CN110743449A

CN110743449A - Lubricating oil graphite coupling dispersion devices

Info

Publication number: CN110743449A
Application number: CN201911040650.8A
Authority: CN
Inventors: 鞠成钢
Original assignee: Individual
Current assignee: Individual
Priority date: 2019-10-30
Filing date: 2019-10-30
Publication date: 2020-02-04

Abstract

The invention discloses a lubricating oil graphite coupling dispersing device, which relates to the field of graphene lubricating oil processing, and comprises a graphite grinding device, a lubricating oil mixing and stirring device, a telescopic grinding assembly, an intermittent blanking control device, a stirring mechanism and a linkage material blocking assembly. Graphite grinder fixed connection is on lubricating oil mixing stirring device, and flexible grinding component's upper end normal running fit connects on graphite grinder, and flexible grinding component's upper end is connected with graphite grinder transmission, and intermittent type unloading controlling means fixed connection is on graphite grinder, and intermittent type unloading controlling means's upper end is connected with flexible grinding component's upper end meshing transmission, and intermittent type unloading controlling means's lower extreme and flexible grinding component's middle part clearance fit are connected.

Description

Lubricating oil graphite coupling dispersion devices

Technical Field

The invention relates to the field of graphene lubricating oil processing, in particular to a graphite coupling and dispersing device for lubricating oil.

Background

The utility model discloses a filtration and dispersion device for graphene lubricating oil, which has the prior patent number of CN201820396442.6, and comprises a base and a reaction kettle, wherein the base is provided with a turntable, and the reaction kettle is arranged on the turntable; a support column, a first filter screen disc and a second filter screen disc are arranged in the reaction kettle; the supporting column is vertically arranged, and the first filter screen disc and the second filter screen disc are fixedly arranged on the supporting column; the top of reation kettle is equipped with the inlet pipe, the mouth of pipe of inlet pipe first filter screen dish is relative. The utility model discloses a simple structure for the dispersion technology of graphite alkene lubricating oil, make the mixture of graphite alkene lubricating oil more even. However, the apparatus cannot grind graphite into smaller particles and cannot intermittently charge graphite.

Disclosure of Invention

The invention aims to provide a lubricating oil graphite coupling dispersing device which has the beneficial effects that the dispersing graphite can be ground into small particles with uniform sizes, the mixing is convenient, and meanwhile, the ground graphite can be intermittently added into lubricating oil, so that the mixing effect is improved.

The purpose of the invention is realized by the following technical scheme:

a lubricating oil graphite coupling dispersion device comprises a graphite grinding device, a lubricating oil mixing and stirring device, a telescopic grinding assembly, an intermittent blanking control device, a stirring mechanism and a linkage material blocking assembly, wherein the graphite grinding device is fixedly connected onto the lubricating oil mixing and stirring device, the upper end of the telescopic grinding assembly is connected onto the graphite grinding device in a rotating fit manner, the upper end of the telescopic grinding assembly is in transmission connection with the graphite grinding device, the intermittent blanking control device is fixedly connected onto the graphite grinding device, the upper end of the intermittent blanking control device is in transmission connection with the upper end of the telescopic grinding assembly in a meshing manner, the lower end of the intermittent blanking control device is in clearance fit connection with the middle of the telescopic grinding assembly, the lower end of the telescopic grinding assembly is in sliding fit connection with the stirring mechanism, the stirring mechanism is in rotating fit connection with the lubricating oil mixing and stirring device, the stirring mechanism is in transmission connection with, the linkage material blocking assembly is provided with six, the six linkage material blocking assemblies are fixedly connected to the inner wall of the graphite grinding device in a surrounding mode, the six linkage material blocking assemblies form a closed circular ring structure, the six linkage material blocking assemblies are attached to the telescopic grinding assembly, and the six linkage material blocking assemblies are connected with the telescopic grinding assembly in a meshing transmission mode.

As further optimization of the technical scheme, the graphite coupling and dispersing device for the lubricating oil comprises a graphite grinding device, a graphite grinding device and a graphite grinding device, wherein the graphite grinding device comprises a grinding cylinder, a pipe seat, a feeding pipe, an inclined plate, a transverse frame plate, a motor frame, a motor, a driving belt wheel and an inverted frustum-shaped fixed grinding seat; grinding vessel sealing fixed connection is on lubricating oil mixing stirring device, tube socket fixed connection is at the front end of grinding vessel, inlet pipe fixed connection is on the tube socket, two swash plate symmetry fixed connection are in the upper end of grinding vessel, horizontal frame plate fixed connection is on two swash plates, motor frame fixed connection is at the middle part of horizontal frame plate, motor fixed connection is on the motor frame, driving pulley fixed connection is on the output shaft of motor, fixed grinding seat fixed connection is on the inner wall of grinding vessel.

As a further optimization of the technical scheme, the lubricating oil graphite coupling dispersing device comprises a mixing drum, an oil inlet pipe, an oil discharge pipe, an annular slide rail, an L-shaped connecting plate and a gear ring; sealed fixed connection of grinding vessel is in the upper end of churn, advances oil pipe and arranges oil pipe fixed connection respectively at the upper and lower both ends of churn, advances oil pipe and arranges oil pipe all with the inside intercommunication of churn, and annular slide rail fixed connection is in the upper end of churn inner wall, and four L type connecting plates of fixed connection are evenly encircleed to the outer end of ring gear, and four L type connecting plates are fixed connection in the upper end of annular slide rail all.

As a further optimization of the technical scheme, the lubricating oil graphite coupling dispersing device comprises a telescopic grinding assembly, a rotating shaft sleeve, a driven belt pulley, a driving bevel gear, a telescopic shaft, an upper slide block, a lower slide block, an upper slide block chute, a grooved pulley, a sleeve, a truncated cone-shaped blanking seat, an annular transition plate, a first inverted truncated cone-shaped grinding plate, a second inverted truncated cone-shaped grinding plate, a rack, an annular groove and a linkage block, wherein the upper slide block is arranged on the upper slide block chute; the middle part of a rotating shaft sleeve is rotatably connected to the middle part of a cross frame plate through a belt seat bearing, a driven belt pulley and a driving bevel gear are fixedly connected to the upper end of the rotating shaft sleeve, the driven belt pulley and the driving belt pulley are in transmission connection through a belt, the driving bevel gear is in meshing transmission connection with an intermittent blanking control device, an expansion shaft is in sliding fit connection with the inside of the rotating shaft sleeve, an upper sliding block and a lower sliding block are respectively fixedly connected to the upper end and the lower end of the expansion shaft, an upper sliding block sliding groove is formed in the lower end of the rotating shaft sleeve, an upper sliding block sliding fit is connected to the inside of the upper sliding block sliding groove, a grooved pulley and a sleeve are sequentially and fixedly connected to the middle part of the expansion shaft from top to bottom, the upper end of a circular truncated cone-shaped blanking seat is fixedly connected to the upper end of the sleeve, the upper end and the lower end of an annular transition plate are; an annular groove is formed in the outer ring of the annular transition plate, six linkage blocks are uniformly connected in the annular groove in a surrounding sliding fit mode, and the upper ends of the six annular grooves are fixedly connected with a rack; the rack is in meshing transmission connection with the linkage material blocking assembly; the lower end of the feeding pipe is positioned above the circular truncated cone-shaped blanking seat and on the inner side of the linkage material blocking assembly; the first inverted circular truncated cone-shaped grinding plate and the second inverted circular truncated cone-shaped grinding plate are both positioned on the inner side of the fixed grinding seat.

