CN110813502A

CN110813502A - Full-automatic grinding device for preparing nano material

Info

Publication number: CN110813502A
Application number: CN201911177097.2A
Authority: CN
Inventors: 刘柏祥
Original assignee: Longyou Oufan Nano Materials Co Ltd
Current assignee: Longyou Oufan Nano Materials Co Ltd
Priority date: 2019-11-26
Filing date: 2019-11-26
Publication date: 2020-02-21
Also published as: JP2021084101A

Abstract

The invention discloses a full-automatic grinding device for preparing nano materials, which comprises a rack, wherein an upper driving cavity is arranged on the inner side of the upper end of the rack, the whole device is provided with a motor which can drive the whole device to run, the starting and stopping operation of the device is simple and convenient, raw materials can be ground into tiny particles in a full-automatic manner, the raw materials can be put into a designated position to start working, then the device runs in a full-automatic manner without manual operation, the required materials can be obtained after the working is finished, the full-automatic operation can effectively reduce the risk of manual operation, the safety of workers is guaranteed, the cost can be effectively reduced, and the nano materials have wider application space.

Description

Full-automatic grinding device for preparing nano material

Technical Field

The invention relates to the field of nano materials, in particular to a full-automatic grinding device for preparing a nano material.

Background

The three major industries of development of the economy of this century are the information science and technology, the life science and technology, and the nano science and technology. Nanotechnology is a firm foundation for further development of information and life science technologies. Future nanotechnology and nanomaterials will penetrate many fields, including new materials, microelectronics, computers, medicine, aerospace, aviation, environment, energy, biotechnology, and agriculture.

At the present stage, the preparation of the nano material is still more complex and the automation degree is not high, so that the preparation cost of the nano material is in a higher level for a long time, the application scene is limited to a certain extent, the nano material can not be applied in a large scale, and the further development of the nano material is hindered.

Disclosure of Invention

The invention aims to provide a full-automatic grinding device for preparing nano materials, which solves the problems that the preparation of the nano materials is still more complicated and the automation degree is not high, and can effectively reduce the cost.

The invention is realized by the following technical scheme.

The invention relates to a full-automatic grinding device for preparing nano materials, which comprises a rack, wherein an upper driving cavity is arranged on the inner side of the upper end of the rack, a first belt pulley is arranged on the left side of the upper driving cavity, a second belt pulley connected with the first belt pulley through a first belt is arranged on the right side of the upper driving cavity, a single-rotation reciprocating lead screw is fixedly arranged at the bottom end of the second belt pulley, a thrust sliding block is arranged on the single-rotation reciprocating lead screw in a threaded fit manner, a pressure plate is fixedly arranged at the bottom end of the thrust sliding block, a first spring is fixedly arranged at the upper end of the thrust sliding block, the upper end of the first spring is fixedly connected with a sealing cover, a first guide rail is arranged on the rack at the left end of the sealing cover, the sealing cover is in a sliding fit with the first guide rail, and a through hole allowing the single-rotation reciprocating lead, a second guide rail in sliding fit with the thrust sliding block is arranged on the left side of the inner wall of the sealing cover, a raw material groove positioned on the left side of the first guide rail is arranged in the machine frame, a movable baffle is arranged at the lower end of the raw material groove, a pushing mechanism is arranged on the left side of the raw material groove, a rolling groove body is arranged below the sealing cover, a pressure cavity communicated up and down is arranged in the rolling groove body, a lower driving cavity is arranged below the left side of the upper driving cavity, a first transmission shaft is rotatably arranged between the lower driving cavity and the upper driving cavity, the upper end of the first transmission shaft is fixedly connected with a first belt pulley, the lower end of the bottom end of the first transmission shaft extends into the lower driving cavity and is fixedly provided with a third bevel gear, a first transmission cavity is arranged on the right side of the lower driving cavity, and a, the right side of the third bevel gear is connected with a fourth bevel gear in a meshing manner, the fourth bevel gear is fixedly installed on the left end face of a fourth transmission shaft, a fourth transmission gear fixedly connected with the right end of the fourth transmission shaft is arranged in a first transmission cavity, a fifth transmission gear is connected above the fourth transmission gear in a meshing manner, a sixth transmission gear is connected below the fourth transmission gear in a meshing manner, the fifth transmission gear is fixedly installed on the left end face of the fifth transmission shaft, the sixth transmission gear is fixedly installed on the left end face of the sixth transmission shaft, and the fifth transmission shaft and the sixth transmission shaft are rotatably installed in the right end wall of the first transmission cavity, extend rightwards and are respectively and in power connection with a vibration mechanism and a crushing mechanism.

