CN218834264U - High-efficient spherical graphite compounding device - Google Patents

Abstract

The utility model relates to a high-efficient spherical graphite compounding device, belong to the helical mixing machine field, which comprises a frame, the frame is provided with one-level mixing portion and second grade mixing portion, the frame corresponds one-level mixing portion and is provided with first feed inlet, the frame corresponds second grade mixing portion and is provided with the discharge gate, the frame corresponds and is provided with the mounting panel between one-level mixing portion and the second grade mixing portion, can communicate between one-level mixing portion and the second grade mixing portion, the frame corresponds and is provided with first pivot in the one-level mixing portion, the frame corresponds first pivot and is provided with the motor, the motor can drive first pivot and rotate, first pivot is provided with the first hob that can the rotation can revolute again, be provided with the second pivot in the first pivot corresponds the second grade mixing portion, the second pivot is provided with the connecting axle, the connecting axle both ends are provided with can enough the rotation can the second hob of revolution again. This application has the effect that increase helical mixing machine work efficiency.

Description

High-efficient spherical graphite compounding device

Technical Field

The application relates to a spiral mixer field especially relates to a high-efficient spherical graphite compounding device.

Background

At present in the processing and purifying process of spherical graphite, at first need process into initial spherical graphite through procedures such as coarse crushing, trimming, magnetic separation with dry concentrate of graphite, carry out purification reaction output high-purity spherical graphite again, and the inevitable minute difference that can exist in the aspect of the high-purity spherical graphite that same batch of dry concentrate of graphite production obtained after a series of processing technology in the purity, directly put into storing storehouse with these spherical graphite then can make the spherical graphite of different purity distribute unevenly, so need put into the helical mixing machine with the spherical graphite after drying, the spherical graphite intensive mixing that mixes of different purity, make it distribute evenly.

Common helical mixing machine main part is the taper setting, including a horizontally pivot, the pivot is by motor drive, and the pivot can the rotation again the revolution, and pivot length direction both ends all are provided with the hob that is on a parallel with the main part lateral wall, and two hobs can the rotation also can be along with the revolution of pivot, reach the effect that the stirring was mixed.

To the correlation technique among the above-mentioned, common helical mixing machine rotates the stirring through two hob and mixes, because coverage area is less when two hob rotate, in order to make spherical graphite can the intensive mixing, then need mix longer time for helical mixing machine mixes the time of once material consumption longer, and efficiency is lower.

SUMMERY OF THE UTILITY MODEL

In order to improve the work efficiency of helical mixing machine, this application provides a high-efficient spherical graphite compounding device.

The application provides a pair of high-efficient spherical graphite compounding device adopts following technical scheme:

the utility model provides a high-efficient spherical graphite compounding device, which comprises a frame, the frame is provided with one-level mixing portion and second grade mixing portion, the frame corresponds one-level mixing portion and is provided with first feed inlet, the frame corresponds second grade mixing portion and is provided with the discharge gate, the frame corresponds and is provided with the mounting panel between one-level mixing portion and the second grade mixing portion, can communicate between one-level mixing portion and the second grade mixing portion, the frame corresponds and is provided with first pivot in the one-level mixing portion, the frame corresponds first pivot and is provided with the motor, the motor can drive first pivot and rotate, first pivot is provided with first hob that can rotate, first hob is provided with the second terminal surface gear, the frame corresponds second terminal surface gear position department and is provided with first terminal surface gear, first hob passes through second terminal surface gear and realizes the rotation with first terminal surface gear meshing, be provided with the second pivot in the first pivot corresponds second grade mixing portion, second pivot rigid coupling has the axle sleeve, the axle sleeve internal rotation is connected with the connecting axle, the axle sleeve corresponds the second hob that can the rotation at connecting axle both ends.

By adopting the scheme, the spherical graphite is firstly placed into the first-stage mixing part, the motor drives the first rotating shaft to rotate, the first rotating shaft rotates to drive the first screw rod to rotate around the direction of the first rotating axis, the first screw rod is meshed with the first end face gear fixedly connected to the rack through the second end face gear, the first screw rod rotates to drive the second end face gear to walk along the tooth face of the first end face gear, so that the first screw rod is driven to rotate, the mixing process in the first-stage mixing part is realized, after the spherical graphite is mixed for a period of time in the first-stage mixing part, the communication part between the first-stage mixing part and the second-stage mixing part is opened, the spherical graphite mixed for a period of time enters the second-stage mixing part to be continuously stirred and mixed, new spherical graphite is put into the first-stage mixing part, the second rotating shaft rotates around the axis of the second rotating shaft along with the rotation of the first rotating shaft, the connecting shaft can rotate at the same time, the second screw rod is driven to rotate through the shaft sleeve, so that the second screw rod can rotate in the second-stage mixing part, the connecting shaft is also realized, the second-stage mixing shaft is discharged from the first-stage mixing part, and then the second-stage mixing part is discharged from the second-stage mixing part. One-level mixing portion and second grade mixing portion simultaneous working have still practiced thrift the mix time when having increased once mixing volume, and twice mixing process can make spherical graphite intensive mixing, has increased spiral mixer's mixing efficiency.

