CN115301149A - Raw material mixing device is used in graphite alkene production and processing - Google Patents

Abstract

A raw material mixing device for graphene production and processing is characterized in that a rotatable rotating disc is mounted on the outer side of a mixing barrel, a mounting box is mounted on the lower side of the rotating disc, sliding clamping blocks capable of performing arc-shaped sliding with the center of the rotating disc as the center are respectively connected to the upper side and the lower side of the inner side of the rotating disc in a sliding mode, and the mixing barrel is detachably mounted between the two sliding clamping blocks; this device can carry out the state of mixing according to the required control mixing barrel of material when using, and then improve the mixing barrel and carry out the intensity that mixes to the material, can effectual improvement mixing effect, and can also control respectively according to the required churning time of material of difference and the speed of stirring, user's operation has not only been made things convenient for, and the controllability is stronger, the required condition when having strengthened the mixing effect of material and can the different material mixes, initial condition can all be replied to rolling disc and mixing barrel after stirring each time finishes, the person of facilitating the use uses.

Description

Raw material mixing device is used in graphite alkene production and processing

Technical Field

The invention relates to the field of graphene mixing, in particular to a raw material mixing device for graphene production and processing.

Background

Graphene is a two-dimensional crystal, and is a hexagonal honeycomb-lattice two-dimensional carbon nanomaterial formed by carbon atoms through sp2 hybridized orbitals. Graphene has excellent optical, electrical and mechanical properties, and has an important application prospect in the aspects of materials science, micro-nano processing, energy, biomedicine, drug delivery and the like, graphene needs to be sequentially added with other raw materials for mixing in the production and preparation process, the mixing degree and the mixing strength also need to be correspondingly adjusted due to the difference of the raw materials in the mixing process, the mixing mode of the existing mixing equipment is relatively single when mixing, the raw materials are easy to precipitate in the mixing process, so that the mixing effect is reduced, the product quality is reduced, the controllability is poor, the mixing mode and the mixing strength cannot be changed according to the difference of the added raw materials, the mixing effect is relatively poor and the mixing efficiency is low in the preparation process of graphene.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides a raw material mixing device for producing and processing graphene, which effectively solves the problems mentioned in the background technology.

In order to solve the problems, the invention adopts the technical scheme that:

a raw material mixing device for graphene production and processing comprises a mixing barrel, wherein a rotatable rotating disc is installed on the outer side of the mixing barrel, an installation box is installed on the lower side of the rotating disc, the rotating disc is installed at the upper end of the installation box in a vertical state, the upper side and the lower side of the inner side of the rotating disc are respectively connected with sliding clamping blocks capable of performing arc-shaped sliding by taking the center of the rotating disc as the center in a sliding mode, and the mixing barrel is detachably installed between the two sliding clamping blocks; the left side and the right side of the lower end in the mounting box are respectively and sequentially connected with a driven disc and a main driving disc in a rotating mode from left to right, the lower end surfaces of the driven disc and the main driving disc are respectively and slidably connected with distraction blocks which can respectively conduct distraction movement by taking the centers of the driven disc and the main driving disc as centers, the distraction blocks on the lower end surfaces of the driven disc and the main driving disc can synchronously move and have opposite movement directions, the outer side surfaces of the driven disc and the main driving disc are jointly provided with a driving belt, two ends of the driving belt are sleeved on the outer side surfaces of the distraction blocks on the lower end surfaces of the driven disc and the main driving disc, the middle parts of the driven disc and the main driving disc are respectively and fixedly connected with a connecting rod, the upper side surface of the connecting rod in the middle part of the driven disc is slidably connected with a first end face gear capable of moving up and down, the upper side of the first end face gear is provided with a second end face gear capable of being meshed, and the second end face gear is fixedly connected with the bottom of the rotating disc; the rear side of the rotating disc is coaxially and rotatably connected with an installation shaft capable of driving the sliding fixture block to make arc-shaped sliding, the rear side of the surface of the installation shaft is fixedly connected with a matched bevel gear, the rear side of the upper end surface of the installation box is slidably connected with an installation plate capable of moving back and forth, and the upper end of the installation plate is fixedly connected with a bevel gear block capable of being meshed with the matched bevel gear; the right side in the mounting box is provided with a power transmission structure capable of moving back and forth, the power transmission structure can push the first end face gear to move upwards to be meshed with the second end face gear when moving towards the rear side, the rear side of the mounting box is rotatably connected with a rotatable spiral groove rod, the power transmission structure can be connected with the spiral groove rod and drive the spiral groove rod to rotate when moving towards the rear side, the surface of the spiral groove rod is meshed with a reciprocating plate capable of moving up and down, the reciprocating plate is slidably connected with the inner wall of the mounting box, the reciprocating plate can be driven to move up and down when rotating in a reciprocating mode, the spiral groove rod can also be driven to rotate in a reciprocating mode when moving up and down, and the power transmission structure can be pushed to move forwards to reset when moving downwards to the bottommost.

Preferably, the lower side of the surface of the connecting rod is respectively and slidably connected with a hinge ring capable of moving up and down, the lower end of the spreading block is respectively and hingedly connected with a supporting rod, the bottom of the supporting rod is respectively and hingedly connected with the upper end of the hinge ring, the lower end of the hinge ring is rotatably connected with a driving cylinder capable of moving up and down, the inner side surface of the driving cylinder is provided with an annular driving groove, the driving cylinder and the connecting rod are coaxial, the surface of the driving cylinder is slidably connected with a limiting plate, the limiting plate is fixedly connected with the inner wall of the mounting box, the lower end inside the driving cylinder is provided with a guide rod, the bottom of the guide rod is rotatably connected with the inner wall of the mounting box, the upper side of the surface of the guide rod is fixedly connected with a guide pin shaft, and the guide pin shaft is meshed with the driving groove; the surface lower side of the guide rod is fixedly connected with a first driving belt wheel and a second driving belt wheel respectively, a first driving belt is sleeved on the outer side surface of the first driving belt wheel and the outer side surface of the second driving belt wheel together, a driving worm wheel is fixedly connected with the surface lower side of the guide rod on the lower side of the main driving disc, a driving worm is meshed on one side of the driving worm wheel, the front end of the driving worm is connected with the surface of the mounting box in a rotating mode, and the front end of the driving worm is fixedly connected with a driving knob.

Preferably, the surface of the first face gear is rotatably connected with a lifting plate capable of moving up and down, the lifting plate is connected with the inner wall of the mounting box in a sliding manner, the upper end of the rear side of the lifting plate is fixedly connected with a first return spring, the upper end of the first return spring is fixedly connected with the inner wall of the mounting box, a control shaft capable of moving back and forth is mounted on the right side in the mounting box, the surface of the control shaft is rotatably connected with a push plate, the push plate is slidably connected with the inner wall of the mounting box, the left end of the push plate is positioned on the front side of the right end of the lifting plate, and when the control shaft moves towards the rear side, the lifting plate can be pushed to move upwards through the push plate; the upper end fixedly connected with transmission pinion of second terminal surface gear, the right side meshing of transmission pinion has the speed reduction gear wheel, the downside of speed reduction gear wheel is provided with the coil spring box, the coil spring box with installation box inner wall fixed connection, the inside of coil spring box is provided with the spring that resets, the outer end of spring that resets in coil spring box inner wall fixed connection, the inner fixedly connected with of spring that resets reset the axle, the upper end both ends of the axle that resets respectively in coil spring box surface rotation connects, the upper end of the axle that resets with speed reduction gear wheel middle part fixed connection.