Furthermore, the pushing mechanism comprises a second transmission cavity which is arranged on the left side of the raw material groove and is penetrated by the first transmission shaft, a first half-edge gear fixedly connected with the first transmission shaft and a first transmission gear positioned above the first half-edge gear are arranged in the second transmission cavity, the right side of the first transmission gear is meshed with a second transmission gear which is fixed on the second transmission shaft, a second half-edge gear is fixedly arranged at the lower end of the second transmission shaft, the upper end and the lower end of the second transmission shaft are respectively rotatably arranged in the upper end wall and the lower end wall of the second transmission cavity, a first tooth socket communicated with the outside is arranged on the right side of the second transmission cavity, and a first rack which can be meshed with the first half-edge gear and the second half-edge gear and is fixedly connected with the movable baffle is slidably arranged in the first tooth socket, a rotating cavity is arranged below the second transmission cavity, a first bevel gear fixedly connected with the first transmission shaft is arranged in the rotating cavity, the first bevel gear is meshed with a second bevel gear, a rotating shaft is fixedly installed at the rear end of the second bevel gear, the rear end of the rotating shaft is rotatably installed in the rear end wall of the rotating cavity, a cam positioned at the rear side of the second bevel gear is also fixedly installed on the rotating shaft, a second tooth groove extending rightwards is arranged at the right side of the rotating cavity, a second rack is slidably installed in the second tooth groove, a roller matched with the cam is arranged at the left end of the second rack, a reciprocating spring is arranged at the right side of the second rack, a lower gear groove is arranged at the front side of the second tooth groove, a third transmission gear meshed with the second rack is arranged in the lower gear groove, and an upper gear groove is arranged above the lower gear groove, go up the gear groove with rotate between the gear groove down and install the third transmission shaft, the third transmission shaft upper end stretches into go up in the gear groove and fixed mounting have a thrust gear, the lower extreme stretches into with third drive gear fixed connection in the gear groove down, go up the gear groove rear side and be provided with the third tooth's socket of controlling the extension, third tooth's socket slidable mounting have with thrust gear engagement connect and with the third rack that rolls cell body fixed connection, first transmission shaft lower extreme and fixed mounting are in rotating electrical machines power in the lower drive chamber diapire is connected.

Further, the vibrating mechanism comprises an eccentric wheel fixedly arranged on the right side of the fifth transmission shaft, a guide block fixedly connected with a rack is arranged above the eccentric wheel, a vibrating strip slides up and down in the guide block, a roller rack is fixedly arranged at the bottom end of the vibrating strip, a vibrating roller which is abutted against the eccentric wheel is arranged in the roller rack through a roller, a filter screen is hinged at the upper end of the vibrating strip, a filter screen frame fixedly connected with the rack is hinged at the right end of the filter screen, a worm is fixedly arranged at the right end of the fifth transmission shaft, worm frames fixedly connected with the rack are symmetrically arranged in the front and at the back below of the worm, a worm wheel shaft is rotatably arranged on the right side of the worm frame, a worm wheel meshed with the worm is fixedly arranged on the worm wheel shaft, a seventh transmission gear is fixedly arranged at the rear end of the worm wheel shaft, and an eighth, the eighth transmission gear is fixedly installed on a seventh transmission shaft, a third belt pulley is fixedly installed on the seventh transmission shaft, the seventh transmission shaft is installed on the rack through a left support, the third belt pulley is connected with a fourth belt pulley through a second belt, and the fourth belt pulley is installed on the rack through a right support.