As further optimization of the technical scheme, the lubricating oil graphite coupling dispersing device comprises an intermittent blanking control device, a feeding device and a discharging device, wherein the intermittent blanking control device comprises an L-shaped frame plate, a disc shaft, a driven bevel gear, a disc, a short shaft, a swing rod, a hinge shaft, a door-shaped frame, a shifting fork, a sliding sleeve and a C-shaped frame; l type frame plate fixed connection is on the cross brace board, the middle-end of disc axle is rotated through the rolling bearing and is connected on L type frame plate, driven bevel gear and disc are fixed connection respectively at the both ends of disc axle, the disc axle is connected with the transmission of drive bevel gear meshing, minor axis fixed connection is in the eccentric position of disc, the upper and lower both ends of pendulum rod are rotated respectively and are connected minor axis and articulated shaft, the articulated shaft normal running fit is connected at the middle-end of door style of calligraphy frame, the equal fixed connection shift fork in both ends of door style of calligraphy frame, the equal clearance fit of inboard of two shift forks is connected in the sheave, the equal sliding sleeve of fixed connection in the outer end of two shift forks, the equal sliding fit of two sliding sleeves connects C type frame, the upper end of two C type frames is fixed connection respectively on two swash plates, the equal fixed connection of lower.

As a further optimization of the technical scheme, the lubricating oil graphite coupling dispersing device comprises a stirring mechanism, a stirring mechanism and a stirring mechanism, wherein the stirring mechanism comprises a lower shaft sleeve, a lower sliding block chute, a bottom frame plate, a blade rotating shaft, a spiral stirring blade, a driven belt wheel, a driving belt wheel, a gear I, a stirring shaft, a stirring plate and a C-shaped sliding seat; the lower end of the lower shaft sleeve is rotatably connected to the central position of the bottom surface of the mixing drum through a bearing with a seat, the lower end of the lower shaft sleeve is provided with a lower sliding block sliding groove, the lower end of the telescopic shaft is connected in the lower shaft sleeve in a sliding fit manner, the lower sliding block is connected in the lower sliding block sliding groove in a sliding fit manner, the bottom frame plate is fixedly connected to the upper end of the lower shaft sleeve, the two blade rotating shafts are respectively rotatably connected to the two ends of the bottom frame plate through the bearing with a seat, and the two stirring shafts are respectively rotatably connected to the outer; the upper end and the lower end of the blade rotating shaft are respectively fixedly connected with a driven belt wheel and a spiral stirring blade, a driving belt wheel and a gear I are fixedly connected to the upper end of the stirring shaft, the gear I is in meshed transmission connection with teeth on the inner side of the gear ring, and a plurality of stirring plates are fixedly connected to the lower end of the stirring shaft; the both ends of chassis board are C type slide of fixed connection all, and two C type slides are all sliding fit connection on annular slide rail.

As a further optimization of the technical scheme, the graphite coupling dispersing device for the lubricating oil comprises a linkage material blocking assembly and a material blocking part, wherein the linkage material blocking assembly comprises a linkage seat and a material blocking part; linkage seat fixed connection is on the inner wall of grinding vessel, and the linkage seat is located the top of fixed grinding seat, and the outer end that keeps off the material piece is connected in the linkage seat, and the lower extreme laminating that keeps off the material piece is on round platform shape blanking seat.

As further optimization of the technical scheme, the lubricating oil graphite coupling dispersing device comprises a linkage seat, a transmission mechanism and a control mechanism, wherein the linkage seat comprises a hollow rectangular seat, a shaft seat plate, a threaded rod and a gear II; the hollow rectangular seat is fixedly connected to the inner wall of the grinding cylinder, the two shaft seat plates are respectively and fixedly connected to the inner side and the outer side of the hollow rectangular seat, two ends of the threaded rod are respectively and rotatably connected to the two shaft seat plates through bearings with seats, and the gear II is fixedly connected to the outer side of the threaded rod; the rack is connected to the hollow rectangular seat in a sliding fit mode and is in meshed transmission connection with the gear II.

As a further optimization of the technical scheme, the graphite coupling dispersing device for the lubricating oil comprises a material blocking member, a guide plate, a connecting seat and a rectangular plate, wherein the material blocking member comprises an arc material blocking plate, an arc rubber pad, an upper baffle plate, a connecting seat and a rectangular plate; the upper and lower both ends of arc striker plate are fixed connection upper baffle plate and arc rubber pad respectively, and the lower extreme laminating of arc rubber pad is on round platform shape blanking seat, two connecting seats of outside fixed connection of arc striker plate, and rectangular plate fixed connection is on two connecting seats, and rectangular plate sliding fit connects in the grinding vessel, and the rectangular plate passes through screw-thread fit to be connected on the threaded rod, and the slope of arc striker plate from interior to exterior top to one side.

As a further optimization of the technical scheme, the lubricating oil graphite coupling dispersing device of the invention is characterized in that the taper of the first inverted circular truncated cone-shaped grinding plate is smaller than that of the second inverted circular truncated cone-shaped grinding plate, and the taper of the second inverted circular truncated cone-shaped grinding plate is equal to that of the fixed grinding seat; the diameter of the outer ring of the annular transition plate is smaller than that of the inner ring of the grinding cylinder.

The lubricating oil graphite coupling dispersing device has the beneficial effects that:

according to the lubricating oil graphite coupling dispersing device, graphite can be dispersed more uniformly by the aid of the telescopic grinding assembly, dispersed graphite can be ground into small particles with uniform sizes by the aid of the telescopic grinding assembly and the inverted-truncated-cone-shaped fixed grinding seat, graphene dispersing effects can be obviously improved, the graphite can be dispersed in lubricating oil more uniformly and stably, mixing is facilitated, ground graphite can be intermittently added into the lubricating oil, and mixing effects are improved.

Drawings

FIG. 1 is a first schematic structural diagram of a graphite-coupled lubricant dispersing apparatus according to the present invention;

FIG. 2 is a schematic structural diagram of a graphite-coupled lubricant dispersing device according to the present invention;

FIG. 3 is a schematic cross-sectional view of a graphite lubricant coupling and dispersing device according to the present invention;

FIG. 4 is a schematic diagram of the internal structure of a graphite lubricant coupling and dispersing device according to the present invention;

FIG. 5 is a schematic view of a graphite grinding apparatus;

FIG. 6 is a schematic cross-sectional view of a graphite grinding apparatus;

FIG. 7 is a schematic structural view of a lubricating oil mixing and stirring device;

FIG. 8 is a schematic view of a retractable polishing assembly;

FIG. 9 is a schematic cross-sectional view of a retractable grinding assembly;

FIG. 10 is a schematic structural diagram of an intermittent blanking control device;

FIG. 11 is a schematic structural view of a stirring mechanism;

fig. 12 is a schematic structural view of the linkage stop assembly;

FIG. 13 is a schematic structural view of a linkage seat;

fig. 14 is a schematic structural view of the material blocking member.