Preferably, two sides corresponding to the end surface of the rotating disc are respectively provided with an arc-shaped chute, the sliding clamping block is respectively connected with the arc-shaped chutes in a sliding manner, arc-shaped springs are respectively arranged inside the arc-shaped chutes, two ends of each arc-shaped spring are respectively fixedly connected with the sliding clamping block and the inner walls of the arc-shaped chutes, the surfaces of the front ends of the sliding clamping blocks are respectively connected with fixing bolts in a threaded manner, and the inner ends of the fixing bolts are respectively attached to the upper end and the lower end of the mixing barrel; the two sides corresponding to the surface of the rear end of the rotating disc are fixedly connected with arc ratchet bars respectively, the inner sides of the arc ratchet bars are meshed with butt joint ratchet blocks capable of moving synchronously respectively, the front end of the installation shaft is fixedly connected with an installation guide plate, the upper end and the lower end of the installation guide plate are connected with connection sliding plates capable of moving synchronously respectively in a sliding mode, the front end of each connection sliding plate is connected with the rear end of the corresponding sliding fixture block in a sliding mode, the inner ends of the two connection sliding plates are fixedly connected with second reset springs respectively, the other ends of the second reset springs are fixedly connected with the surface of the installation guide plate respectively, the inner ends of the two butt joint ratchet blocks are fixedly connected with the connection sliding plates respectively, the surface of the installation shaft is connected with a rotating cylinder in a rotating mode, the upper side and the lower side of the left side of the surface of the rotating cylinder are hinged with pull rods respectively, the other ends of the pull rods are hinged with the connection sliding plates respectively, the surface of the rotating cylinder is fixedly connected with a rotating gear, one side of the rotating gear is meshed with a guide rack capable of moving up and down, the surface of the rotating cylinder is connected with an annular rack, and the inner side of the annular plate is connected with the inner side of the guide sliding plate.

Preferably, the power transmission structure includes a motor fixedly connected to the right side inside the mounting box, an output end of the lower side of the motor is fixedly connected with an upper bevel gear, a lower bevel gear is arranged on the lower side of the upper bevel gear, the lower bevel gear is fixedly connected with an upper end of a connecting rod in the middle of the main drive disk, the control shaft is located between the upper bevel gear and the lower bevel gear, a front end of the control shaft penetrates through the front end of the mounting box, a control button is rotatably connected with a front end of the control shaft, a surface of the control shaft is fixedly connected with a butt bevel gear which can be respectively engaged with the upper bevel gear and the lower bevel gear, a rear end of the control shaft is rotatably connected with a control panel, the control panel is slidably connected with an inner wall of the mounting box, a pushing spring is fixedly connected to a rear side of a lower end of the control panel, the other end of the pushing spring is fixedly connected with an inner wall of the mounting box, a lower end of the control panel is rotatably connected with a second linkage bevel gear, a first linkage bevel gear which can be engaged with the second linkage bevel gear is fixedly connected to a front end center of the pushing spring, a surface of the control shaft is fixedly connected with a first linkage bevel gear which is fixedly connected with a belt pulley, and a second belt pulley which is commonly engaged with a second belt pulley.

Preferably, the left side fixedly connected with tooth piece of control panel, the rear side of tooth piece is provided with the cooperation gear that can mesh, the cooperation gear with the mounting box inner wall rotates to be connected, the left end of cooperation gear is with axle center fixedly connected with rotor plate, the left side of rotor plate is provided with the sliding groove board, the sliding groove board with mounting box inner wall fixed connection, the sliding surface of sliding groove board is connected with the link block that can reciprocate, the upper end fixedly connected with interlock spring of link block, the upper end of interlock spring with sliding groove board fixed connection, the rear side position on the left end surface of rotor plate articulates there is the articulated slab, the other end of articulated slab with the interlock slider articulates, the left end fixedly connected with clamp plate of link block, the rear side fixedly connected with of annular plate corresponds the board, the right-hand member that corresponds the board is located the downside of clamp plate.

Preferably, a locking ratchet block is fixedly connected to a lower side of a left end of the control panel, a locking ratchet bar capable of moving left and right is engaged with a left side of the locking ratchet block, a lower end of the locking ratchet bar is slidably connected to an inner wall of the mounting box, second engaging springs are fixedly connected to front and rear sides of a left end of the locking ratchet bar respectively, the other end of each second engaging spring is fixedly connected to the inner wall of the mounting box, a vertical plate is fixedly connected to an upper end of the locking ratchet bar, a mounting groove plate is arranged on an upper side of the locking ratchet bar, the mounting groove plate is fixedly connected to the inner wall of the mounting box, mounting grooves are formed in upper and lower sides of a surface of the mounting groove plate respectively, mounting sliders capable of moving left and right are slidably connected to an inside of the mounting grooves respectively, fitting springs are fixedly connected to left and right sides of the mounting sliders respectively, outer ends of the fitting springs are fixedly connected to inner walls of the mounting grooves respectively, a hinge pin is fixedly connected to rear ends of the mounting sliders respectively, a through rod is rotatably connected to a through rod, a front end and rear end of the through a swing guide rod, a guide rod is connected to the swing plate, and a guide rod is connected to the guide rod, and a swing plate, when the guide rod is fixed to the guide rod, when the guide rod, the guide rod is moved up and down, the guide rod is connected to the guide rod.

Preferably, a braking rack is arranged on the left side of the spiral grooved rod and fixedly connected with the inner wall of the mounting box, a braking tooth block capable of moving back and forth is slidably connected to the bottom of the reciprocating plate and is meshed with the braking tooth bar, a first meshing spring is fixedly connected to the front end of the braking tooth block, the front end of the first meshing spring is fixedly connected with the reciprocating plate, an operating plate is fixedly connected to the left end of the reciprocating plate and is slidably connected with the surface of the left end of the mounting box, an index is fixedly connected to the rear end of the operating plate, and scales are arranged on the rear side of the index and correspond to the surface of the mounting box.

The invention has novel structure, ingenious conception and simple and convenient operation, and compared with the prior art, the invention has the following advantages:

this device can carry out the state of mixing according to the required control mixing barrel of material when using, and then improve the mixing barrel and carry out the intensity that mixes to the material, can effectual improvement mixing effect, and can also control respectively according to the required churning time of material of difference and the speed of stirring, not only made things convenient for user's operation, and the controllability is stronger, the mixing effect of material has been strengthened and the required condition when can the different material of fully provided mixes, initial condition can all be replied to rolling disc and mixing barrel after stirring each time finishes, the person of facilitating the use injects new material or dismantles the mixing barrel into in to the mixing barrel, the person of facilitating the use uses, the later maintenance is simple, the cost is lower, application scope is extensive, the function is various.

Drawings

Fig. 1 is a first schematic view of an overall structure of a raw material mixing device for graphene production and processing according to the present invention.

Fig. 2 is a second schematic view of the overall structure of the raw material mixing device for graphene production and processing according to the present invention.

Fig. 3 is a schematic cross-sectional view of an internal structure of a mounting box of a raw material mixing device for graphene production and processing.

Fig. 4 is a schematic diagram of a driving structure of a driving disk and a driven disk of the raw material mixing device for graphene production and processing.

Fig. 5 is a schematic view of an installation structure of a spreading block of a raw material mixing device for graphene production and processing.

Fig. 6 is a schematic diagram of a driving rod transmission structure of the raw material mixing device for graphene production and processing.

Fig. 7 is a schematic view of a guide rod mounting structure of the raw material mixing device for graphene production and processing.

Fig. 8 is a schematic view of an installation structure of a rotating disk of the raw material mixing device for graphene production and processing.

Fig. 9 is a schematic diagram of a coil spring driving structure of a raw material mixing device for graphene production and processing according to the present invention.

Fig. 10 is a schematic view of a mounting structure of a mixing barrel of the raw material mixing device for graphene production and processing according to the present invention.

Fig. 11 is a schematic structural view of a sliding fixture block driving structure of the raw material mixing device for graphene production and processing.

Fig. 12 is a schematic view of a rotating structure of a rotating cylinder of the raw material mixing device for graphene production and processing according to the present invention.

Fig. 13 is a first schematic view of a power transmission structure of a raw material mixing device for graphene production and processing according to the present invention.