Furthermore, the crushing mechanism comprises a crushing cavity positioned on the right side of the sixth transmission shaft, the right end of the sixth transmission shaft extends into the crushing cavity and is fixedly provided with a fifth belt pulley, the fifth belt pulley is connected with the sixth belt pulley through a third belt, the sixth belt pulley is fixedly arranged on an eighth transmission shaft, the left end and the right end of the eighth transmission shaft are rotatably arranged in the left end wall and the right end wall of the crushing cavity, a ball milling shell fixedly connected with the sixth transmission shaft is arranged in the crushing cavity, the ball milling shell is provided with a plurality of particle openings, the eight transmission shaft is fixedly provided with a column milling shell, the column milling shell is provided with a plurality of dust openings, a ball body with a diameter smaller than the particle openings is arranged in the ball milling shell, a cylinder with a diameter larger than the dust openings is arranged in the column milling shell, and a left crushing gear is arranged above the ball milling shell, the left side is smashed the gear right side meshing and is connected with right crushing gear, left side is smashed the gear and is passed through left gear support mounting in the frame, right side is smashed the gear and is passed through right gear support mounting in the frame, install the seventh belt pulley on the gear support of a left side, the seventh belt pulley passes through fourth belt and eighth belt pulley connection, the eighth belt pulley with fourth belt pulley coaxial installation is on right branch frame, it is provided with the material storage chamber to smash the chamber below.

Furthermore, an inclined groove communicated with the upper part of the crushing cavity is formed below the filter screen, so that materials passing through the filter screen fall into the crushing cavity through the inclined groove.

The invention has the beneficial effects that: the device simple structure, the simple operation, degree of automation is high, only need put into the assigned position with raw and other materials and can begin work, and the full automatization operation does not need the manual operation afterwards, can acquire required material after the work. The full-automatic operation can effectively reduce the risk of manual operation, ensure the safety of workers, effectively reduce the cost and ensure that the nano material has wider application space.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

FIG. 1 is a schematic structural diagram of an embodiment of the present invention;

FIG. 2 is an enlarged schematic view of the structure at A in FIG. 1 according to an embodiment of the present invention;

FIG. 3 is an enlarged schematic view of the structure at B in FIG. 1 according to an embodiment of the present invention;

fig. 4 is an enlarged schematic view of the structure at C in fig. 1 according to the embodiment of the present invention.

Detailed Description

The invention will now be described in detail with reference to fig. 1-4, wherein for ease of description the orientations described hereinafter are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The full-automatic grinding device for preparing the nano material comprises a frame 1, wherein an upper driving cavity 86 is arranged on the inner side of the upper end of the frame 1, a first belt pulley 3 is arranged on the left side of the upper driving cavity 86, a second belt pulley 5 connected with the first belt pulley 3 through a first belt 4 is arranged on the right side of the upper driving cavity 86, a single-rotation reciprocating lead screw 6 is fixedly installed at the bottom end of the second belt pulley 5, a thrust slider 10 is installed on the single-rotation reciprocating lead screw 6 in a threaded fit manner, a pressure plate 87 is fixedly installed at the bottom end of the thrust slider 10, a first spring 9 is fixedly installed at the upper end of the thrust slider 10, the upper end of the first spring 9 is fixedly connected with a sealing cover 8, a first guide rail 7 is arranged on the frame 1 at the left end of the sealing cover 8, the sealing cover 8 is in a sliding fit manner with the first guide rail 7, a through hole allowing the single-rotation reciprocating lead screw 6 to pass through, a second guide rail 11 in sliding fit with the thrust slider 10 is arranged on the left side of the inner wall of the sealing cover 8, a raw material groove 12 positioned on the left side of the first guide rail 7 is arranged in the machine frame 1, a movable baffle 13 is arranged at the lower end of the raw material groove 12, a pushing mechanism 88 is arranged on the left side of the raw material groove 12, a rolling groove body 14 is arranged below the sealing cover 8, a pressure cavity 16 communicated with the upper part and the lower part is arranged in the rolling groove body 14, a lower driving cavity 92 is arranged below the left side of the upper driving cavity 86, a first transmission shaft 2 is rotatably arranged between the lower driving cavity 92 and the upper driving cavity 86, the upper end of the first transmission shaft 2 is fixedly connected with the first belt pulley 3, the lower end of the bottom end of the first transmission shaft 2 extends into the lower driving cavity 92 and is fixedly provided with a third bevel gear 36, a first transmission cavity 93 is arranged on the right side of the lower driving cavity 92, and a, the right side of the third bevel gear 36 is engaged with a fourth bevel gear 37, the fourth bevel gear 37 is fixedly mounted on the left end face of a fourth transmission shaft 38, a fourth transmission gear 40 fixedly connected with the right end of the fourth transmission shaft 38 is arranged in the first transmission cavity 93, a fifth transmission gear 39 is engaged and connected above the fourth transmission gear 40, a sixth transmission gear 41 is engaged and connected below the fourth transmission gear 40, the fifth transmission gear 39 is fixedly mounted on the left end face of a fifth transmission shaft 42, the sixth transmission gear 41 is fixedly mounted on the left end face of a sixth transmission shaft 43, the fifth transmission shaft 42 and the sixth transmission shaft 43 are rotatably mounted in the right end wall of the first transmission cavity 93 and extend rightwards, and are respectively and dynamically connected with a vibration mechanism 89 and a crushing mechanism 90.