Preferably, the mounting plate is fixedly connected with a third face gear at a position corresponding to the second rotating shaft, the second rotating shaft penetrates through the third face gear, the two connecting shafts are fixedly connected with a fourth face gear at a position corresponding to the third face gear, and the fourth face gear is meshed with the third face gear to realize rotation of the connecting shafts.

Through adopting above-mentioned scheme, the second pivot drives the connecting axle and rotates around the axis direction, and fourth terminal surface gear rotates and walks along third terminal surface gear tooth face along one connecting axle, realizes the rotation of connecting axle.

Preferably, the direction sleeve is fixedly connected to two ends of the shaft sleeve in the length direction, the second screw rod is rotatably connected to the direction sleeve, a fifth face gear is fixedly connected to one end, close to the second screw rod, of the connecting shaft, a sixth face gear is fixedly connected to one end, close to the connecting shaft, of the second screw rod, and the fifth face gear is meshed with the sixth face gear to achieve rotation of the second screw rod.

By adopting the above scheme, axle sleeve and connecting axle rotate along with the second pivot jointly and drive the diversion sleeve and rotate around the second pivot, and the diversion sleeve drives the second hob and rotates around the second pivot, and fifth terminal surface gear rotates along with the connecting axle simultaneously, and sixth terminal surface gear drives the rotation of second hob with the meshing of fifth terminal surface gear.

Preferably, the second feed inlet has all been seted up at mounting plate diameter both ends, and the mounting panel is inserted and is equipped with the closing plate corresponding second feed inlet position department.

Through adopting above-mentioned scheme, pull out two closing plates to the direction of keeping away from each other, one-level mixing portion is in the connected state with second grade mixing portion, and spherical graphite after the stirring of one-level mixing portion falls into the second grade mixing portion through the second feed inlet in, impels two closing plates to the direction that is close to each other, and one-level mixing portion and second grade mixing portion are in the state of blocking.

Preferably, a rotating sleeve is fixedly connected to the position, corresponding to the first screw rod, of the first rotating shaft, the first screw rod is rotatably connected to the rotating sleeve, deep groove ball bearings are arranged at the positions, corresponding to the rotating connection position of the first screw rod, of the rotating sleeve, the outer ring of each deep groove ball bearing is fixedly connected to the rotating sleeve, and the inner ring of each deep groove ball bearing is fixedly connected to the first screw rod.

Through adopting above-mentioned scheme, first hob still follows the rotation sleeve and together rotates around first hob axis when self axis is pivoted, rotation sleeve and first hob commentaries on classics can receive the interact power of horizontal direction, first hob rotates sleeve and rotates to be connected out and can receive great wearing and tearing with first hob, can improve first hob and the intensity that rotates sleeve horizontal direction atress through installation deep groove ball bearing, and then can improve the condition that rotation sleeve and first hob produced wearing and tearing.

Preferably, a plane thrust bearing is arranged at the position, corresponding to the second rotating shaft, of the upper side of the mounting plate, and the plane thrust bearing is rotatably connected to the second rotating shaft.

Through adopting above-mentioned scheme, the gravity of third hob acts on in the second pivot, and the second pivot bears great load, receives vertical decurrent effort, can improve the intensity that the vertical direction of second pivot received the power through mounting plane thrust bearing, and then improves the second pivot and easily appears cracked condition because of the overweight of load.

Preferably, the mounting panel upside corresponds first hob position department rigid coupling and has a support sleeve, and support sleeve can play the supporting role to first hob.

Through adopting above-mentioned scheme, it is connected with two first hob to rotate the sleeve, and the load is great, and support sleeve can provide ascending holding power for rotating the sleeve, has reduced support sleeve because of the great probability that breaks off and damages of taking place of load, has improved the stability of structure.

Preferably, one end of the second rotating shaft, which is far away from the mounting plate, is fixedly connected with a third spiral rod which is coaxially arranged.

Through adopting above-mentioned scheme, when the second hob rotates the stirring, can constantly mix the extrusion of spherical graphite to the middle part, the third hob can mix the spherical graphite that extrudees to the middle part and stir once more and mix, can make more abundant that spherical graphite mixes, can also shorten the churning time simultaneously, improved work efficiency.