Fig. 14 is a second schematic view of a power transmission structure of the raw material mixing device for graphene production and processing according to the present invention.

Fig. 15 is a schematic view of a spiral groove rod transmission structure of the raw material mixing device for graphene production and processing.

Fig. 16 is a schematic view of a mounting structure of a braking tooth block of the raw material mixing device for graphene production and processing according to the present invention.

Fig. 17 is a schematic view of a mounting structure of a locking ratchet of a raw material mixing device for graphene production and processing according to the present invention.

Fig. 18 is a schematic view of an installation structure of a swing groove plate of the raw material mixing device for graphene production and processing according to the present invention.

Fig. 19 is a schematic diagram of a moving structure of a pressing plate of the raw material mixing device for graphene production and processing according to the present invention.

Reference numbers in the figures: 1-mounting box, 2-rotating disc, 3-mixing barrel, 4-main driving disc, 5-driven disc, 6-limiting plate, 7-driving worm, 8-driving knob, 9-driving worm wheel, 10-first driving pulley, 11-second driving pulley, 12-driving belt, 13-control shaft, 14-butt bevel gear, 15-lower bevel gear, 16-upper bevel gear, 17-motor, 18-control button, 19-driving barrel, 21-guide rod, 22-spreading block, 23-supporting rod, 24-hinged ring, 25-guide pin shaft, 26-connecting rod, 27-driving groove, 28-first face gear, 29-second face gear, 30-driving pinion, 31-reduction gear, bull gear 32-coil spring box, 33-reset coil spring, 34-lifting plate, 35-first reset spring, 36-push plate, 37-sliding fixture block, 38-fixing bolt, 39-arc spring, 40-arc ratchet bar, 41-butt ratchet block, 42-connecting sliding plate, 43-mounting guide plate, 44-second reset spring, 45-pull rod, 47-rotating cylinder, 48-rotating gear, 49-mounting shaft, 50-matching bevel gear, 51-bevel gear block, 52-mounting plate, 53-pressing plate, 54-third reset spring, 55-annular plate, 56-pin rod, 57-corresponding plate, 58-guide rack, 59-first matching belt wheel, 60-control plate, 61-second matching belt wheel, 62-spiral grooved rod, 63-reciprocating plate, 64-operating plate, 65-index, 66-braking rack, 67-matching pin shaft, 68-first meshing spring, 69-braking tooth block, 70-mounting grooved plate, 71-swinging grooved plate, 72-swinging plate, 73-mounting sliding block, 74-matching spring, 75-connecting pin shaft, 76-guide rod, 77-stopping ratchet rack, 78-second meshing spring, 79-stopping ratchet block, 80-tooth block, 81-matching gear, 82-rotating plate, 83-sliding grooved plate, 84-hinge plate, 85-connecting sliding block, 86-linkage spring, 87-pressing plate, 88-cam, 89-vertical plate, 90-first linkage bevel gear, 91-second linkage bevel gear, 92-scale and 93-pushing spring.

Detailed Description

The following are specific embodiments of the present invention, and the technical solutions of the present invention will be further described with reference to the drawings, but the present invention is not limited to these embodiments.

As shown in fig. 1 to 19, the present invention provides a raw material mixing device for graphene production and processing, including a mixing barrel 3, wherein a rotatable rotating disc 2 is installed at an outer side of the mixing barrel 3, an installation box 1 is installed at a lower side of the rotating disc 2, the rotating disc 2 is installed at an upper end of the installation box 1 in a vertical state, upper and lower sides of an inner side of the rotating disc 2 are respectively slidably connected with a sliding fixture block 37 capable of performing arc-shaped sliding with a center of the rotating disc 2 as a center, and the mixing barrel 3 is detachably installed between the two sliding fixture blocks 37; a driven disc 5 and a main driving disc 4 are respectively and sequentially connected to the left side and the right side of the lower end inside the mounting box 1 from left to right in a rotating mode, the lower end surfaces of the driven disc 5 and the main driving disc 4 are respectively and slidably connected with a spreading block 22 which can respectively perform gathering and scattering motions by taking the centers of the driven disc 5 and the main driving disc 4 as centers, the spreading blocks 22 on the lower end surfaces of the driven disc 5 and the main driving disc 4 can synchronously move and have opposite moving directions, the outer side surfaces of the driven disc 5 and the main driving disc 4 are jointly provided with a driving belt 12, the two ends of the driving belt 12 are sleeved on the outer side surfaces of the spreading blocks 22 on the lower end surfaces of the driven disc 5 and the main driving disc 4, the middle parts of the driven disc 5 and the main driving disc 4 are respectively and fixedly connected with a connecting rod 26, the upper side surface of the connecting rod 26 in the middle part of the driven disc 5 is slidably connected with a first end face gear 28 which can move up and down, an engageable second end face gear 29 is installed on the upper side of the first end face gear 28, and the second end face gear 29 is fixedly connected with the bottom of the rotating disc 2; the rear side of the rotating disc 2 is coaxially and rotatably connected with a mounting shaft 49 which can drive the sliding fixture block 37 to slide in an arc shape, the rear side of the surface of the mounting shaft 49 is fixedly connected with a matching bevel gear 50, the rear side of the upper end surface of the mounting box 1 is slidably connected with a mounting plate 52 which can move back and forth, and the upper end of the mounting plate 52 is fixedly connected with a bevel gear block 51 which can be meshed with the matching bevel gear 50; the right side in the mounting box 1 is provided with a power transmission structure capable of moving back and forth, the power transmission structure can push the first end face gear 28 to move upwards to be meshed with the second end face gear 29 when moving towards the rear side, the rear side of the mounting box 1 is rotatably connected with a rotatable spiral groove rod 62, when the power transmission structure moves towards the rear side, the power transmission structure can be connected with the spiral groove rod 62 and drive the spiral groove rod 62 to rotate, the surface of the spiral groove rod 62 is meshed with a reciprocating plate 63 capable of moving up and down, the reciprocating plate 63 is slidably connected with the inner wall of the mounting box 1, when the spiral groove rod 62 rotates in a reciprocating mode, the reciprocating plate 63 can be driven to move up and down, when the reciprocating plate 63 moves up and down, the spiral groove rod 62 can also be driven to rotate in a reciprocating mode, and when the reciprocating plate 63 moves downwards to the bottommost, the power transmission structure can be pushed to move towards the front side to reset.