In the figure: a graphite grinding device 1; 1-1 of a grinding cylinder; a tube holder 1-2; a feed pipe 1-3; 1-4 of an inclined plate; 1-5 of a transverse frame plate; 1-6 of a motor frame; 1-7 of a motor; 1-8 of a driving belt wheel; 1-9 of a fixed grinding seat in the shape of an inverted frustum; a lubricating oil mixing and stirring device 2; 2-1 of a mixing drum; 2-2 parts of an oil inlet pipe; 2-3 of an oil discharge pipe; 2-4 of an annular slide rail; 2-5 of an L-shaped connecting plate; 2-6 parts of gear ring; a telescopic grinding assembly 3; a rotating shaft sleeve 3-1; a driven pulley 3-2; 3-3 of a drive bevel gear; 3-4 of a telescopic shaft; 3-5 parts of an upper sliding block; 3-6 parts of a lower sliding block; 3-7 of an upper sliding block sliding groove; 3-8 grooved wheels; 3-9 parts of a sleeve; 3-10 parts of a circular truncated cone-shaped blanking seat; 3-11 parts of an annular transition plate; a first reverse circular truncated cone-shaped polishing plate 3-12; a second inverted circular truncated cone-shaped grinding plate 3-13; racks 3-14; 3-15 parts of annular groove; 3-16 of linkage blocks; an intermittent blanking control device 4; 4-1 of an L-shaped frame plate; a disc shaft 4-2; a driven bevel gear 4-3; 4-4 of a disc; the short shaft is 4-5; 4-6 of a swing rod; 4-7 of a hinged shaft; 4-8 of a portal frame; 4-9 of a shifting fork; 4-10 parts of a sliding sleeve; 4-11 parts of a C-shaped frame; a stirring mechanism 5; 5-1 of a lower shaft sleeve; a lower sliding block chute 5-2; 5-3 of a bottom frame plate; 5-4 of a blade rotating shaft; 5-5 parts of spiral stirring blades; 5-6 parts of a driven belt wheel; 5-7 of a driving belt wheel; 5-8 parts of a gear I; 5-9 parts of a stirring shaft; 5-10 parts of a stirring plate; 5-11 of a C-shaped sliding seat; the linkage material blocking component 6; a linkage seat 6-1; a hollow rectangular seat 6-1-1; a bearing plate 6-1-2; 6-1-3 parts of threaded rod; gear II 6-1-4; a material blocking part 6-2; the arc-shaped material baffle 6-2-1; 6-2-2 parts of an arc-shaped rubber pad; an upper baffle 6-2-3; 6-2-4 of a connecting seat; rectangular plate 6-2-5.

Detailed Description

The invention is described in further detail below with reference to figures 1-14 and the detailed description.

The first embodiment is as follows:

the embodiment is described below with reference to fig. 1 to 14, a lubricating oil graphite coupling dispersing device, which comprises a graphite grinding device 1, a lubricating oil mixing and stirring device 2, a telescopic grinding assembly 3, an intermittent blanking control device 4, a stirring mechanism 5 and a linkage material blocking assembly 6, wherein the graphite grinding device 1 is fixedly connected to the lubricating oil mixing and stirring device 2, the upper end of the telescopic grinding assembly 3 is rotatably connected to the graphite grinding device 1, the upper end of the telescopic grinding assembly 3 is in transmission connection with the graphite grinding device 1, the intermittent blanking control device 4 is fixedly connected to the graphite grinding device 1, the upper end of the intermittent blanking control device 4 is in meshing transmission connection with the upper end of the telescopic grinding assembly 3, the lower end of the intermittent blanking control device 4 is in clearance fit connection with the middle of the telescopic grinding assembly 3, and the lower end of the telescopic grinding assembly 3 is in sliding fit connection with the

stirring mechanism

5, 5 normal running fit of rabbling mechanism connects in lubricating oil mixing stirring device 2, the rabbling mechanism 5 is connected with the 2 meshing transmissions of lubricating oil mixing stirring device, linkage fender material subassembly 6 is provided with six, six linkage fender material subassemblies 6 encircle fixed connection on graphite grinder 1's inner wall, six linkage fender material subassemblies 6 form confined ring structure, six linkage fender material subassemblies 6 all laminate with flexible grinding assembly 3, six linkage fender material subassemblies 6 all are connected with flexible grinding assembly 3 meshing transmissions. When the invention is used, lubricating oil is poured into a lubricating oil mixing and stirring device 2, graphite is introduced into a graphite grinding device 1 through a feeding pipe and a graphite grinding assembly 3, the graphite falls on a telescopic grinding assembly 3, after the graphite grinding device 1 is electrified and started, the graphite grinding device 1 drives the telescopic grinding assembly 3 to rotate, the telescopic grinding assembly 3 rotating under the action of gravity and centrifugal force drives the graphite to be uniformly dispersed, the telescopic grinding assembly 3 drives an intermittent blanking control device 4 to work, the intermittent blanking control device 4 drives the telescopic grinding assembly 3 to move up and down, when the telescopic grinding assembly 3 moves upwards, the telescopic grinding assembly 3 drives six linkage material blocking assemblies 6 to be far away from the telescopic grinding assembly 3, the graphite falls between the telescopic grinding assembly 3 and the graphite grinding device 1 through a gap between the linkage material blocking assembly 6 and the

telescopic grinding assembly

3, 3 downstream of flexible grinding component, the laminating of six linkage material stopping component 6 is on flexible grinding component 3, block graphite landing downwards, rotatory flexible grinding component 3 grinds graphite into the tiny particle under the combined action with graphite grinder 1, when flexible grinding component 3 upward movement once more, the tiny particle that grinds falls into in lubricated oil mixing stirring device 2, flexible grinding component 3 drives the 5 rotations of rabbling mechanism simultaneously, the tiny particle graphite and the lubricating oil stirring in rotatory rabbling mechanism 5 mixes lubricated oil mixing stirring device 2 are mixed, make the dispersion of graphite in lubricating oil more even and stable, be convenient for mix, when flexible grinding component 3 upward movement simultaneously, graphite can landing downwards once more, the reciprocal grinding graphite that realizes the intermittent type of circulation in proper order and drop into graphite in to lubricating oil.

The second embodiment is as follows:

the graphite grinding device 1 comprises a grinding cylinder 1-1, a pipe seat 1-2, a feeding pipe 1-3, an inclined plate 1-4, a transverse frame plate 1-5, a motor frame 1-6, a motor 1-7, a driving pulley 1-8 and an inverted frustum-shaped fixed grinding seat 1-9; the grinding cylinder 1-1 is fixedly connected to the lubricating oil mixing and stirring device 2 in a sealing mode, the pipe seat 1-2 is fixedly connected to the front end of the grinding cylinder 1-1, the feeding pipe 1-3 is fixedly connected to the pipe seat 1-2, the two inclined plates 1-4 are symmetrically and fixedly connected to the upper end of the grinding cylinder 1-1, the transverse frame plate 1-5 is fixedly connected to the two inclined plates 1-4, the motor frame 1-6 is fixedly connected to the middle of the transverse frame plate 1-5, the motor 1-7 is fixedly connected to the motor frame 1-6, the driving belt wheel 1-8 is fixedly connected to an output shaft of the motor 1-7, and the fixed grinding seat 1-9 is fixedly connected to the inner wall of the grinding cylinder 1-1.

