present invention;

FIG. 6 is an enlarged schematic view of structure of C in FIG. 3 according to an embodiment of the present invention;

FIG. 7 is a schematic structural view of the fixing plate in FIG. 6 according to an embodiment of the present invention;

Fig. 8 is a schematic structural diagram of the push ring in fig. 2 according to an embodiment of the present invention.

In the accompanying drawings: the bottom plate 101, the first supporting plate 102, the second supporting plate 103, the drying cylinder 104, the collecting cylinder 105, the heating cylinder 106, the connecting shaft 107, the connecting sleeve 108, the motor 109, the material opening 110, the electric heating wire 111, the connecting groove 112, the transmission assembly 2, the first gear 201, the second gear 202, the first inner gear ring 203, the crushing assembly 3, the rotating shaft 301, the blades 302, the third gear 303, the second inner gear ring 304, the mounting plate 401, the guiding chute 402, the sliding block 403, the connecting plate 404, the screw rod 405, the supporting block 406, the closing assembly 5, the pushing ring 501, the fixing sleeve 502, the pressure spring 503, the pushing rod 504, the sliding block 505, the sliding baffle 506, the fixing plate 507, the bolt 508 and the scraping rod 6.

Detailed Description

The present invention will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present invention more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the invention.

Specific implementations of the invention are described in detail below in connection with specific embodiments.

As shown in fig. 1 to 3, a nanomaterial fabrication drying apparatus provided in accordance with an embodiment of the present invention includes a base plate 101, and a first support plate 102 and a second support plate 103 fixed to the base plate 101, and further includes:

Drying drum 104, collecting drum 105, heating drum 106, motor 109, electric heating wire 111 and connecting groove 112;

The two ends of the drying cylinder 104 are respectively fixed with a connecting sleeve 108, the two connecting sleeves 108 are respectively and rotatably connected to the first supporting plate 102 and the second supporting plate 103, the heating cylinder 106 is rotatably connected to the drying cylinder 104, the electric heating wire 111 is fixed to the heating cylinder 106, the two ends of the heating cylinder 106 are respectively and fixedly provided with a connecting shaft 107, the connecting shafts 107 penetrate through the drying cylinder 104, the two connecting shafts 107 are respectively and rotatably connected to the first supporting plate 102 and the second supporting plate 103, the connecting shafts 107 are arranged in the connecting sleeves 108, the drying cylinder 104 is fixedly provided with four collecting cylinders 105, the drying cylinder 104 and the collecting cylinders 105 are communicated through connecting grooves 112, the motor 109 is fixed to the second supporting plate 103, the rotating end of the motor 109 is connected with the connecting shafts 107, the drying cylinder 104 is provided with a material opening 110, the material opening 110 is in threaded connection with a sealing cover, and the scraping rod 6 is fixedly arranged in the drying cylinder 104;

the transmission assembly 2 drives the drying cylinder 104 to reversely rotate in a rotating mode of the connecting shaft 107, and the transmission assembly 2 is arranged in the connecting sleeve 108;

A crushing assembly 3 for crushing the nano-materials by rotating the drying cylinder 104, wherein the crushing assembly 3 is arranged in the collecting cylinder 105;

and the closing assembly 5 is used for controlling the opening and closing of the connecting groove 112, and the closing assembly 5 is arranged in the connecting groove 112.