Preferably, the frame corresponds one-level mixing portion and second grade mixing portion lateral wall and has all seted up the access door.

Through adopting above-mentioned scheme, break down or use the long time after when the device, maintenance personal can be through opening the access door, inspects the maintenance to device inner structure.

In summary, the present application has the following beneficial effects:

1. spherical graphite is firstly placed into the first-stage mixing portion, the spherical graphite is mixed for a period of time in the first-stage mixing portion, a communicating part of the first-stage mixing portion and the second-stage mixing portion is opened, the spherical graphite mixed for a period of time enters the second-stage mixing portion to be continuously stirred and mixed, the spherical graphite is discharged from a discharge port after being fully mixed in the second-stage mixing portion, and the spherical graphite mixed for a period of time in the second-stage mixing portion is introduced into the second-stage mixing portion. The first-stage mixing part and the second-stage mixing part work simultaneously, so that the mixing time is saved while the primary mixing amount is increased, the spherical graphite can be fully mixed in the two mixing processes, and the mixing efficiency of the spiral mixer is increased;

2. the first screw rod rotates around the axis of the first screw rod and simultaneously rotates around the axis of the first rotating shaft along with the rotating sleeve, the rotating sleeve and the first screw rod can be subjected to interaction force in the horizontal direction, the first screw rod rotating sleeve and the first screw rod are connected in a rotating mode and can be subjected to large abrasion, the intensity of the horizontal direction stress of the first screw rod and the rotating sleeve can be improved by installing the deep groove ball bearing, and the abrasion condition of the rotating sleeve and the first screw rod can be further improved;

3. when the second hob rotates the stirring, can constantly extrude the mixing to the middle part with spherical graphite, the third hob can stir the mixing again to the spherical graphite of middle part with extrusion mixing, can make more abundant that spherical graphite mixes, can also shorten the churning time simultaneously, has improved work efficiency.

Drawings

FIG. 1 is a schematic structural diagram of an efficient spherical graphite mixing device according to an embodiment of the present disclosure;

FIG. 2 is a cross-sectional view of a projecting rotating sleeve of a high efficiency spherical graphite compounding device according to an embodiment of the present application;

FIG. 3 is a schematic diagram of the internal structure of a protruded primary mixing part of a high-efficiency spherical graphite mixing device according to an embodiment of the present application;

FIG. 4 is an enlarged view of portion A of FIG. 3;

fig. 5 is an enlarged view of a portion B in fig. 3.

Description of the reference numerals: 1. a frame; 11. a sealing door; 12. mounting a plate; 13. a sealing plate; 14. a discharge port; 15. an access door; 16. a motor; 2. a first-stage mixing section; 21. a first rotating shaft; 22. installing a sleeve; 23. rotating the sleeve; 24. a support sleeve; 25. a first face gear; 26. a second face gear; 27. a first screw rod; 28. a deep groove ball bearing; 3. a secondary mixing section; 31. a second rotating shaft; 32. a connecting sleeve; 33. a shaft sleeve; 34. a connecting shaft; 341. a third face gear; 342. a fourth face gear; 343. a fifth face gear; 344. a sixth face gear; 35. a second screw rod; 36. a third screw rod; 37. a planar thrust bearing; 38. turning sleeve.

Detailed Description

The present application is described in further detail below with reference to figures 1-5.

The embodiment of the application discloses high-efficient spherical graphite compounding device. Referring to fig. 1 and 2, frame 1 including vertical setting, frame 1 is sealed tubular structure, frame 1 is provided with one-level mixing portion 2 and second grade mixing portion 3, one-level mixing portion 2 is cylindricly, second grade mixing portion 3 is coniform, one-level mixing portion 2 is located the 3 tops of second grade mixing portion and sets up, frame 1 corresponds 2 upsides of one-level mixing portion and has seted up two first feed inlets, two first feed inlets are located the symmetrical setting of 1 upper surface of frame, first feed inlet is circularly, frame 1 corresponds first feed inlet position department and rotates and is connected with sealing door 11. Frame 1 corresponds 2 downside rigid couplings of one-level mixing portion has mounting panel 12, and mounting panel 12 is circular and the area equals with 2 cross sections of one-level mixing portion and 3 upper end cross sections of second grade mixing portion, and 3 upper ends rigid couplings of second grade mixing portion are in mounting panel 12. Two second feed inlets have been seted up on mounting panel 12 surface, two second feed inlets are located mounting panel 12 diameter both ends, two second feed inlets are the setting of U type, the direction of the centre of a circle is all kept away from to U type opening, mounting panel 12 corresponds second feed inlet position department and all inserts and is equipped with closing plate 13, closing plate 13 can follow the reciprocal slip of mounting panel 12 length direction, pull out two closing plate 13 to the direction of keeping away from each other, one-level mixing portion 2 is in the connected state with second grade mixing portion 3, impel two closing plate 13 to the direction that is close to each other, one-level mixing portion 2 and second grade mixing portion 3 are in the state of blocking. The lower end of the frame 1 corresponding to the second-stage mixing part 3 is provided with a discharge hole 14. The frame 1 corresponds first grade mixing portion 2 and the 3 lateral walls of second grade mixing portion and has seted up access door 15.