The third concrete implementation mode:

the present embodiment is described below with reference to fig. 1 to 14, and the lubricating oil mixing and stirring device 2 includes a stirring cylinder 2-1, an oil inlet pipe 2-2, an oil discharge pipe 2-3, an annular slide rail 2-4, an L-shaped connecting plate 2-5, and a gear ring 2-6; the grinding cylinder 1-1 is fixedly connected to the upper end of the stirring cylinder 2-1 in a sealing mode, the oil inlet pipe 2-2 and the oil discharge pipe 2-3 are fixedly connected to the upper end and the lower end of the stirring cylinder 2-1 respectively, the oil inlet pipe 2-2 and the oil discharge pipe 2-3 are communicated with the interior of the stirring cylinder 2-1, the annular slide rail 2-4 is fixedly connected to the upper end of the inner wall of the stirring cylinder 2-1, the outer end of the gear ring 2-6 is uniformly and fixedly connected with four L-shaped connecting plates 2-5 in a surrounding mode, and the four L-shaped connecting plates 2-5 are fixedly connected to the upper end of the annular slide. When the lubricating oil mixing and stirring device 2 is used, lubricating oil is introduced into the stirring cylinder 2-1 through the oil inlet pipe 2-2, and the lubricating oil is discharged through the oil discharge pipe 2-3 with a control valve.

The fourth concrete implementation mode:

the embodiment is described below with reference to fig. 1 to 14, and the telescopic grinding assembly 3 includes a rotary shaft sleeve 3-1, a driven pulley 3-2, a driving bevel gear 3-3, a telescopic shaft 3-4, an upper sliding block 3-5, a lower sliding block 3-6, an upper sliding block chute 3-7, a grooved pulley 3-8, a sleeve 3-9, a truncated cone shaped blanking seat 3-10, an annular transition plate 3-11, a first inverted truncated cone shaped grinding plate 3-12, a second inverted truncated cone shaped grinding plate 3-13, a rack 3-14, an annular groove 3-15 and a linkage block 3-16; the middle part of a rotating shaft sleeve 3-1 is rotationally connected with the middle part of a cross frame plate 1-5 through a bearing with a seat, a driven belt wheel 3-2 and a driving bevel gear 3-3 are fixedly connected with the upper end of the rotating shaft sleeve 3-1, the driven belt wheel 3-2 is in transmission connection with the driving belt wheel 1-8 through a belt, the driving bevel gear 3-3 is in meshing transmission connection with an intermittent blanking control device 4, a telescopic shaft 3-4 is in sliding fit connection in the rotating shaft sleeve 3-1, an upper slide block 3-5 and a lower slide block 3-6 are respectively and fixedly connected with the upper end and the lower end of the telescopic shaft 3-4, an upper slide block chute 3-7 is arranged at the lower end of the rotating shaft sleeve 3-1, the upper slide block 3-5 is in sliding fit connection in the upper slide block chute 3-7, a grooved pulley 3-8 and a sleeve 3-, the upper end of a round table-shaped blanking seat 3-10 is fixedly connected with the upper end of a sleeve 3-9, the upper end and the lower end of an annular transition plate 3-11 are respectively and fixedly connected with the round table-shaped blanking seat 3-10 and a first inverted round table-shaped grinding plate 3-12, and the upper end and the lower end of a second inverted round table-shaped grinding plate 3-13 are respectively and fixedly connected with the first inverted round table-shaped grinding plate 3-12 and the lower end of the sleeve 3-9; the outer ring of the annular transition plate 3-11 is provided with an annular groove 3-15, six linkage blocks 3-16 are uniformly connected in the annular groove 3-15 in a surrounding sliding fit manner, and the upper ends of the six annular grooves 3-15 are fixedly connected with racks 3-14; the racks 3-14 are in meshed transmission connection with the linkage material blocking assembly 6; the lower end of the feeding pipe 1-3 is positioned above the circular truncated cone-shaped blanking seat 3-10 and on the inner side of the linkage material blocking assembly 6; the first inverted circular truncated cone-shaped grinding plate 3-12 and the second inverted circular truncated cone-shaped grinding plate 3-13 are both positioned at the inner side of the fixed grinding seat 1-9. The clearance between the first inverted circular truncated cone-shaped grinding plate 3-12 and the fixed grinding seat 1-9 is larger than the clearance between the second inverted circular truncated cone-shaped grinding plate 3-13 and the fixed grinding seat 1-9. When the telescopic grinding component 3 is used, the motors 1-7 are connected with a power supply and a control switch through leads and are started, the motors 1-7 drive the driving belt wheels 1-8 to rotate, the driving belt wheels 1-8 drive the driven belt wheels 3-2 to rotate through belts, the driven belt wheels 3-2 drive the rotating shaft sleeve 3-1 to rotate, the rotating shaft sleeve 3-1 drives the driving bevel gears 3-3 to rotate, the driving bevel gears 3-3 drive the intermittent blanking control device 4 to work, the rotating shaft sleeve 3-1 drives the telescopic shafts 3-4 to rotate through the upper sliding blocks 3-5, the telescopic shafts 3-4 drive the grooved wheels 3-8 and the sleeves 3-9 to rotate, the sleeves 3-9 drive the circular truncated cone-shaped blanking seats 3-10, the annular transition plates 3-11, the first inverted truncated cone-shaped grinding plates 3-12, The second inverted circular truncated cone type grinding plate 3-13 rotates, the graphite led out from the cross frame plate 1-5 is uniformly dispersed by the rotary circular truncated cone type blanking seat 3-10 under the action of centrifugal force and slides downwards to a gap between the first inverted circular truncated cone type grinding plate 3-12 and the fixed grinding seat 1-9 under the action of gravity, friction force and shearing force are generated between the rotary first inverted circular truncated cone type grinding plate 3-12 and the fixed grinding seat 1-9 to grind large graphite into small particles, the small particles of graphite enter a gap between the second inverted circular truncated cone type grinding plate 3-13 and the fixed grinding seat 1-9 to be further ground into uniform smaller particles, and the ground graphite falls into the lubricating oil mixing and stirring device 2 through the lower end of the fixed grinding seat 1-9; the annular grooves 3-15 and the linkage blocks 3-16 are arranged so that the six racks 3-14 are not driven to rotate when the annular transition plate 3-11 rotates, and the racks 3-14 can be driven to move up and down when the annular transition plate 3-11 moves up and down; the arrangement of the upper sliding block 3-5 and the upper sliding block sliding groove 3-7 enables the rotating shaft sleeve 3-1 to drive the telescopic shaft 3-4 to rotate, and meanwhile, the telescopic shaft 3-4 can slide up and down in the rotating shaft sleeve 3-1.