The upper side, the lower side and the lower side of the surface of the mixing barrel 3 are respectively provided with a feeding hole and a discharging hole, when in use, materials can be poured into the mixing barrel 3 through the feeding hole, and the materials in the mixing barrel 3 can be taken out through the discharging hole, when the device is in use, the rotating disc 2 can rotate in the vertical state at the upper end of the mounting box 1, so that the mixing barrel 3 is driven to rotate by taking the axial direction of the diameter of the rotating disc 2 as a central line, and the effect of mixing the materials in the mixing barrel 3 is achieved; when the mixing barrel 3 rotates, the mounting shaft 49 can be rotated to drive the two sliding fixture blocks 37 to perform arc-shaped sliding around the center of the rotating disc 2, so as to drive the mixing barrel 3 to change from a vertical state to an inclined state, and further when the mixing barrel 3 continues to rotate around the diameter of the rotating disc 2 as the axis, the upper end and the lower end of the mixing barrel 3 are in a shaking state, so that the effect of enhancing the stirring strength of the materials in the mixing barrel 3 can be achieved, and further the stirring effect of the materials in the mixing barrel 3 can be enhanced, when the inclined state of the mixing barrel 3 is adjusted, the mounting plate 52 can be moved, the bottom of the mounting plate 52 is in sliding connection with the upper end of the mounting box 1, the front side of the bottom of the mounting plate 52 is fixedly connected with the third return spring 54, the other end of the third return spring 54 is fixedly connected with the mounting box 1, the rear end of the mounting plate 52 is fixedly connected with the pressing plate 53, the pressing plate 53 is used for pushing the bevel gear block 51 to move forwards and mesh with the mating bevel gear 50, the third return spring 54 is used for pushing the bevel block 51 to reset, and therefore, when the mounting plate 52 moves forwards and meshes with the bevel block 51 and further meshes with the mating bevel gear 50, so as to drive the mounting shaft 49 to perform sliding of the mixing barrel 3, and further to perform tilting; the rotating speed of mixing tub 3 may be controlled by the distance that the plurality of spreading blocks 22 at the lower end of driving disk 4 move outward, the moving directions of the plurality of spreading blocks 22 at the lower ends of driving disk 4 and driven disk 5 are opposite, moving outward or inward by controlling spreading blocks 22 corresponds to changing the diameters of driving disk 4 and driven disk 5, when the plurality of spreading blocks 22 at the lower end of driving disk 4 move outward synchronously, the plurality of spreading blocks 22 at the lower end of driven disk 5 move inward simultaneously, so that driving belt 12 may always cooperate with spreading blocks 22 at both sides, and while the rotating speed of driving disk 4 is fixed, when the distance that spreading blocks 22 at the lower end of driving disk 4 move outward is larger, the distance that spreading blocks 22 at the lower end of driven disk 5 move inward is larger, and when driving disk 4 drives driven disk 5 to rotate, the rotating speed of driven disk 5 is increased, and when spreading blocks 22 at the lower end of driving disk 4 move inward, spreading blocks 22 at the lower end of driven disk 5 move outward, and when driving disk 4 drives driven disk 5 to rotate, the larger rotating speed that driving disk 5 is increased, and when driving disk 4 drives driven disk 5 to rotate, the diameter of driven disk 5 is decreased, and when driving disk 4 drives driven disk 5, the diameter of driven disk 5 is decreased, and when driving disk 5 rotates, the diameter of driving disk 4 is increased, and when driving disk 5 is increased, the diameter of driving disk 5 is decreased, and when driving disk 5 is increased, the diameter of driving disk 5 is increased, and when driving disk 5 is increased, the diameter of driving disk 4 is increased, diameter of driving disk 5 is decreased, and when driving disk 5 is increased, diameter of driving disk 5 is decreased, and when driving disk 4 is increased, diameter of driving disk 5 is decreased, diameter of driving disk 5 is increased, diameter of driving disk 4 is decreased, diameter of driving disk 5 is increased, diameter of driving disk 5 is decreased, diameter of driving disk, and diameter of driving disk, diameter of driving disk 4 is decreased, diameter of driving disk 5 is decreased, and diameter of driving disk 5 is decreased, diameter of driving disk 4 is increased, and diameter of driving disk 4 is decreased; when the driven disc 5 rotates, the first end face gear 28 is controlled to move upwards to be meshed with the second end face gear 29, and then the rotating disc 2 can be driven to rotate; the power transmission structure is used for controlling the spiral groove rod 62 and the rotating disc 2 to rotate, when the power transmission structure moves towards the rear side, the power transmission structure can push the first end face gear 28 to move upwards to be meshed with the second end face gear 29, so that the rotating disc 2 can be driven to rotate, when the power transmission structure moves towards the rear side, the spiral groove rod 62 can be driven to rotate, the reciprocating plate 63 is used for controlling the rotation time of the rotating disc 2, when the power transmission structure moves towards the rear side, the time for the rotating disc 2 to rotate can be designated by moving the reciprocating plate 63 upwards, when the power transmission structure moves towards the rear side to enable the rotating disc 2 and the spiral groove rod 62 to rotate, the spiral groove is formed in the surface of the spiral groove rod 62, the upper end of the reciprocating plate 63 is fixedly connected with the matching pin shaft 67, the matching pin shaft 67 is in sliding fit with the spiral groove, and the reciprocating plate 63 can only move upwards and downwards under the sliding connection of the reciprocating plate 63 and the mounting box 1, when the spiral grooved bar 62 rotates, the reciprocating plate 63 can be continuously driven to move downwards through the sliding fit of the spiral groove and the matching pin shaft 67, when the reciprocating plate 63 moves to the lowest side again, the power transmission structure can be pushed to move backwards for resetting, when the power transmission structure moves backwards for resetting, the spiral grooved bar 62 stops rotating once the power transmission structure resets, the first end face gear 28 also moves downwards again for resetting, the first end face gear 28 and the second end face gear 29 are not meshed any more, the rotating disc 2 loses power for continuous rotation and resets, when the device is used, the device can be controlled according to the stirring time and the stirring intensity required by different materials, the operation of a user is facilitated, the controllability is stronger, the material mixing effect is enhanced, and the required conditions when different materials are mixed can be fully met, the function is various.

The lower side of the surface of the connecting rod 26 is respectively and slidably connected with a hinge ring 24 capable of moving up and down, the lower end of the spreading block 22 is respectively and hingedly connected with a support rod 23, the bottom of the support rod 23 is respectively and hingedly connected with the upper end of the hinge ring 24, the lower end of the hinge ring 24 is rotatably connected with a driving barrel 19 capable of moving up and down, the inner side surface of the driving barrel 19 is provided with an annular driving groove 27, the driving barrel 19 and the connecting rod 26 are coaxial, the surface of the driving barrel 19 is slidably connected with a limiting plate 6, the limiting plate 6 is fixedly connected with the inner wall of the mounting box 1, the lower end of the interior of the driving barrel 19 is provided with a guide rod 21, the bottom of the guide rod 21 is rotatably connected with the inner wall of the mounting box 1, the upper side of the surface of the guide rod 21 is fixedly connected with a guide pin shaft 25, and the guide pin shaft 25 is meshed with the driving groove 27; the surface downside of guide pole 21 is fixedly connected with first drive pulley 10 and second drive pulley 11 respectively, a first drive belt has been cup jointed jointly to the outside surface of first drive pulley 10 with second drive pulley 11, the surface downside fixedly connected with drive worm wheel 9 of guide pole 21 of main drive dish 4 downside, the meshing of one side of drive worm wheel 9 has drive worm 7, the front end of drive worm 7 with mounting box 1 surface rotates and connects, the front end fixedly connected with drive knob 8 of drive worm 7.

The driving knob 8 is used for controlling the rotating speed of the rotating disc 2, when the driving knob 8 rotates, the driving worm 7 is meshed with the driving worm wheel 9, the first driving belt wheel 10, the second driving belt wheel 11 and the first driving belt can drive the two guide rods 21 to rotate simultaneously, the driving groove 27 is of an inclined annular structure, when the guide rods 21 rotate, the driving cylinder 19 can be driven to move up and down through the sliding fit of the driving groove 27 and the guide pin shaft 25, when the driving cylinder 19 moves up and down, the hinge ring 24 can be driven to move up and down through the linkage of the supporting rod 23, and then the plurality of distraction blocks 22 are driven to synchronously move towards the inner side or towards the outer side, so that the rotating speed of the driven disc 5 is changed.

The surface of the first face gear 28 is rotatably connected with a lifting plate 34 capable of moving up and down, the lifting plate 34 is slidably connected with the inner wall of the mounting box 1, the upper end of the rear side of the lifting plate 34 is fixedly connected with a first return spring 35, the upper end of the first return spring 35 is fixedly connected with the inner wall of the mounting box 1, the right side inside the mounting box is provided with a control shaft 13 capable of moving back and forth, the surface of the control shaft 13 is rotatably connected with a push plate 36, the push plate 36 is slidably connected with the inner wall of the mounting box 1, the left end of the push plate 36 is positioned at the front side of the right end of the lifting plate 34, and when the control shaft 13 moves towards the rear side, the lifting plate 34 can be pushed to move upwards through the push plate 36; the upper end fixedly connected with transmission pinion 30 of second terminal surface gear 29, the right side meshing of transmission pinion 30 has speed reduction gear wheel 31, speed reduction gear wheel 31's downside is provided with coil spring box 32, coil spring box 32 with 1 inner wall fixed connection of mounting box, the inside of coil spring box 32 is provided with reset coil spring 33, reset coil spring 33's outer end in coil spring box 32 inner wall fixed connection, reset coil spring 33's the inner fixedly connected with axle that resets, reset the upper end both ends of axle respectively in coil spring box 32 surface rotation is connected, reset the axle the upper end with 31 middle part fixed connection of speed reduction gear wheel.