Further, the pushing mechanism 88 includes a second transmission cavity 91 disposed on the left side of the raw material tank 12 and penetrated by the first transmission shaft 2, a first half-edge gear 22 fixedly connected to the first transmission shaft 2 and a first transmission gear 21 located above the first half-edge gear 22 are disposed in the second transmission cavity 91, the right side of the first transmission gear 21 is engaged with a second transmission gear 35, the second transmission gear 35 is fixed on the second transmission shaft 33, a second half-edge gear 34 is fixedly mounted at the lower end of the second transmission shaft 33, the upper and lower ends of the second transmission shaft 33 are respectively rotatably mounted in the upper and lower end walls of the second transmission cavity 91, a first tooth groove 32 communicated with the outside is disposed on the right side of the second transmission cavity 91, a first rack 31 capable of being engaged with the first half-edge gear 22 and the second half-edge gear 34 and fixedly connected to the movable baffle 13 is slidably mounted in the first tooth groove 32, a rotating cavity 94 is arranged below the second transmission cavity 91, a first bevel gear 26 fixedly connected with the first transmission shaft 2 is arranged in the rotating cavity 94, the first bevel gear 26 is engaged with a second bevel gear 27, a rotating shaft 95 is fixedly installed at the rear end of the second bevel gear 27, the rear end of the rotating shaft 95 is rotatably installed in the rear end wall of the rotating cavity 94, a cam 25 positioned at the rear side of the second bevel gear 27 is also fixedly installed on the rotating shaft 95, a second tooth groove 23 extending rightwards is arranged at the right side of the rotating cavity 94, a second tooth groove 19 is slidably installed in the second tooth groove 23, a roller 28 matched with the cam 25 is arranged at the left end of the second tooth groove 19, a reciprocating spring 18 is arranged at the right side of the second tooth groove 19, a lower gear groove 96 is arranged at the front side of the second tooth groove 23, and a third transmission gear 20 engaged with the second tooth groove 19 is arranged in the lower gear groove 96, lower gear groove 96 top is provided with gear groove 97, go up gear groove 97 with rotate between the gear groove 96 down and install third transmission shaft 17, third transmission shaft 17 upper end stretches into go up in gear groove 97 and fixed mounting have thrust gear 15, and the lower extreme stretches into down in the gear groove 96 with third drive gear 20 fixed connection, go up gear groove 97 rear side and be provided with the third tooth's socket 30 of extending about, third tooth's socket 30 slidable mounting have with thrust gear 15 meshing is connected and is rolled cell body 14 fixed connection's third rack 29, 2 lower extremes of first transmission shaft and fixed mounting are in the 24 power connection of rotating electrical machines in the lower drive chamber 92 diapire.