The fifth concrete implementation mode:

the embodiment is described below with reference to fig. 1-14, and the intermittent blanking control device 4 comprises an L-shaped frame plate 4-1, a disc shaft 4-2, a driven bevel gear 4-3, a disc 4-4, a short shaft 4-5, a swing rod 4-6, a hinge shaft 4-7, a portal frame 4-8, a shifting fork 4-9, a sliding sleeve 4-10 and a C-shaped frame 4-11; an L-shaped frame plate 4-1 is fixedly connected on a cross frame plate 1-5, the middle end of a disk shaft 4-2 is rotatably connected on the L-shaped frame plate 4-1 through a bearing with a seat, a driven bevel gear 4-3 and a disk 4-4 are respectively fixedly connected at two ends of the disk shaft 4-2, the disk shaft 4-2 is in meshing transmission connection with a driving bevel gear 3-3, a short shaft 4-5 is fixedly connected at the eccentric position of the disk 4-4, the upper end and the lower end of a swing rod 4-6 are respectively rotatably connected with the short shaft 4-5 and a hinge shaft 4-7, the hinge shaft 4-7 is rotatably connected at the middle end of a portal frame 4-8, two ends of the portal frame 4-8 are both fixedly connected with a shifting fork 4-9, the inner sides of the two shifting forks 4-9 are both in clearance fit connection, the outer ends of the two shifting forks 4-9 are fixedly connected with a sliding sleeve 4-10, the two sliding sleeves 4-10 are connected with a C-shaped frame 4-11 in a sliding fit mode, the upper ends of the two C-shaped frames 4-11 are fixedly connected to the two inclined plates 1-4 respectively, and the lower ends of the two C-shaped frames 4-11 are fixedly connected to the inner wall of the grinding cylinder 1-1. When the intermittent blanking control device 4 is used, the driving bevel gear 3-3 drives the driven bevel gear 4-3 to rotate, the driven bevel gear 4-3 drives the disc shaft 4-2 to rotate, the disc shaft 4-2 drives the disc 4-4 to rotate, the disc 4-4 drives the short shaft 4-5 to do circular motion, the short shaft 4-5 drives the oscillating bar 4-6 and the hinge shaft 4-7 to reciprocate, the hinge shaft 4-7 drives the portal frame 4-8 and the two shifting forks 4-9 to move up and down, the two C-shaped frames 4-11 play a role in guiding, the two shifting forks 4-9 drive the grooved wheels 3-8 to move up and down, the 3-8 drive the telescopic shaft 3-4 to move up and down, and the two shifting forks 4-9 are arranged so that the grooved wheels 3-8 can move up and down under the driving of the shifting forks 4-9 and can also; when the telescopic shaft 3-4 drives the sleeve 3-9, the truncated cone-shaped blanking seat 3-10, the annular transition plate 3-11, the first inverted truncated cone-shaped grinding plate 3-12, the second inverted truncated cone-shaped grinding plate 3-13 and the rack 3-14 to move up and down, the distance between the first inverted truncated cone-shaped grinding plate 3-12, the second inverted truncated cone-shaped grinding plate 3-13 and the fixed grinding seat 1-9 is increased, simultaneously the rack 3-14 drives the six linkage material blocking assemblies 6 to move outwards simultaneously, the six linkage material blocking assemblies 6 are separated from the truncated cone-shaped blanking seat 3-10, graphite enters a gap between the first inverted truncated cone-shaped grinding plate 3-12 and the fixed grinding seat 1-9, when the telescopic grinding assembly 3 moves down, the distance between the first inverted truncated cone-shaped grinding plate 3-12 and the second inverted cone-shaped grinding plate 3-13 and the fixed grinding seat 1-9 is reduced, meanwhile, the six linkage material blocking assemblies 6 are attached to the circular truncated cone-shaped blanking seats 3-10 to block graphite, the graphite cannot fall between the first inverted circular truncated cone-shaped grinding plates 3-12 and the fixed grinding seats 1-9, when the telescopic grinding assembly 3 moves upwards again, small-particle graphite falls into the lubricating oil mixing and stirring device 2 to introduce lubricating oil into the lubricating oil mixing and stirring device 2, the telescopic grinding assembly 3 drives the stirring mechanism 5 to rotate while rotating, the rotating stirring mechanism 5 disperses and mixes small-particle graphite and lubricating oil uniformly to ensure that the graphite is dispersed and stably in the lubricating oil and is convenient to mix, the six linkage material blocking assemblies 6 are separated from the circular truncated cone-shaped blanking seats 3-10 simultaneously, the graphite slides downwards to fall into gaps between the first inverted circular truncated cone-shaped grinding plates 3-12 and the fixed grinding seats 1-9 to be ground, the intermittent graphite feeding is realized by sequential cyclic reciprocation.

The sixth specific implementation mode:

the embodiment is described below with reference to fig. 1 to 14, and the stirring mechanism 5 includes a lower shaft sleeve 5-1, a lower slider chute 5-2, a bottom frame plate 5-3, a blade rotating shaft 5-4, a helical stirring blade 5-5, a driven pulley 5-6, a driving pulley 5-7, a gear i 5-8, a stirring shaft 5-9, a stirring plate 5-10 and a C-shaped sliding seat 5-11; the lower end of a lower shaft sleeve 5-1 is rotatably connected to the central position of the bottom surface of a stirring cylinder 2-1 through a bearing with a seat, the lower end of the lower shaft sleeve 5-1 is provided with a lower sliding block chute 5-2, the lower end of a telescopic shaft 3-4 is connected in the lower shaft sleeve 5-1 in a sliding fit manner, a lower sliding block 3-6 is connected in the lower sliding block chute 5-2 in a sliding fit manner, a bottom frame plate 5-3 is fixedly connected to the upper end of the lower shaft sleeve 5-1, two blade rotating shafts 5-4 are respectively and rotatably connected to the two ends of the bottom frame plate 5-3 through bearings with a seat, and two stirring shafts 5-9 are respectively and rotatably connected to the outer ends of the two ends; the upper end and the lower end of the blade rotating shaft 5-4 are respectively fixedly connected with a driven belt wheel 5-6 and a spiral stirring blade 5-5, a driving belt wheel 5-7 and a gear I5-8 are both fixedly connected to the upper end of a stirring shaft 5-9, the gear I5-8 is in meshing transmission connection with teeth on the inner side of a gear ring 2-6, and a plurality of stirring plates 5-10 are both fixedly connected to the lower end of the stirring shaft 5-9; two ends of the bottom frame plate 5-3 are fixedly connected with a C-shaped sliding seat 5-11, and the two C-shaped sliding seats 5-11 are connected to the annular sliding rail 2-4 in a sliding fit mode. When the stirring mechanism 5 is used, the telescopic shaft 3-4 drives the lower shaft sleeve 5-1 to rotate through the lower sliding block 3-6, the lower shaft sleeve 5-1 drives the bottom frame plate 5-3 to rotate, the bottom frame plate 5-3 drives the blade rotating shaft 5-4 and the stirring plate 5-10 to do circular motion around the axis of the lower shaft sleeve 5-1 through the driven belt pulley 5-6 and the stirring shaft 5-9, so as to stir lubricating oil and graphite, the stirring shaft 5-9 drives the gear I5-8 to do circular motion, the gear I5-8 is meshed with the gear ring 2-6 to drive the driving gear I5-8 to rotate around the axis of the gear I, the gear I5-8 drives the stirring shaft 5-9 to rotate, the stirring shaft 5-9 drives the driving belt pulley 5-7 and the plurality of stirring plates 5-10 to rotate around the axis of the stirring, the driving belt wheel 5-7 drives the driven belt wheel 5-6 to rotate through a belt, the driven belt wheel 5-6 drives the blade rotating shaft 5-4 to rotate, and the blade rotating shaft 5-4 drives the spiral stirring blade 5-5 to rotate around the axis of the blade rotating shaft 5-4, so that the spiral stirring blade 5-5 and the plurality of stirring plates 5-10 can rotate while revolving around the lower shaft sleeve 5-1, a better stirring effect is realized, and the graphite is dispersed in the lubricating oil more uniformly and stably; the arrangement of the driven belt wheel 5-6 and the lower sliding block chute 5-2 enables the telescopic shaft 3-4 to drive the lower shaft sleeve 5-1 to rotate, and meanwhile, the telescopic shaft 3-4 can slide up and down in the lower shaft sleeve 5-1.