In the embodiment of the present invention, a filter screen is fixed on the side wall of the drying cylinder 104, so that the water vapor in the drying cylinder 104 is dispersed from the filter screen; during the use, throw into nano-material in to the stoving section of thick bamboo 104 through feed opening 110, then screw on sealed lid, electric heater strip 111 heats heating section of thick bamboo 106, motor 109 drives connecting axle 107 rotation, connecting axle 107 drives heating section of thick bamboo 106, drive assembly 2 passes through connecting axle 107 pivoted mode and drives stoving section of thick bamboo 104 and reversely rotate, closure assembly 5 control spread groove 112 is opened, nano-material in the stoving section of thick bamboo 104 gets into in the collecting section of thick bamboo 105, when stoving section of thick bamboo 104 drive collecting section of thick bamboo 105 moves the top, nano-material in the collecting section of thick bamboo 105 falls to heating section of thick bamboo 106 from spread groove 112, heating section of thick bamboo 106 heats the drying to nano-material, make nano-material drop downwards along the outer wall of heating section of thick bamboo 106, and then make nano-material even and heating section of thick bamboo 106 outer wall contact, thereby make nano-material even drying, along with the rotation of stoving section of thick bamboo 104, four collecting section of thick bamboo 105 collect and pour out nano-material in proper order, simultaneously, broken assembly 3 is broken through the mode of stoving section of thick bamboo 104 rotation to nano-material, and then caking when avoiding nano-material to dry, the scraper bar 6 rotates, when the stoving section of thick bamboo 104 rotates, scraper bar 6 and heating section of thick bamboo 106 is moved to the upper portion of thick bamboo 106, and then the inner wall of thick bamboo 106 is opened to the heating section of thick bamboo 106 is closed, and then the nano-material is closed to be blown off from the material is closed to the material is opened to the heating section of thick bamboo 106, and then is closed to the material is opened to the drying, and is closed to the material is opened, and is closed to the drying, and is opened.

As shown in fig. 4, as a preferred embodiment of the present invention, the transmission assembly 2 includes a first gear 201, a second gear 202 and a first ring gear 203, the first gear 201 is rotatably connected to the second support plate 103, the second gear 202 is fixed on the connection shaft 107, the first gear 201 is engaged with the second gear 202, the first ring gear 203 is fixed in the connection sleeve 108, and the second gear 202 is engaged with the first ring gear 203.

In the embodiment of the present invention, the connecting shaft 107 drives the second gear 202 and the heating cylinder 106 to rotate, the second gear 202 rotates reversely by the first gear 201, the first gear 201 drives the connecting sleeve 108 to rotate reversely by the first inner gear ring 203, and the connecting sleeve 108 drives the drying cylinder 104 to rotate reversely.

As shown in fig. 1 to 3 and 5, as a preferred embodiment of the present invention, the crushing assembly 3 includes a rotation shaft 301, a vane 302, a third gear 303 and a second ring gear 304, the rotation shaft 301 is rotatably connected in the collection tube 105, the vane 302 is fixed on the rotation shaft 301, the third gear 303 is fixed on the rotation shaft 301, the second ring gear 304 is fixed on the first support plate 102, and the third gear 303 is engaged with the second ring gear 304, the vane 302 is provided in plurality, and the plurality of vanes 302 are uniformly fixed on the rotation shaft 301.

In the embodiment of the present invention, the drying cylinder 104 drives the collecting cylinder 105 to revolve around the axis of the drying cylinder 104, the drying cylinder 104 drives the rotating shaft 301 to revolve around the axis, and when the rotating shaft 301 revolves around the axis, the rotating shaft 301 is driven to rotate by the way that the third gear 303 is meshed with the second inner gear ring 304, the rotating shaft 301 drives the blades 302 to rotate, and the nano materials in the collecting cylinder 105 are stirred and crushed when the blades 302 rotate.

As shown in fig. 1,2, 3, 5, 6, 7 and 8, as a preferred embodiment of the present invention, the closing assembly 5 includes a push ring 501, a fixing sleeve 502, a compression spring 503, a push rod 504, a sliding block 505, a sliding baffle 506, a fixing plate 507, and a bolt 508, the push ring 501 is slidably connected to the first support plate 102, the fixing sleeve 502 is fixed to the collecting cylinder 105, the sliding block 505 is slidably connected to the fixing sleeve 502, the push rod 504 is fixed to the sliding block 505, one end of the push rod 504 is fixedly connected to the sliding baffle 506, two ends of the compression spring 503 are respectively connected to the sliding block 505 and the collecting cylinder 105, the fixing plate 507 is fixed to the connecting groove 112, the sliding baffle 506 is slidably connected to the fixing plate 507, the sliding baffle 506 and the fixing plate 507 are provided with a plurality of through holes, the bolt 508 is threadedly connected to the first support plate 102, and one end of the bolt 508 is rotatably connected to the push ring 501.