Further, the vibration mechanism 89 comprises an eccentric wheel 50 fixedly mounted on the right side of the fifth transmission shaft 42, a guide block 46 fixedly connected with the frame 1 is arranged above the eccentric wheel 50, a vibration bar 45 slides up and down in the guide block 46, a roller frame 47 is fixedly mounted at the bottom end of the vibration bar 45, a vibration roller 48 abutting against the eccentric wheel 50 is mounted in the roller frame 47 through a roller 49, a filter screen 44 is hinged to the upper end of the vibration bar 45, a filter screen frame 58 fixedly connected with the frame 1 is hinged to the right end of the filter screen 44, a worm 51 is fixedly mounted at the right end of the fifth transmission shaft 42, worm frames 53 fixedly connected with the frame 1 are symmetrically arranged in front and back below the worm 51, a worm wheel shaft 98 is rotatably mounted on the right side of the worm frame 53, and a worm wheel 52 meshed with the worm 51 is fixedly mounted on the worm wheel shaft 98, a seventh transmission gear 54 is fixedly installed at the rear end of the worm wheel shaft, an eighth transmission gear 55 is connected to the right side of the seventh transmission gear 54 in a meshed manner, the eighth transmission gear 55 is fixedly installed on a seventh transmission shaft 57, a third belt pulley 56 is fixedly installed on the seventh transmission shaft 57, the seventh transmission shaft 57 is installed on the rack 1 through a left bracket 59, the third belt pulley 56 is connected with a fourth belt pulley 61 through a second belt 60, and the fourth belt pulley 61 is installed on the rack 1 through a right bracket 63.

Further, the crushing mechanism 90 includes a crushing cavity 72 located on the right side of the sixth transmission shaft 43, the right end of the sixth transmission shaft 43 extends into the crushing cavity 72 and is fixedly provided with a fifth belt pulley 82, the fifth belt pulley 82 is connected with a sixth belt pulley 80 through a third belt 81, the sixth belt pulley 80 is fixedly installed on an eighth transmission shaft 78, the left and right ends of the eighth transmission shaft 78 are rotatably installed in the left and right end walls of the crushing cavity 72, a ball milling housing 73 fixedly connected with the sixth transmission shaft 43 is arranged in the crushing cavity 72, a plurality of particle openings 74 are arranged on the ball milling housing 73, a column milling housing 77 is fixedly installed on the eight transmission shaft 78, a plurality of dust openings 76 are arranged on the column milling housing 77, a sphere 75 with a diameter smaller than that of the particle opening is arranged in the ball milling housing 73, a cylinder 79 with a diameter larger than that of the dust opening is arranged in the column milling housing 77, ball-milling casing 73 top is equipped with a left side and smashes gear 66, the meshing of a left side crushing gear 66 right side is connected with right crushing gear 69, a left side crushing gear 66 passes through left gear bracket 64 and installs in frame 1, right side crushing gear 69 passes through right gear bracket 68 and installs in frame 1, install seventh belt pulley 65 on the left gear bracket 64, seventh belt pulley 65 passes through fourth belt 63 and is connected with eighth belt pulley 62, eighth belt pulley 62 with fourth belt pulley 61 coaxial arrangement is on right branch frame 63, it is provided with material storage chamber 83 to smash chamber 72 below.

Further, an inclined groove 99 is provided below the screen 44 to communicate with an upper portion of the pulverizing chamber 72, so that the material passing through the screen 44 falls into the pulverizing chamber 72 through the inclined groove 99.

In the initial state, the movable shutter 13 is positioned just below the raw material tank 12, and the pressure chamber 16 is in a sealed state.

Sequence of mechanical actions of the whole device:

1: after raw materials to be ground are placed into the raw material tank 12, the rotating motor 24 is started, the rotating motor 24 drives the first transmission shaft 2 to rotate, the first transmission shaft 2 rotates to drive the first half gear 22 to rotate, the first half gear 22 rotates to drive the first rack 31 to move rightwards in the first tooth space 32, the first rack 31 moves rightwards to push the movable baffle 13 to move rightwards, part of the raw materials are pushed into the grinding tank body 14, the first transmission shaft 2 rotates to drive the first transmission gear 21, the first transmission gear 21 rotates to drive the second transmission gear 35 to rotate in the opposite direction, the second transmission gear 35 rotates to drive the second transmission shaft 33 to rotate, the second transmission shaft 33 rotates to drive the second half gear 34 to rotate, the second half gear 34 rotates to drive the first rack 31 to move leftwards in the first tooth space 32, the first rack 31 moves leftwards to drive the movable baffle 13 to move leftwards to return to the position below the raw material tank 12, and then do so in a reciprocating motion.