The rotating disc 2 is in a state that the mixing barrel 3 faces the right front direction in an initial state, and is used for facilitating a user to inject materials into the mixing barrel 3 and disassemble the mixing barrel 3, and the coil spring is used for driving the rotating disc 2 to reset after the rotating disc 2 rotates; the upper side of the rear end of the push plate 36 is provided with an inclined surface inclined to the front side, when the control shaft 13 moves to the rear side, the lift plate 34 can be directly pushed to move upwards through the inclined surface at the rear end of the push plate 36, when the lift plate 34 moves upwards, the first return spring 35 can be extruded and the first end face gear 28 can be driven to move upwards to be meshed with the second end face gear 29, so as to drive the rotating disc 2 to rotate, when the rotating disc 2 rotates, the coil spring can be driven to contract through the meshing of the transmission pinion 30 and the reduction gear 31, and the diameter of the transmission pinion 30 is smaller than that of the reduction gear 31, so that when the transmission pinion 30 rotates along with the rotating disc 2, the reduction gear 31 is in a deceleration rotation effect, and the coil spring is gradually driven to contract and overload during the continuous rotation of the rotating disc 2, and when the coil spring is disengaged from the first end face gear 28 and the second end face gear 29, the reduction gear 31 can be driven to rotate under the condition of absence of external force restriction, and the transmission pinion 30 can be accelerated to enable the rotating disc 2 to be quickly restored to the front side of the rotating disc 2, thereby facilitating the user to rapidly operate the mixing barrel.

Arc-shaped sliding grooves are respectively formed in two sides, corresponding to the end face of the rotating disc 2, of the sliding clamping block 37, the arc-shaped sliding grooves are respectively connected with the sliding clamping block in a sliding mode, arc-shaped springs 39 are respectively arranged inside the arc-shaped sliding grooves, two ends of each arc-shaped spring 39 are respectively fixedly connected with the corresponding sliding clamping block 37 and the inner wall of each arc-shaped sliding groove, the front end surface of each sliding clamping block 37 is respectively connected with a fixing bolt 38 in a threaded mode, and the inner end of each fixing bolt 38 is respectively attached to the upper end and the lower end of the corresponding mixing barrel 3; the two sides corresponding to the surface of the rear end of the rotating disc 2 are fixedly connected with arc ratchet bars 40 respectively, the inner sides of the arc ratchet bars 40 are engaged with butt-joint ratchet blocks 41 capable of moving synchronously respectively, the front end of the mounting shaft 49 is fixedly connected with a mounting guide plate 43, the upper and lower ends of the mounting guide plate 43 are slidably connected with connecting slide plates 42 capable of moving synchronously respectively, the front end of the connecting slide plate 42 is slidably connected with the rear end of the slide block 37 respectively, the inner ends of the two butt-joint ratchet blocks 41 are fixedly connected with the connecting slide plates 42 respectively, the inner ends of the two connecting slide plates 42 are fixedly connected with second return springs 44 respectively, the other ends of the second return springs 44 are fixedly connected with the surface of the mounting guide plate 43 respectively, the surface of the mounting shaft 49 is rotatably connected with a rotating cylinder 47, the upper and lower sides on the left side of the surface of the rotating cylinder 47 are hinged with tie rods 45 respectively, the other ends of the tie rods 45 are hinged with the connecting slide plates 42 respectively, the surface of the rotating cylinder 47 is fixedly connected with a rotating ring gear 48, one side of the rotating cylinder 48 is engaged with a guide rack 58 capable of moving up and down, the upper end of the linking plate 55 is slidably connected with the connecting rod 55, and the upper end of the linking plate 55 is slidably connected with the connecting ring gear 55.

Under the effect of threaded connection of the sliding fixture block 37, the fixing bolt 38 can drive the fixing bolt 38 to move inwards to extrude the mixing barrel 3 when the fixing bolt 38 is rotated, so that the effect of fixing the mixing barrel 3 is achieved; notches are respectively formed in the inner ends of the sliding fixture blocks 37, the upper end and the lower end of the mixing barrel 3 are respectively and fixedly connected with a fixture column, when the mixing barrel 3 is installed on the inner sides of the two sliding fixture blocks 37, the fixture columns are meshed with the notches, and therefore the fixing effect on the mixing barrel 3 and the stability of the mixing barrel 3 during rotation can be enhanced; the inner part of the arc chute is fixedly connected with an arc rod, the arc rod and the rotating disc 2 are coaxial, the arc spring 39 is sleeved on the surface of the arc rod, the arc spring 39 can be extruded when the sliding fixture block 37 slides, the sliding fixture block 37 moves by rotating the mounting shaft 49, the mounting guide plate 43 can be driven to swing when the mounting shaft 49 rotates, then the sliding fixture block 37 can be driven to slide under the drive of the connecting sliding plate 42, the connecting sliding plate 42 can drive the butt joint ratchet block 41 to move and be meshed with the arc ratchet rack 40 when swinging, the mounting shaft 49 can have the function of unidirectional rotation by the meshing of the butt joint ratchet block 41 and the arc ratchet rack 40, when the rotating disc 2 stops rotating, the connecting sliding plate 58 can be driven to move downwards by controlling the annular plate 55 to move and be meshed with the rotating gear 48, the rotating cylinder 47 can be driven to synchronously drive the two connecting sliding plates 42 to move inwards by the pulling of the pull rod 45 when the rotating cylinder 47 rotates, so that the butt joint ratchet block 41 and the arc rack 40 are disengaged, then the sliding fixture block 37 can be pushed back to the upper end of the sliding fixture block 37 and the vertical pin reset spring 44 can be connected with the second annular plate 44, and the vertical pin reset spring 44 respectively, and can be pushed back to the connecting spring and can be connected to the vertical pin and reset rod for resetting pin and can be connected with the second connecting barrel when the sliding rack 40.

The power transmission structure comprises a motor 17 fixedly connected to the right side inside the mounting box 1, an upper bevel gear 16 is fixedly connected to an output end of the lower side of the motor 17, a lower bevel gear 15 is arranged on the lower side of the upper bevel gear 16, the lower bevel gear 15 is fixedly connected to the upper end of a connecting rod 26 in the middle of the main drive disk 4, the control shaft 13 is located between the upper bevel gear 16 and the lower bevel gear 15, the front end of the control shaft 13 penetrates through the front end of the mounting box 1, a control button 18 is rotatably connected to the front end of the control shaft 13, a butt bevel gear 14 which can be respectively engaged with the upper bevel gear 16 and the lower bevel gear 15 is fixedly connected to the surface of the control shaft 13, a control plate 60 is rotatably connected to the rear end of the control shaft 13, the control plate 60 is slidably connected to the inner wall of the mounting box 1, a push spring 93 is fixedly connected to the rear side of the lower end of the control plate 60, the other end of the push spring 93 is fixedly connected to the inner wall of the mounting box 1, a second bevel gear 91 is rotatably connected to the lower end of the control plate 60, a belt pulley 61 is fixedly connected to the bottom of the spiral grooved rod 62, which is fixedly connected to the second bevel gear can be engaged with the second linkage gear 91, a belt pulley 90, and a belt pulley 59 is fixedly connected to the surface of the first bevel gear 59, and a belt pulley 59 which are co-matched with the first pulley 59.