In the embodiment of the present invention, the lower end of the push ring 501 is wider than the upper end; after the nano material is dried, the bolt 508 is turned, the bolt 508 pushes the push ring 501 to move rightwards, so that the lower end of the push ring 501 pushes the push rod 504 to move rightwards, the push rod 504 drives the slide baffle 506 to move rightwards, through holes on the slide baffle 506 and the fixed plate 507 are misplaced, and then the connecting groove 112 is closed, when the collecting cylinder 105 at the lower end moves to the upper end, the push rod 504 is not contacted with the push ring 501, the pressure spring 503 pushes the sliding block 505 to move leftwards, the sliding block 505 drives the push rod 504 to move leftwards, the push rod 504 drives the slide baffle 506 to move leftwards, the through holes on the slide baffle 506 and the fixed plate 507 are overlapped, and then the connecting groove 112 is opened, so that the nano material in the collecting cylinder 105 falls out of the connecting groove 112, and then the nano material is stored in the drying cylinder 104, and the nano material in the drying cylinder 104 is conveniently discharged.

As shown in fig. 1 and fig. 2, as a preferred embodiment of the present invention, a mounting plate 401 is rotatably connected to the base plate 101, a guide chute 402 is provided on the mounting plate 401, a slide block 403 is slidably connected to the guide chute 402, a connecting plate 404 is rotatably connected to the slide block 403, a tail end of the connecting plate 404 is rotatably connected to the base plate 101, a screw rod 405 is rotatably connected to the guide chute 402, and the screw rod 405 is in threaded connection with the slide block 403, one end of the screw rod 405 extends out of the mounting plate 401, and a supporting block 406 is fixed on the mounting plate 401.

In the embodiment of the invention, the screw rod 405 is rotated, the screw rod 405 drives the slide block 403 to move rightwards, and the slide block 403 pushes the bottom plate 101 to rotate clockwise through the connecting plate 404, so that the left end of the bottom plate 101 is higher than the right end, and the nano material is conveniently discharged from the material port 110.

In the above embodiment of the present invention, when the nano material production drying device is used, nano material is put into the drying cylinder 104 through the material port 110, then the sealing cover is screwed on, the electric heating wire 111 heats the heating cylinder 106, the motor 109 drives the connecting shaft 107 to rotate, the connecting shaft 107 drives the second gear 202 and the heating cylinder 106 to rotate, the first gear 201 of the second gear 202 is reversed, the first gear 201 drives the connecting sleeve 108 to be reversed through the first annular gear 203, the connecting sleeve 108 drives the drying cylinder 104 to be reversed, the nano material in the drying cylinder 104 enters the collecting cylinder 105, the drying cylinder 104 drives the collecting cylinder 105 to move upwards, the nano material in the collecting cylinder 105 falls onto the heating cylinder 106 from the connecting groove 112, the heating cylinder 106 heats and dries the nano material, the nano material falls down along the outer wall of the heating cylinder 106, and the nano material is uniformly contacted with the outer wall of the heating cylinder 106, so that the nanometer materials are uniformly dried, along with the rotation of the drying cylinder 104, the four collecting cylinders 105 collect and pour the nanometer materials in turn, meanwhile, the drying cylinder 104 drives the collecting cylinders 105 to revolve around the axis of the drying cylinder 104, the drying cylinder 104 drives the rotating shaft 301 to revolve, when the rotating shaft 301 revolves, the rotating shaft 301 is driven to rotate in a mode of meshing and matching the third gear 303 with the second inner gear ring 304, the rotating shaft 301 drives the blades 302 to rotate, the nanometer materials in the collecting cylinders 105 are stirred and crushed when the blades 302 rotate, the caking is avoided when the nanometer materials are dried, the scraping rod 6 is driven to rotate when the drying cylinder 104 rotates, the scraping rod 6 and the heating cylinder 106 reversely rotate, the scraping rod 6 is further driven to scrape the outer wall of the heating cylinder 106 to clean, the nanometer materials are prevented from being attached to the heating cylinder 106, after the nanometer materials are dried, the pushing ring 501 is pushed to right by the bolts 508 to move by the bolts 508, the push rod 504 is pushed to the right by the lower end of the push ring 501, the push rod 504 drives the sliding baffle 506 to move to the right, through holes on the sliding baffle 506 and the fixed plate 507 are staggered, the connecting groove 112 is closed, when the collecting cylinder 105 at the lower end moves to the upper end, the push rod 504 is not contacted with the push ring 501, the pressure spring 503 pushes the sliding block 505 to move to the left, the sliding block 505 drives the push rod 504 to move to the left, the push rod 504 drives the sliding baffle 506 to move to the left, the through holes on the sliding baffle 506 and the fixed plate 507 are overlapped, the connecting groove 112 is opened, nano materials in the collecting cylinder 105 fall out of the connecting groove 112, the nano materials are stored in the drying cylinder 104, the nano materials do not enter the collecting cylinder 105 any more after falling out of the collecting cylinder 105, the lead screw 405 is rotated, the lead screw 405 drives the slide block 403 to move to the right, the slide block 403 pushes the bottom plate 101 to rotate clockwise through the connecting plate 404, the left end of the bottom plate 101 is higher than the right end, the nano materials are conveniently discharged from the material port 110, and the nano materials are discharged from the material port 110.