The seventh embodiment:

the embodiment is described below with reference to fig. 1 to 14, and the linkage stop assembly 6 includes a linkage seat 6-1 and a stop member 6-2; the linkage seat 6-1 is fixedly connected to the inner wall of the grinding cylinder 1-1, the linkage seat 6-1 is positioned above the fixed grinding seat 1-9, the outer end of the material blocking part 6-2 is connected into the linkage seat 6-1, and the lower end of the material blocking part 6-2 is attached to the frustum-shaped material dropping seat 3-10. When the linkage material blocking assembly 6 is used, the racks 3-14 move up and down to drive the linkage seat 6-1 to work, and the linkage seat 6-1 drives the material blocking piece 6-2 to move inwards or outwards.

The specific implementation mode is eight:

the embodiment is described below with reference to fig. 1-14, wherein the linkage seat 6-1 comprises a hollow rectangular seat 6-1-1, a shaft seat plate 6-1-2, a threaded rod 6-1-3 and a gear II 6-1-4; the hollow rectangular seat 6-1-1 is fixedly connected to the inner wall of the grinding cylinder 1-1, the two shaft seat plates 6-1-2 are respectively and fixedly connected to the inner side and the outer side of the hollow rectangular seat 6-1-1, two ends of the threaded rod 6-1-3 are respectively and rotatably connected to the two shaft seat plates 6-1-2 through a bearing with a seat, and the gear II 6-1-4 is fixedly connected to the outer side of the threaded rod 6-1-3; the rack 3-14 is connected to the hollow rectangular seat 6-1-1 in a sliding fit mode, and the rack 3-14 is in meshed transmission connection with the gear II 6-1-4. When the linkage seat 6-1 is used, the rack 3-14 moves upwards to drive the gear II 6-1-4 to rotate, the gear II 6-1-4 drives the threaded rod 6-1-3 to rotate, and the threaded rod 6-1-3 drives the material blocking part 6-2 to move inwards or outwards.

The specific implementation method nine:

the embodiment is described below with reference to fig. 1-14, and the material blocking member 6-2 includes an arc material blocking plate 6-2-1, an arc rubber pad 6-2-2, an upper blocking plate 6-2-3, a connecting seat 6-2-4 and a rectangular plate 6-2-5; the upper end and the lower end of the arc-shaped material baffle 6-2-1 are respectively fixedly connected with an upper baffle 6-2-3 and an arc-shaped rubber gasket 6-2-2, the lower end of the arc-shaped rubber gasket 6-2-2 is attached to the circular truncated cone-shaped material dropping seat 3-10, the outer side of the arc-shaped material baffle 6-2-1 is fixedly connected with two connecting seats 6-2-4, the rectangular plate 6-2-5 is fixedly connected to the two connecting seats 6-2-4, the rectangular plate 6-2-5 is connected in the grinding cylinder 1-1 in a sliding fit mode, the rectangular plate 6-2-5 is connected to the threaded rod 6-1-3 in a threaded fit mode, and the arc-shaped material baffle 6-2-1 is inclined upwards from inside to outside. When the material blocking piece 6-2 is used, the threaded rod 6-1-3 generates relative displacement with the rectangular plate 6-2-5 when rotating to drive the rectangular plate 6-2-5 to move inwards or outwards, the rectangular plate 6-2-5 drives the arc material blocking plate 6-2-1 to move inwards or outwards through the two connecting seats 6-2-4, the arc rubber gasket 6-2-2 is made of rubber materials, and the circular truncated cone-shaped material dropping seat 3-10 is prevented from being blocked when moving upwards.

The detailed implementation mode is ten:

referring to fig. 1-14, the taper of the first reverse circular truncated cone-shaped grinding plate 3-12 is smaller than the taper of the second reverse circular truncated cone-shaped grinding plate 3-13, the gap between the first reverse circular truncated cone-shaped grinding plate 3-12 and the fixed grinding seat 1-9 is larger than the gap between the second reverse circular truncated cone-shaped grinding plate 3-13 and the fixed grinding seat 1-9, the taper of the second reverse circular truncated cone-shaped grinding plate 3-13 is equal to the taper of the fixed grinding seat 1-9, further grinding graphite into uniform smaller particles; the outer ring diameter of the annular transition plate 3-11 is smaller than the inner ring diameter of the grinding cylinder 1-1, so that graphite can fall into the gap between the first inverted circular truncated cone type grinding plate 3-12 and the fixed grinding seat 1-9 through the gap between the annular transition plate 3-11 and the grinding cylinder 1-1.

The working principle of the lubricating oil graphite coupling dispersing device is as follows: when the device is used, lubricating oil is poured into a lubricating oil mixing and stirring device 2, graphite is introduced into a graphite grinding device 1 through a feeding pipe and a telescopic grinding assembly 3, the graphite falls on the telescopic grinding assembly 3, after the graphite grinding device 1 is powered on and started, the graphite grinding device 1 drives the telescopic grinding assembly 3 to rotate, the telescopic grinding assembly 3 which rotates under the action of gravity and centrifugal force drives the graphite to be uniformly dispersed, the telescopic grinding assembly 3 drives an intermittent blanking control device 4 to work, the intermittent blanking control device 4 drives the telescopic grinding assembly 3 to move up and down, when the telescopic grinding assembly 3 moves upwards, the telescopic grinding assembly 3 drives six linkage material blocking assemblies 6 to be far away from the telescopic grinding assembly 3, the graphite falls between the telescopic grinding assembly 3 and the graphite grinding device 1 through a gap between the linkage material blocking assembly 6 and the telescopic grinding assembly 3, 3 downstream of flexible grinding component, the laminating of six linkage material stopping component 6 is on flexible grinding component 3, block graphite landing downwards, rotatory flexible grinding component 3 grinds graphite into the tiny particle under the combined action with graphite grinder 1, when flexible grinding component 3 upward movement once more, the tiny particle that grinds falls into in lubricated oil mixing stirring device 2, flexible grinding component 3 drives the 5 rotations of rabbling mechanism simultaneously, the tiny particle graphite and the lubricating oil stirring in rotatory rabbling mechanism 5 mixes lubricated oil mixing stirring device 2 are mixed, make the dispersion of graphite in lubricating oil more even and stable, be convenient for mix, when flexible grinding component 3 upward movement simultaneously, graphite can landing downwards once more, the reciprocal grinding graphite that realizes the intermittent type of circulation in proper order and drop into graphite in to lubricating oil.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims

1. The utility model provides a lubricating oil graphite coupling dispersion devices, includes graphite grinder (1), lubricating oil mixing stirring device (2), flexible grinding assembly (3), intermittent type unloading controlling means (4), rabbling mechanism (5) and linkage fender material subassembly (6), its characterized in that: graphite grinder (1) fixed connection on lubricating oil mixing stirring device (2), the upper end normal running fit of flexible grinding assembly (3) is connected on graphite grinder (1), the upper end and the graphite grinder (1) transmission of flexible grinding assembly (3) are connected, intermittent type unloading controlling means (4) fixed connection is on graphite grinder (1), the upper end of intermittent type unloading controlling means (4) is connected with the upper end meshing transmission of flexible grinding assembly (3), the lower extreme of intermittent type unloading controlling means (4) is connected with the middle part clearance fit of flexible grinding assembly (3), the lower extreme sliding fit of flexible grinding assembly (3) is connected in rabbling mechanism (5), rabbling mechanism (5) normal running fit is connected in lubricating oil mixing stirring device (2), rabbling mechanism (5) is connected with lubricating oil mixing stirring device (2) meshing transmission, the linkage material blocking assembly (6) is provided with six, the six linkage material blocking assemblies (6) are fixedly connected to the inner wall of the graphite grinding device (1) in a surrounding mode, the six linkage material blocking assemblies (6) form a closed circular ring structure, the six linkage material blocking assemblies (6) are attached to the telescopic grinding assembly (3), and the six linkage material blocking assemblies (6) are connected with the telescopic grinding assembly (3) in a meshing transmission mode.

2. The graphite coupling lubricant dispersing device of claim 1, wherein: the graphite grinding device (1) comprises a grinding cylinder (1-1), a pipe seat (1-2), a feeding pipe (1-3), an inclined plate (1-4), a transverse frame plate (1-5), a motor frame (1-6), a motor (1-7), a driving pulley (1-8) and an inverted frustum-shaped fixed grinding seat (1-9); the grinding cylinder (1-1) is fixedly connected to the lubricating oil mixing and stirring device (2) in a sealing mode, the pipe seat (1-2) is fixedly connected to the front end of the grinding cylinder (1-1), the feeding pipe (1-3) is fixedly connected to the pipe seat (1-2), the two inclined plates (1-4) are symmetrically and fixedly connected to the upper end of the grinding cylinder (1-1), the transverse frame plate (1-5) is fixedly connected to the two inclined plates (1-4), the motor frame (1-6) is fixedly connected to the middle of the transverse frame plate (1-5), the motor (1-7) is fixedly connected to the motor frame (1-6), the driving belt wheel (1-8) is fixedly connected to an output shaft of the motor (1-7), and the fixed grinding seat (1-9) is fixedly connected to the inner wall of the grinding cylinder (1-1).

3. The graphite coupling lubricant dispersing device of claim 2, wherein: the lubricating oil mixing and stirring device (2) comprises a stirring cylinder (2-1), an oil inlet pipe (2-2), an oil discharge pipe (2-3), an annular sliding rail (2-4), an L-shaped connecting plate (2-5) and a gear ring (2-6); the grinding cylinder (1-1) is fixedly connected to the upper end of the stirring cylinder (2-1) in a sealing mode, the oil inlet pipe (2-2) and the oil discharge pipe (2-3) are fixedly connected to the upper end and the lower end of the stirring cylinder (2-1) respectively, the oil inlet pipe (2-2) and the oil discharge pipe (2-3) are communicated with the interior of the stirring cylinder (2-1), the annular sliding rail (2-4) is fixedly connected to the upper end of the inner wall of the stirring cylinder (2-1), the outer end of the gear ring (2-6) is uniformly and fixedly connected with four L-shaped connecting plates (2-5) in a surrounding mode, and the four L-shaped connecting plates (2-5) are fixedly connected to the upper end of the annular sliding rail (.

4. The graphite coupling lubricant dispersing device of claim 3, wherein: the telescopic grinding assembly (3) comprises a rotary shaft sleeve (3-1), a driven belt pulley (3-2), a driving bevel gear (3-3), a telescopic shaft (3-4), an upper sliding block (3-5), a lower sliding block (3-6), an upper sliding block sliding groove (3-7), a grooved pulley (3-8), a sleeve (3-9), a frustum-shaped blanking seat (3-10), an annular transition plate (3-11), a first inverted frustum-shaped grinding plate (3-12), a second inverted frustum-shaped grinding plate (3-13), a rack (3-14), an annular groove (3-15) and a linkage block (3-16); the middle part of a rotating shaft sleeve (3-1) is rotatably connected with the middle part of a cross frame plate (1-5), a driven belt wheel (3-2) and a driving bevel gear (3-3) are fixedly connected with the upper end of the rotating shaft sleeve (3-1), the driven belt wheel (3-2) is in transmission connection with the driving belt wheel (1-8) through a belt, the driving bevel gear (3-3) is in meshing transmission connection with an intermittent blanking control device (4), a telescopic shaft (3-4) is in sliding fit connection with the inside of the rotating shaft sleeve (3-1), an upper slide block (3-5) and a lower slide block (3-6) are respectively and fixedly connected with the upper end and the lower end of the telescopic shaft (3-4), an upper slide block chute (3-7) is arranged at the lower end of the rotating shaft sleeve (3-1), the upper slide block (3-5) is in sliding fit with the inside of the, the grooved pulleys (3-8) and the sleeves (3-9) are fixedly connected to the middle parts of the telescopic shafts (3-4) from top to bottom in sequence, the upper ends of the frustum-shaped blanking seats (3-10) are fixedly connected to the upper ends of the sleeves (3-9), the upper ends and the lower ends of the annular transition plates (3-11) are fixedly connected with the frustum-shaped blanking seats (3-10) and the first inverted frustum-shaped grinding plates (3-12) respectively, and the upper ends and the lower ends of the second inverted frustum-shaped grinding plates (3-13) are fixedly connected with the first inverted frustum-shaped grinding plates (3-12) and the lower ends of the sleeves (3-9) respectively; an annular groove (3-15) is formed in the outer ring of the annular transition plate (3-11), six linkage blocks (3-16) are uniformly connected in the annular groove (3-15) in a surrounding sliding fit mode, and the upper ends of the six annular grooves (3-15) are fixedly connected with racks (3-14); the racks (3-14) are in meshed transmission connection with the linkage material blocking assembly (6); the lower end of the feeding pipe (1-3) is positioned above the circular truncated cone-shaped blanking seat (3-10) and on the inner side of the linkage material blocking assembly (6); the first inverted circular truncated cone-shaped grinding plate (3-12) and the second inverted circular truncated cone-shaped grinding plate (3-13) are both positioned at the inner side of the fixed grinding seat (1-9).