The motor 17 is used for driving the rotating disc 2 and the spiral groove rod 62 to rotate, the control button 18 is used for pushing the power transmission structure to move towards the rear side, a user can drive the control shaft 13 to move towards the rear side by pushing the control button 18 when using the power transmission structure, the pushing spring 93 is used for driving the control shaft 13 to reset by pushing the control panel 60, when the control shaft 13 moves towards the rear side, the power transmitted by the motor 17 can be transmitted to the control shaft 13 and the lower bevel gear 15 by meshing the matching bevel gear 50 with the upper bevel gear 16 and the lower bevel gear 15 respectively, the main driving disc 4 can rotate when the lower bevel gear 15 rotates, when the control shaft 13 rotates, the second interlocking bevel gear 91 can be driven to rotate by the transmission of the first matching belt wheel 59, the second matching belt wheel 61 and the second driving belt, when the control shaft 13 moves towards the rear side, the first interlocking bevel gear 90 can be meshed with the second interlocking bevel gear 91, and when the second interlocking bevel gear 91 rotates, the spiral groove rod 62 can be driven to rotate by the meshing with the first interlocking bevel gear 90.

The left side fixedly connected with tooth piece 80 of control panel 60, the rear side of tooth piece 80 is provided with meshable cooperation gear 81, cooperation gear 81 with mounting box 1 inner wall rotates to be connected, the left end of cooperation gear 81 is with axle center fixedly connected with rotor plate 82, the left side of rotor plate 82 is provided with sliding groove board 83, sliding groove board 83 with mounting box 1 inner wall fixed connection, sliding groove board 83's surperficial sliding connection has connecting slider 85 that can reciprocate, connecting slider 85's upper end fixedly connected with interlock spring 86, the upper end of interlock spring 86 with sliding groove board 83 fixed connection, the rear side position on rotor plate 82's left end surface articulates there is articulated slab 84, the other end of articulated slab 84 with the interlock slider is articulated, the left end fixedly connected with clamp plate 87 of connecting slider 85, the rear side fixedly connected with of annular plate 55 corresponds board 57, the right-hand member that corresponds board 57 is located the downside of clamp plate 87.

When the control shaft 13 moves back and forth, the rotating plate 82 is driven to rotate by the meshing of the toothed block 80 and the matching gear 81, when the rotating plate 82 rotates, the connecting slide block 85 can be driven to move up and down by the interlocking of the hinge plate 84, when the control shaft 13 moves towards the rear side, the rotating plate 82 is driven to rotate by the meshing of the toothed block 80 and the matching gear 81, the connecting slide block 85 is pushed upwards and presses the interlocking spring 86 through the transmission of the hinge plate 84, the connecting slide block 85 does not influence the annular plate 55 when moving upwards, when the control shaft 13 moves towards the rear side and returns, the rotating plate 82 is driven to rotate reversely by the meshing of the toothed block 80 and the matching gear 81, when the rotating plate 82 rotates reversely, the connecting slide block 85 can be driven to move downwards by the hinge plate 84, when the connecting slide block 85 moves downwards, the corresponding plate 57 can be pushed downwards by the pressing plate 87, when the corresponding plate 57 moves downwards, the annular plate 55 can also move downwards in the same step, and further can drive the guide rack 58 to move downwards, so that the guide rack 58 is meshed with the rotating rack 48, when the rotating block 47 can drive the interlocking spring to return the rotating block 47 to rotate again, and return the second interlocking spring 47 when the corresponding plate 57 to return.

A stop ratchet block 79 is fixedly connected with the lower side of the left end of the control plate 60, a stop ratchet bar 77 which can move left and right is meshed with the left side of the stop ratchet block 79, the lower end of the stopping ratchet bar 77 is connected with the inner wall of the mounting box 1 in a sliding way, the front side and the rear side of the left end of the stopping ratchet bar 77 are respectively and fixedly connected with a second meshing spring 78, the other end of the second engaging spring 78 is fixedly connected with the inner wall of the mounting box 1, the upper end of the stopping ratchet bar 77 is fixedly connected with a vertical plate 89, the upper side of the stopping ratchet bar 77 is provided with an installation groove plate 70, the installation groove plate 70 is fixedly connected with the inner wall of the installation box 1, the upper and lower sides of the surface of the installation groove plate 70 are respectively provided with an installation sliding groove, the inside of the installation sliding groove is respectively connected with an installation sliding block 73 which can move left and right in a sliding way, the left side and the right side of the mounting slide block 73 are respectively fixedly connected with a matching spring 74, the outer end of the matching spring 74 is respectively fixedly connected with the inner wall of the mounting chute, the rear ends of the mounting sliders 73 are respectively and fixedly connected with connecting pin shafts 75, the middle part of the mounting groove plate 70 is rotatably connected with a through rod, the front end and the rear end of the through rod are respectively fixedly connected with a cam 88 and a swinging groove plate 71, the cam 88 is matched with the vertical plate 89, when the cam 88 is rotated to the left side, the stopping ratchet bar 77 can be pushed to move to the left side by pressing the vertical plate 89, the connecting pin shaft 75 is respectively connected with the upper side and the lower side of the swinging groove plate 71 in a sliding manner, the middle part of the rear end of the swinging groove plate 71 is fixedly connected with a swinging plate 72, a guide rod 76 is fixedly connected to the lower side of the front end of the reciprocating plate 63, the guide rod 76 is positioned at the lower side of the swinging plate 72, when the reciprocating plate 63 moves up and down, the swinging groove plate 71 can be driven to swing left and right through the matching of the guide rod 76 and the swinging plate 72.

Connecting grooves are respectively formed in the upper side and the lower side of the surface of the swing groove plate 71, the connecting pin shafts 75 are respectively in sliding fit with the connecting grooves, when the swing groove plate 71 swings left and right, the mounting sliding block 73 can be pushed to move through the sliding fit of the connecting grooves and the connecting pin shafts 75, the matching spring 74 is extruded, the swing groove plate 71 can also drive the cam 88 to rotate when swinging, and the matching spring 74 is used for pushing the swing groove plate 71 and the cam 88 to reset; the engagement of the stop ratchet block 79 and the stop ratchet bar 77 makes the control shaft 13 move only forward in one direction, for maintaining the transmission effect when the first end face gear 28 is engaged with the second end face gear 29 and the engagement effect of the first linkage bevel gear 90 and the second linkage bevel gear 91, and when the control shaft 13 moves backward, the control plate 60 extrudes the push spring 93, the rotation of the spiral grooved rod 62 can be reset by the downward movement of the reciprocating plate 63 to stop, when the reciprocating plate 63 moves upward, the guide rod 76 pushes the swinging plate 72 to swing upward, and when the swinging plate 72 swings upward, the upper end of the swinging grooved plate 71 swings to the right, so that the cam 88 rotates to the right side, and the stop ratchet bar 77 is not affected, that is, when the reciprocating plate 63 moves upward, the control shaft 13 is not affected; when the reciprocating plate 63 moves downwards to reset, the guide rod 76 pushes the swinging plate 72 to swing downwards, when the swinging plate 72 swings downwards, the upper end of the swinging groove plate 71 swings towards the left side and drives the cam 88 to rotate towards the left side, when the cam 88 rotates towards the left side, the stop ratchet bar 77 can be pushed towards the left side to move away from the stop ratchet block 79 and further the control plate 60 can move forwards to reset under the pushing of the pushing spring 93, therefore, when the reciprocating plate 63 moves downwards to the lowest point, the setting time of the rotation of the mixing barrel 3 by a user is indicated to be finished, and the stop ratchet bar 77 is disengaged from the stop ratchet block 79, the power transmission structure resets, the spiral groove rod 62 stops rotating, the rotating disk 2 also loses power, and is rapidly reset and stops rotating under the driving of the coil spring.