2: the first transmission shaft 2 rotates to drive the first belt pulley 3 to rotate, the first belt pulley 3 rotates to drive the second belt pulley 5 to rotate through the first belt 4, the second belt pulley 5 rotates to drive the single-rotation reciprocating lead screw 6 to rotate, the single-rotation reciprocating lead screw 6 rotates to drive the thrust slider 10 to move upwards in the second guide rail 11, the thrust slider 10 moves upwards to drive the pressure plate 87 to move upwards, the thrust slider 10 moves upwards to extrude the first spring 9 to drive the sealing cover 8 to move upwards in the first guide rail 7, the thrust slider 10 starts to move downwards in the second guide rail 11 after moving to the top end, the thrust slider 10 moves downwards to drive the pressure plate 87 to move downwards, the thrust slider 10 moves downwards to drive the sealing cover 8 to move downwards in the first guide rail 7 through the first spring 9, and after the pressure cavity 16 is sealed, the pressure plate 87 continues to move downwards to roll raw materials, after the rolling is finished, the roller is moved upwards and then is reciprocated in such a way.

3: the first transmission shaft 2 rotates to drive the first bevel gear 26 to rotate, the first bevel gear 26 rotates to drive the second bevel gear 27 to rotate, the second bevel gear 27 rotates to drive the cam 25 to rotate, the cam 25 rotates to push the roller 28 to reciprocate left and right, the roller 28 reciprocates left and right to drive the second rack 19 to reciprocate left and right in the second tooth groove 23, the second rack 19 reciprocates left and right to drive the third transmission gear 20 to rotate, the third transmission gear 20 rotates to drive the third transmission shaft 17 to rotate, the third transmission shaft 17 rotates to drive the thrust gear 15 to rotate, the thrust gear 15 rotates to drive the third rack 29 to move left and right in the third tooth slot 30, the third rack 29 moves left and right to drive the rolling groove body 14 to do left and right reciprocating motion, and the primarily rolled materials are pushed into the vibration mechanism 89 through the slope 79.

4: the first transmission shaft 2 rotates to drive the third bevel gear 36 to rotate, the third bevel gear 36 rotates to drive the fourth bevel gear 37 to rotate, the fourth bevel gear 37 rotates to drive the fourth transmission shaft 38 to rotate, the fourth transmission shaft 38 rotates to drive the fourth transmission gear 40 to rotate, the fourth transmission gear 40 rotates to drive the fifth transmission gear 39 to rotate, the fifth transmission gear 39 rotates to drive the fifth transmission shaft 42 to rotate, the fifth transmission shaft 42 rotates to drive the eccentric wheel 50 to rotate, the eccentric wheel 50 rotates to drive the vibration roller 48 to do small-distance up-and-down reciprocating motion, the vibration roller 48 does small-distance up-and-down reciprocating motion to drive the vibration strip 45 to do up-and-down reciprocating motion, the vibration strip 45 does up-and-down reciprocating motion to drive the filter screen 44 to do micro vibration, small-particle materials enter the inclined groove 99 through the filter screen and then are sent into the crushing cavity 72, large particles fall onto the second belt 60 along the filter, the fifth transmission shaft 42 rotates to drive the worm 51 to rotate, the worm 51 rotates to drive the worm wheel 52 to rotate, the worm 53 rotates to drive the seventh transmission gear 54, the seventh transmission gear 54 rotates to drive the eighth transmission gear 55 to rotate, the eighth transmission gear 55 rotates to drive the third belt pulley 56 to rotate, the third belt pulley 56 rotates to drive the fourth belt pulley 61 to rotate, the fourth belt pulley 61 rotates to drive the eighth belt pulley 62 and the seventh belt pulley 65 to rotate, the seventh belt pulley 65 rotates to drive the left crushing gear 66 to rotate, the left crushing gear 66 rotates to drive the right crushing gear 69 to rotate, and large particles are further refined and then are sent into the crushing cavity 72.