The foregoing description of the preferred embodiments of the invention is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the invention.

Claims

1. The utility model provides a nano-material produces drying device, includes the bottom plate to and fixed first backup pad and second backup pad on the bottom plate, its characterized in that still includes:

the closing component is used for controlling the opening and closing of the connecting groove and is arranged in the connecting groove;

the transmission assembly comprises a first gear, a second gear and a first inner gear ring, the first gear is rotationally connected to the second supporting plate, the second gear is fixed on the connecting shaft and is meshed with the second gear, the first inner gear ring is fixed in the connecting sleeve, and the second gear is meshed with the first inner gear ring;

The crushing assembly comprises a rotating shaft, blades, a third gear and a second inner gear ring, the rotating shaft is rotationally connected in the collecting cylinder, the blades are fixed on the rotating shaft, the third gear is fixed on the rotating shaft, the second inner gear ring is fixed on the first supporting plate, and the third gear is meshed and matched with the second inner gear ring;

The utility model discloses a closed subassembly, including pushing ring, fixed cover, pressure spring, push rod, sliding block, slide damper, fixed plate and bolt, push ring sliding connection is in first backup pad, fixed cover is fixed on the collection cylinder, sliding block sliding connection is in fixed cover, the push rod is fixed on the sliding block, and the one end and the slide damper fixed connection of push rod, the both ends of pressure spring are connected with sliding block and collection cylinder respectively, the fixed plate is fixed in the spread groove, slide damper sliding connection is on the fixed plate, all be provided with a plurality of through-holes on slide damper and the fixed plate, bolt threaded connection is in first backup pad, and the one end and the push ring rotation of bolt are connected.

2. The nanomaterial fabrication drying apparatus of claim 1, wherein a plurality of the blades are provided, and the plurality of the blades are uniformly fixed on a rotation shaft.

3. The nanomaterial production drying device of claim 1, wherein the base plate is rotatably connected with a mounting plate, a guide chute is arranged on the mounting plate, a slide block is slidably connected with the guide chute, a connecting plate is rotatably connected with the slide block, the tail end of the connecting plate is rotatably connected with the base plate, a screw rod is rotatably connected with the guide chute, the screw rod is in threaded connection with the slide block, and one end of the screw rod extends out of the mounting plate.

4. A nanomaterial fabrication drying apparatus as claimed in claim 3, wherein a support block is secured to the mounting plate.