The left side of the spiral grooved rod 62 is provided with a braking rack 66, the braking rack 66 is fixedly connected with the inner wall of the installation box 1, the bottom of the reciprocating plate 63 is slidably connected with a braking tooth block 69 capable of moving back and forth, the braking tooth block 69 is meshed with the braking rack 66, the front end of the braking tooth block 69 is fixedly connected with a first meshing spring 68, the front end of the first meshing spring 68 is fixedly connected with the reciprocating plate 63, the left end of the reciprocating plate 63 is fixedly connected with an operation plate 64, the operation plate 64 is slidably connected with the surface of the left end of the installation box 1, the rear end of the operation plate 64 is fixedly connected with an index 65, and the surface of the installation box 1 at the rear side of the index 65 is correspondingly provided with scales 92.

The scale 92 can be set as a time scale 92, which is used for setting the time that the rotating disc 2 needs to rotate, the control panel 60 is used for facilitating the user to control the reciprocating plate 63 to move upwards, when the brake tooth block 69 is meshed with the brake tooth bar 66, the reciprocating plate 63 can be temporarily positioned, the situation that the reciprocating plate 63 moves downwards under the influence of gravity when the user moves the reciprocating plate 63 upwards through the movable operation panel 64 is avoided, the first meshing spring 68 is used for pushing the brake tooth block 69 to be meshed with the brake tooth bar 66, when the operation panel 64 moves upwards, the index 65 can also move upwards synchronously, the user can control the rotating time of the rotating disc 2 through the index 65 and the scale 92 correspondingly, and the use by the user is facilitated.

The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications or additions may be made to the described embodiments or alternatives may be employed by those skilled in the art without departing from the spirit or ambit of the invention as defined in the appended claims.

Claims (8)

1. The utility model provides a raw materials mixing arrangement is used in graphite alkene production and processing, includes blending tank (3), its characterized in that: a rotatable rotating disc (2) is mounted on the outer side of the mixing barrel (3), a mounting box (1) is mounted on the lower side of the rotating disc (2), the rotating disc (2) is mounted at the upper end of the mounting box (1) in a vertical state, sliding clamping blocks (37) capable of sliding in an arc shape with the center of the rotating disc (2) as the center are respectively connected to the upper side and the lower side of the inner side of the rotating disc (2) in a sliding mode, and the mixing barrel (3) is detachably mounted between the two sliding clamping blocks (37); the left side and the right side of the lower end in the mounting box (1) are respectively and sequentially connected with a driven disc (5) and a main driving disc (4) in a rotating mode from left to right, the lower end surfaces of the driven disc (5) and the main driving disc (4) are respectively and slidably connected with spreading blocks (22) which can respectively perform gathering and scattering motions by taking the centers of the driven disc (5) and the main driving disc (4) as centers, the spreading blocks (22) on the lower end surfaces of the driven disc (5) and the main driving disc (4) can synchronously move and have opposite moving directions, the outer side surfaces of the driven disc (5) and the main driving disc (4) are jointly provided with a driving belt (12), two ends of the driving belt (12) are sleeved on the outer side surfaces of the spreading blocks (22) on the lower end surfaces of the driven disc (5) and the main driving disc (4), the middle parts of the driven disc (5) and the main driving disc (4) are respectively and fixedly connected with a connecting rod (26), the upper side surface of the connecting rod (26) in the middle part of the driven disc (5) is slidably connected with a first end face gear (28) which can move up and down, the upper side gear (29) is connected with a second end face gear (29), and a rotating gear (29) which is meshed with a rotating disc; the rear side of the rotating disc (2) is coaxially and rotatably connected with a mounting shaft (49) which can drive the sliding clamping block (37) to slide in an arc shape, the rear side of the surface of the mounting shaft (49) is fixedly connected with a matched bevel gear (50), the rear side of the upper end surface of the mounting box (1) is movably connected with a mounting plate (52) which can move back and forth, and the upper end of the mounting plate (52) is fixedly connected with a bevel gear block (51) which can be meshed with the matched bevel gear (50); the power transmission structure capable of moving back and forth is installed on the right side inside the mounting box (1), the power transmission structure can push the first end face gear (28) to move upwards to be meshed with the second end face gear (29) when moving towards the rear side, the rear side of the mounting box (1) is rotatably connected with a spiral grooved rod (62), when the power transmission structure moves towards the rear side, the power transmission structure can be connected with the spiral grooved rod (62) and drive the spiral grooved rod (62) to rotate, a reciprocating plate (63) capable of moving up and down is meshed on the surface of the spiral grooved rod (62), the reciprocating plate (63) is slidably connected with the inner wall of the mounting box (1), when the spiral grooved rod (62) rotates in a reciprocating mode, the reciprocating plate (63) can be driven to move up and down, when the reciprocating plate (63) moves up and down, the spiral grooved rod (62) can be driven to rotate in a reciprocating mode, and when the reciprocating plate (63) moves down to the bottommost, the power transmission structure can be pushed to move forwards and reset.

2. The raw material mixing device for graphene production and processing according to claim 1, characterized in that: the lower side of the surface of the connecting rod (26) is respectively and slidably connected with a hinge ring (24) capable of moving up and down, the lower end of the strutting block (22) is respectively hinged with a supporting rod (23), the bottom of the supporting rod (23) is respectively hinged with the upper end of the hinge ring (24), the lower end of the hinge ring (24) is rotatably connected with a driving cylinder (19) capable of moving up and down, the inner side surface of the driving cylinder (19) is provided with an annular driving groove (27), the driving cylinder (19) and the connecting rod (26) are coaxial, the surface of the driving cylinder (19) is slidably connected with a limiting plate (6), the limiting plate (6) is fixedly connected with the inner wall of the mounting box (1), the lower end of the inner part of the driving cylinder (19) is provided with a guide rod (21), the bottom of the guide rod (21) is rotatably connected with the inner wall of the mounting box (1), the upper side of the surface of the guide rod (21) is fixedly connected with a guide pin shaft (25), and the guide pin shaft (25) is meshed with the driving groove (27); the utility model discloses a drive worm, including leading pole (21), the surperficial downside of leading pole (21) is the first drive pulley (10) of fixedly connected with and second drive pulley (11) respectively, first drive pulley (10) with a first drive belt has been cup jointed jointly to the outside surface of second drive pulley (11), the surperficial downside fixedly connected with drive worm wheel (9) of leading pole (21) of main drive dish (4) downside, the meshing of one side of drive worm wheel (9) has drive worm (7), the front end of drive worm (7) with mounting box (1) surface rotation is connected, the front end fixedly connected with drive knob (8) of drive worm (7).

3. The raw material mixing device for graphene production and processing according to claim 1, characterized in that: the surface of the first end face gear (28) is rotatably connected with a lifting plate (34) capable of moving up and down, the lifting plate (34) is connected with the inner wall of the mounting box (1) in a sliding mode, the upper end of the rear side of the lifting plate (34) is fixedly connected with a first return spring (35), the upper end of the first return spring (35) is fixedly connected with the inner wall of the mounting box (1), a control shaft (13) capable of moving back and forth is mounted on the right side inside the mounting box, the surface of the control shaft (13) is rotatably connected with a push plate (36), the push plate (36) is connected with the inner wall of the mounting box (1) in a sliding mode, the left end of the push plate (36) is located on the front side of the right end of the lifting plate (34), and when the control shaft (13) moves towards the rear side, the lifting plate (34) can be pushed to move upwards through the push plate (36); the upper end fixedly connected with transmission pinion (30) of second terminal surface gear (29), the right side meshing of transmission pinion (30) has speed reduction gear wheel (31), the downside of speed reduction gear wheel (31) is provided with coil spring box (32), coil spring box (32) with mounting box (1) inner wall fixed connection, the inside of coil spring box (32) is provided with reset coil spring (33), the outer end of reset coil spring (33) in coil spring box (32) inner wall fixed connection, the inner fixedly connected with reset shaft of reset coil spring (33), the upper end both ends of reset shaft respectively in coil spring box (32) surface rotation is connected, the upper end of reset shaft with speed reduction gear wheel (31) middle part fixed connection.