5: after entering the crushing chamber 72, the particles to be treated enter the ball mill housing 73 and the column mill housing 77 through the particle opening 74 and the dust opening 76, the fourth transmission gear 40 rotates to drive the sixth transmission gear 41 to rotate, the sixth transmission gear 41 rotates to drive the sixth transmission shaft 43 to rotate, the sixth transmission shaft 43 rotates to drive the fifth belt pulley 82 and the ball milling housing 73 to rotate, the ball milling housing 73 rotates to drive the spheres 75 therein to do centrifugal motion, so that the particles entering the ball milling housing 73 are refined again, the fifth belt pulley 82 rotates to drive the sixth belt pulley 80 to rotate, the sixth belt pulley 80 rotates to drive the eighth transmission shaft 78 to rotate, the eighth transmission shaft 78 rotates to drive the cylindrical mill housing 77 to rotate, the cylindrical mill housing 77 rotates to drive the cylindrical body 79 therein to do centrifugal motion, and the particles entering the cylindrical mill housing 77 are finally refined and then stored in the material storage cavity 83.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims

1. A full-automatic grinding device for preparing nano materials comprises a rack, wherein an upper driving cavity is arranged on the inner side of the upper end of the rack, a first belt pulley is arranged on the left side of the upper driving cavity, a second belt pulley connected with the first belt pulley through a first belt is arranged on the right side of the upper driving cavity, a single-rotation reciprocating lead screw is fixedly installed at the bottom end of the second belt pulley, a thrust sliding block is installed on the single-rotation reciprocating lead screw in a threaded fit manner, a pressure plate is fixedly installed at the bottom end of the thrust sliding block, a first spring is fixedly installed at the upper end of the thrust sliding block, the upper end of the first spring is fixedly connected with a sealing cover, a first guide rail is arranged on the rack at the left end of the sealing cover, the sealing cover is in a sliding fit with the first guide rail, a through hole allowing the single-rotation reciprocating lead screw to pass through is arranged at the, a raw material groove positioned on the left side of the first guide rail is arranged in the machine frame, a movable baffle is arranged at the lower end of the raw material groove, a pushing mechanism is arranged on the left side of the raw material groove, a rolling groove body is arranged below the sealing cover, a pressure cavity communicated up and down is arranged in the rolling groove body, a lower driving cavity is arranged below the left side of the upper driving cavity, a first transmission shaft is rotatably arranged between the lower driving cavity and the upper driving cavity, the upper end of the first transmission shaft is fixedly connected with a first belt pulley, the lower end of the bottom end of the first transmission shaft extends into the lower driving cavity and is fixedly provided with a third bevel gear, a first transmission cavity is arranged on the right side of the lower driving cavity, a fourth transmission shaft is rotatably arranged between the first transmission cavity and the lower driving cavity, the right side of the third bevel gear is engaged with a fourth bevel gear, and the fourth bevel gear, be provided with in the first transmission chamber with fourth transmission shaft right-hand member fixed connection's fourth drive gear, fourth drive gear top meshing is connected with fifth drive gear, fourth drive gear below meshing is connected with sixth drive gear, fifth drive gear fixed mounting is on fifth transmission shaft left end face, sixth drive gear fixed mounting is on sixth transmission shaft left end face, the fifth transmission shaft with the sixth transmission shaft all rotates to be installed extend right and respectively power connection has vibration mechanism and rubbing crusher to construct in the first transmission chamber right-hand member wall.