5. The graphite coupling lubricant dispersing device of claim 4, wherein: the intermittent blanking control device (4) comprises an L-shaped frame plate (4-1), a disc shaft (4-2), a driven bevel gear (4-3), a disc (4-4), a short shaft (4-5), a swing rod (4-6), a hinge shaft (4-7), a door-shaped frame (4-8), a shifting fork (4-9), a sliding sleeve (4-10) and a C-shaped frame (4-11); an L-shaped frame plate (4-1) is fixedly connected on a transverse frame plate (1-5), the middle end of a disc shaft (4-2) is rotatably connected on the L-shaped frame plate (4-1), a driven bevel gear (4-3) and a disc (4-4) are respectively and fixedly connected at two ends of the disc shaft (4-2), the disc shaft (4-2) is in meshing transmission connection with a driving bevel gear (3-3), a short shaft (4-5) is fixedly connected at the eccentric position of the disc (4-4), the upper end and the lower end of a swing rod (4-6) are respectively and rotatably connected with the short shaft (4-5) and a hinge shaft (4-7), the hinge shaft (4-7) is rotatably connected at the middle end of a portal frame (4-8) in a matching manner, two ends of the portal frame (4-8) are both fixedly connected with a shifting fork (4-9), the inner sides of the two shifting forks (4-9) are connected in the grooved wheels (3-8) in a clearance fit manner, the outer ends of the two shifting forks (4-9) are fixedly connected with one sliding sleeve (4-10), the two sliding sleeves (4-10) are connected with one C-shaped frame (4-11) in a sliding fit manner, the upper ends of the two C-shaped frames (4-11) are fixedly connected to the two inclined plates (1-4) respectively, and the lower ends of the two C-shaped frames (4-11) are fixedly connected to the inner wall of the grinding cylinder (1-1).

6. The graphite coupling lubricant dispersing device of claim 5, wherein: the stirring mechanism (5) comprises a lower shaft sleeve (5-1), a lower sliding block chute (5-2), an underframe plate (5-3), a blade rotating shaft (5-4), a spiral stirring blade (5-5), a driven belt wheel (5-6), a driving belt wheel (5-7), a gear I (5-8), a stirring shaft (5-9), a stirring plate (5-10) and a C-shaped sliding seat (5-11); the lower end of a lower shaft sleeve (5-1) is rotatably connected to the central position of the bottom surface of a stirring cylinder (2-1), the lower end of the lower shaft sleeve (5-1) is provided with a lower sliding block sliding groove (5-2), the lower end of a telescopic shaft (3-4) is connected in the lower shaft sleeve (5-1) in a sliding fit manner, a lower sliding block (3-6) is connected in the lower sliding block sliding groove (5-2) in a sliding fit manner, a bottom frame plate (5-3) is fixedly connected to the upper end of the lower shaft sleeve (5-1), two blade rotating shafts (5-4) are respectively rotatably connected to two ends of the bottom frame plate (5-3), and two stirring shafts (5-9) are respectively rotatably connected to the outer ends of two ends of the bottom frame plate (; the upper end and the lower end of the blade rotating shaft (5-4) are respectively fixedly connected with a driven belt wheel (5-6) and a spiral stirring blade (5-5), a driving belt wheel (5-7) and a gear I (5-8) are fixedly connected to the upper end of a stirring shaft (5-9), the gear I (5-8) is in meshing transmission connection with teeth on the inner side of a gear ring (2-6), and a plurality of stirring plates (5-10) are fixedly connected to the lower end of the stirring shaft (5-9); two ends of the bottom frame plate (5-3) are fixedly connected with a C-shaped sliding seat (5-11), and the two C-shaped sliding seats (5-11) are connected to the annular sliding rail (2-4) in a sliding fit mode.

7. The graphite coupling lubricant dispersing device of claim 6, wherein: the linkage material blocking assembly (6) comprises a linkage seat (6-1) and a material blocking member (6-2); the linkage seat (6-1) is fixedly connected to the inner wall of the grinding cylinder (1-1), the linkage seat (6-1) is located above the fixed grinding seat (1-9), the outer end of the material blocking part (6-2) is connected into the linkage seat (6-1), and the lower end of the material blocking part (6-2) is attached to the circular truncated cone-shaped blanking seat (3-10).

8. The graphite coupling lubricant dispersing device of claim 7, wherein: the linkage seat (6-1) comprises a hollow rectangular seat (6-1-1), a shaft seat plate (6-1-2), a threaded rod (6-1-3) and a gear II (6-1-4); the hollow rectangular seat (6-1-1) is fixedly connected to the inner wall of the grinding cylinder (1-1), the two shaft seat plates (6-1-2) are respectively and fixedly connected to the inner side and the outer side of the hollow rectangular seat (6-1-1), two ends of the threaded rod (6-1-3) are respectively and rotatably connected to the two shaft seat plates (6-1-2), and the gear II (6-1-4) is fixedly connected to the outer side of the threaded rod (6-1-3); the rack (3-14) is connected to the hollow rectangular seat (6-1-1) in a sliding fit manner, and the rack (3-14) is in meshed transmission connection with the gear II (6-1-4).

9. The graphite-coupled lubricant dispersion apparatus of claim 8, wherein: the material blocking piece (6-2) comprises an arc material blocking plate (6-2-1), an arc rubber pad (6-2-2), an upper baffle plate (6-2-3), a connecting seat (6-2-4) and a rectangular plate (6-2-5); the upper end and the lower end of the arc-shaped material baffle plate (6-2-1) are respectively fixedly connected with the upper baffle plate (6-2-3) and the arc-shaped rubber gasket (6-2-2), the lower end of the arc-shaped rubber gasket (6-2-2) is attached to the circular truncated cone-shaped material dropping seat (3-10), the outer side of the arc-shaped material baffle plate (6-2-1) is fixedly connected with the two connecting seats (6-2-4), the rectangular plate (6-2-5) is fixedly connected to the two connecting seats (6-2-4), the rectangular plate (6-2-5) is connected to the threaded rod (6-1-3) in a sliding fit mode, and the arc-shaped material baffle plate (6-2-1) is inclined upwards from inside to outside.

10. The graphite coupling lubricant dispersing device of claim 4, wherein: the conicity of the first inverted circular truncated cone-shaped grinding plate (3-12) is smaller than that of the second inverted circular truncated cone-shaped grinding plate (3-13), and the conicity of the second inverted circular truncated cone-shaped grinding plate (3-13) is equal to that of the fixed grinding seat (1-9); the diameter of the outer ring of the annular transition plate (3-11) is smaller than that of the inner ring of the grinding cylinder (1-1).