4. The raw material mixing device for graphene production and processing according to claim 1, characterized in that: arc-shaped sliding grooves are formed in two sides, corresponding to the end face of the rotating disc (2), of the rotating disc respectively, the sliding clamping blocks (37) are connected with the arc-shaped sliding grooves in a sliding mode respectively, arc-shaped springs (39) are arranged inside the arc-shaped sliding grooves respectively, two ends of each arc-shaped spring (39) are fixedly connected with the corresponding sliding clamping block (37) and the inner wall of the corresponding arc-shaped sliding groove respectively, the front end surface of each sliding clamping block (37) is connected with a fixing bolt (38) in a threaded mode respectively, and the inner end of each fixing bolt (38) is attached to the upper end and the lower end of the corresponding mixing barrel (3) respectively; the two sides corresponding to the surface of the rear end of the rotating disc (2) are respectively fixedly connected with arc-shaped ratchet bars (40), the inner sides of the arc-shaped ratchet bars (40) are respectively engaged with butt joint ratchet blocks (41) capable of moving synchronously, the front end of the installation shaft (49) is fixedly connected with installation guide plates (43), the upper end and the lower end of each installation guide plate (43) are respectively connected with connecting sliding plates (42) capable of moving synchronously in a sliding manner, the front ends of the connecting sliding plates (42) are respectively connected with the rear ends of the sliding blocks (37) in a sliding manner, the inner ends of the two connecting sliding plates (42) are respectively and fixedly connected with second reset springs (44), the other ends of the second reset springs (44) are respectively and fixedly connected with the surfaces of the installation guide plates (43), the inner ends of the two butt joint ratchet blocks (41) are respectively and fixedly connected with the connecting sliding plates (42), the surface of the installation shaft (49) is rotatably connected with rotating cylinders (47), the upper side and the lower side of the left side of the rotating cylinder (47) are respectively hinged with pull rods (45), the other ends of the rotating cylinders (47) are respectively hinged with the connecting sliding plates (42), the fixed surfaces of the rotating gears (47), and the rotating rack gears (48) are meshed with rotating rack guide frames (58), and one side of the rotating rack (48) capable of moving rack (58) capable of moving up and down, the linkage frame is connected with the surface of the guide rack (58) in a sliding mode, the upper end of the mounting box (1) is connected with a ring-shaped plate (55) capable of moving up and down in a sliding mode, the ring-shaped plate (55) and the connecting rod (26) are coaxial, and the bottom of the guide rack (58) is connected with the inner side of the ring-shaped plate (55) in a sliding mode.

5. The raw material mixing device for graphene production and processing according to claim 1, characterized in that: the power transmission structure comprises a motor (17) fixedly connected to the right side in the mounting box (1), an output end of the lower side of the motor (17) is fixedly connected with an upper bevel gear (16), a lower bevel gear (15) is arranged on the lower side of the upper bevel gear (16), the lower bevel gear (15) is fixedly connected with the upper end of a connecting rod (26) in the middle of the main driving disk (4), the control shaft (13) is positioned between the upper bevel gear (16) and the lower bevel gear (15), the front end of the control shaft (13) penetrates through the front end of the mounting box (1), and the front end of the control shaft (13) is rotatably connected with a control button (18), the surface of the control shaft (13) is fixedly connected with a butt bevel gear (14) which can be meshed with an upper bevel gear (16) and a lower bevel gear (15) respectively, the rear end of the control shaft (13) is rotatably connected with a control plate (60), the control plate (60) is in sliding connection with the inner wall of the mounting box (1), the rear side of the lower end of the control plate (60) is fixedly connected with a pushing spring (93), the other end of the pushing spring (93) is fixedly connected with the inner wall of the mounting box (1), the lower end of the control plate (60) is rotatably connected with a second linkage bevel gear (91), and the bottom of the spiral grooved bar (62) is fixedly connected with a first linkage bevel gear which can be meshed with the second linkage bevel gear (91) (90) The front end of the second linkage bevel gear (91) is coaxially and fixedly connected with a second matching belt wheel (61), the rear side of the surface of the control shaft (13) is fixedly connected with a first matching belt wheel (59), and a second transmission belt is sleeved on the surfaces of the first matching belt wheel (59) and the second matching belt wheel (61) together.

6. The raw material mixing device for graphene production and processing according to claim 5, wherein: the left side fixedly connected with tooth piece (80) of control panel (60), the rear side of tooth piece (80) is provided with meshable cooperation gear (81), cooperation gear (81) with mounting box (1) inner wall rotates and connects, the left end of cooperation gear (81) is with axle center fixedly connected with rotor plate (82), the left side of rotor plate (82) is provided with sliding groove board (83), sliding groove board (83) with mounting box (1) inner wall fixed connection, sliding groove board's (83) surperficial sliding connection has connecting slider (85) that can reciprocate, connecting slider's (85) upper end fixedly connected with interlock spring (86), the upper end of interlock spring (86) with sliding groove board (83) fixed connection, the rear side position on the left end surface of rotor plate (82) articulates there is articulated slab (84), the other end of articulated slab (84) with the interlock slider articulates, connecting slider's (85) left side is connected with clamp plate (87), the rear side fixed connection of annular plate (55) corresponds board (57), the right-hand end that corresponds board (57) is located the downside of clamp plate (87).

7. The raw material mixing device for graphene production and processing according to claim 5, wherein: a stop ratchet block (79) is fixedly connected to the lower side of the left end of the control plate (60), a stop ratchet bar (77) capable of moving left and right is meshed to the left side of the stop ratchet block (79), the lower end of the stop ratchet bar (77) is slidably connected with the inner wall of the mounting box (1), second meshing springs (78) are fixedly connected to the front side and the rear side of the left end of the stop ratchet bar (77) respectively, the other end of each second meshing spring (78) is fixedly connected with the inner wall of the mounting box (1), a vertical plate (89) is fixedly connected to the upper end of the stop ratchet bar (77), a mounting groove plate (70) is arranged on the upper side of the stop ratchet bar (77), the mounting groove plate (70) is fixedly connected with the inner wall of the mounting box (1), mounting sliding grooves are respectively formed in the upper side and the lower side of the surface of the mounting groove plate (70), mounting sliders (73) capable of moving left and right sides are respectively and fixedly connected with matching springs (74), the outer ends of the matching springs (74) are fixedly connected with the mounting grooves (73), a mounting slider (73) is fixedly connected with a swinging rod (71) which is fixedly connected with a swinging rod, and a swinging rod (71) which is connected with the front and rear end of a pin shaft (88), the cam (88) is matched with the vertical plate (89), when the cam (88) rotates towards the left side, the stop ratchet rack (77) can be pushed to move towards the left side through extruding the vertical plate (89), the connecting pin shaft (75) is respectively connected with the upper side and the lower side of the swing groove plate (71) in a sliding mode, the middle of the rear end of the swing groove plate (71) is fixedly connected with a swing plate (72), the lower side of the front end of the reciprocating plate (63) is fixedly connected with a guide rod (76), the guide rod (76) is located on the lower side of the swing plate (72), and when the reciprocating plate (63) moves up and down, the guide rod (76) and the swing plate (72) can be matched to drive the swing groove plate (71) to swing left and right.

8. The raw material mixing device for graphene production and processing according to claim 1, characterized in that: the left side of spiral grooved bar (62) is provided with braking rack (66), braking rack (66) with mounting box (1) inner wall fixed connection, the bottom sliding connection of reciprocating plate (63) has braking tooth piece (69) that can the back-and-forth movement, braking tooth piece (69) and braking tooth strip (66) meshing, the front end fixed connection of braking tooth piece (69) has first meshing spring (68), the front end of first meshing spring (68) with reciprocating plate (63) fixed connection, the left end fixed connection of reciprocating plate (63) has operation panel (64), operation panel (64) with the left end surface sliding connection of mounting box (1), the rear end fixed connection of operation panel (64) has index (65), the index (65) rear side the corresponding scale (92) that is provided with in mounting box (1) surface.

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