2. The full-automatic grinding device for preparing the nano-material according to claim 1, wherein: the pushing mechanism comprises a second transmission cavity which is arranged on the left side of the raw material groove and is penetrated by the first transmission shaft, a first half-edge gear fixedly connected with the first transmission shaft and a first transmission gear positioned above the first half-edge gear are arranged in the second transmission cavity, the right side of the first transmission gear is meshed with a second transmission gear which is fixed on the second transmission shaft, a second half-edge gear is fixedly arranged at the lower end of the second transmission shaft, the upper end and the lower end of the second transmission shaft are respectively rotatably arranged in the upper end wall and the lower end wall of the second transmission cavity, a first tooth socket communicated with the outside is arranged on the right side of the second transmission cavity, a first rack which can be meshed with the first half-edge gear and the second half-edge gear and is fixedly connected with the movable baffle is slidably arranged in the first tooth socket, a rotating cavity is arranged below the second transmission cavity, a first bevel gear fixedly connected with the first transmission shaft is arranged in the rotating cavity, the first bevel gear is meshed with a second bevel gear, a rotating shaft is fixedly installed at the rear end of the second bevel gear, the rear end of the rotating shaft is rotatably installed in the rear end wall of the rotating cavity, a cam positioned at the rear side of the second bevel gear is also fixedly installed on the rotating shaft, a second tooth groove extending rightwards is arranged at the right side of the rotating cavity, a second tooth rack is slidably installed in the second tooth groove, a roller matched with the cam is arranged at the left end of the second tooth rack, a reciprocating spring is arranged at the right side of the second tooth rack, a lower gear groove is arranged at the front side of the second tooth groove, a third transmission gear meshed with the second tooth rack is arranged in the lower gear groove, an upper gear groove is arranged above the lower gear groove, and a third transmission shaft is rotatably installed between the upper gear groove and the lower gear groove, third transmission shaft upper end stretches into go up in the gear groove and fixed mounting have a thrust gear, the lower extreme stretches into down in the gear groove with third drive gear fixed connection, go up the gear groove rear side and be provided with the third tooth's socket of extending about, third tooth's socket slidable mounting have with thrust gear meshing connects and with the third rack that rolls cell body fixed connection, first transmission shaft lower extreme and fixed mounting are in rotating electrical machines power connection in the lower drive chamber diapire.

3. The full-automatic grinding device for preparing the nano-material according to claim 1, wherein: the vibrating mechanism comprises an eccentric wheel fixedly arranged on the right side of the fifth transmission shaft, a guide block fixedly connected with a rack is arranged above the eccentric wheel, a vibrating strip slides up and down in the guide block, a roller rack is fixedly arranged at the bottom end of the vibrating strip, a vibrating roller which is abutted against the eccentric wheel is arranged in the roller rack through a roller, a filter screen is hinged at the upper end of the vibrating strip, a filter screen frame fixedly connected with the rack is hinged at the right end of the filter screen, a worm is fixedly arranged at the right end of the fifth transmission shaft, worm frames fixedly connected with the rack are symmetrically arranged in front and at back below the worm, a worm wheel shaft is rotatably arranged on the right side of the worm frame, a worm wheel meshed with the worm is fixedly arranged on the worm wheel shaft, a seventh transmission gear is fixedly arranged on the rear end of the worm wheel shaft, and an eighth transmission, the eighth transmission gear is fixedly installed on a seventh transmission shaft, a third belt pulley is fixedly installed on the seventh transmission shaft, the seventh transmission shaft is installed on the rack through a left support, the third belt pulley is connected with a fourth belt pulley through a second belt, and the fourth belt pulley is installed on the rack through a right support.

4. The full-automatic grinding device for preparing the nano-material according to claim 3, wherein: the crushing mechanism comprises a crushing cavity positioned on the right side of the sixth transmission shaft, the right end of the sixth transmission shaft extends into the crushing cavity and is fixedly provided with a fifth belt pulley, the fifth belt pulley is connected with the sixth belt pulley through a third belt, the sixth belt pulley is fixedly arranged on an eighth transmission shaft, the left end and the right end of the eighth transmission shaft are rotatably arranged in the left end wall and the right end wall of the crushing cavity, the crushing cavity is internally provided with a ball milling shell fixedly connected with the sixth transmission shaft, the ball milling shell is provided with a plurality of particle openings, the eight transmission shaft is fixedly provided with a column milling shell, the column milling shell is provided with a plurality of dust openings, a ball body with a diameter smaller than the particle openings is arranged in the ball milling shell, a cylinder with a diameter larger than the dust openings is arranged in the column milling shell, and a left crushing gear is arranged above the ball milling shell, the left side is smashed the gear right side meshing and is connected with right crushing gear, left side is smashed the gear and is passed through left gear support mounting in the frame, right side is smashed the gear and is passed through right gear support mounting in the frame, install the seventh belt pulley on the gear support of a left side, the seventh belt pulley passes through fourth belt and eighth belt pulley connection, the eighth belt pulley with fourth belt pulley coaxial installation is on right branch frame, it is provided with the material storage chamber to smash the chamber below.

5. The full-automatic grinding device for preparing the nano-material according to claim 4, wherein: the filter screen below be provided with smash chamber upper portion and be linked together the inclined groove to the material through the filter screen falls into through the inclined groove smash in the chamber.