Referring to fig. 2 and 3, a motor 16 is fixedly connected to the upper end of the outer side of the first-stage mixing portion 2 corresponding to the rack 1, an output shaft of the motor 16 is vertically arranged downward, a first rotating shaft 21 coaxially arranged is fixedly connected to the output shaft of the motor 16, the first rotating shaft 21 vertically penetrates through the rack 1 downward, and the first rotating shaft 21 is located in the first-stage mixing portion 2. The frame 1 is corresponding to first pivot 21 and is kept away from the rigid coupling of mounting panel 12 position department and has a mounting sleeve 22, and first pivot 21 is located to the mounting sleeve 22 cover, and mounting sleeve 22 extends to and is close to first pivot 21 middle part position department along 21 length sides of first pivot, and mounting sleeve 22 is close to mounting panel 12 one side rigid coupling and has first terminal surface gear 25, and first terminal surface gear 25 axis and first pivot 21 collineation, first terminal surface gear 25 cover are located first pivot 21. The middle position of the first rotating shaft 21 is fixedly connected with a rotating sleeve 23, the axis of the rotating sleeve 23 is collinear with the first rotating shaft 21, the upper end of the rotating sleeve 23 is rotatably connected to the lower end of the mounting sleeve 22, and the rotating sleeve 23 is sleeved on the first face gear 25. Rotating sleeve 23 is perpendicular to self axis direction both sides and all rotates and be connected with first hob 27, and first hob 27 all is close to first terminal surface gear 25 setting, and first hob 27 is perpendicular to first pivot 21 setting, and two first hobs 27 keep away from one end each other and all extend to and be close to frame 1 position department.

Referring to fig. 2 and 4, the deep groove ball bearings 28 are respectively sleeved at the positions of the rotary sleeve 23 corresponding to the rotary connection positions of the first screw rods 27, the inner rings of the deep groove ball bearings 28 are fixedly connected to the first screw rods 27, and the outer rings of the deep groove ball bearings 28 are fixedly connected to the rotary sleeve 23. The positions of the two first screw rods 27 corresponding to the first face gears 25 are fixedly connected with second face gears 26 which are coaxially arranged, the two second face gears 26 are respectively positioned at two sides of the first rotating shaft 21, and the two second face gears 26 are both meshed with the first face gears 25. The mounting panel 12 corresponds the rigid coupling in the below of rotating sleeve 23 and has a support sleeve 24, and the support sleeve 24 axis and first pivot 21 collineation, support sleeve 24 keep away from mounting panel 12 one side and rotate to connect in rotating sleeve 23, play the supporting role to rotating sleeve 23.

Referring to fig. 3 and 4, when the motor 16 drives the first rotating shaft 21 to rotate, the rotating sleeve 23 rotates along with the rotation of the first rotating shaft 21, the rotating sleeve 23 drives the first screw rod 27 and the second face gear 26 to rotate horizontally around the first rotating shaft 21, the second face gear 26 is engaged with the first face gear 25, the first face gear 25 is fixed, then the second face gear 26 rotates around the tooth surface of the first face gear 25, and the second face gear 26 rotates to drive the first rotating shaft 21 to rotate around its axis.

Referring to fig. 2 and 5, a second rotating shaft 31 coaxially disposed is fixedly connected to one end of the first rotating shaft 21 close to the mounting plate 12, the second rotating shaft 31 is disposed to penetrate through the mounting plate 12, a planar thrust bearing 37 is fixedly connected to a position on the upper side of the mounting plate 12 corresponding to the penetrating position of the second rotating shaft 31, and the second rotating shaft 31 is sleeved with the planar thrust bearing 37. A coaxial third face gear 341 is fixedly connected to a position of the lower side of the mounting plate 12 corresponding to the penetrating position of the second rotating shaft 31, and the second rotating shaft 31 is sleeved with the third face gear 341. A connecting sleeve 32 is fixedly connected to the lower side of the mounting plate 12 at a position corresponding to the third face gear 341, and the axis of the connecting sleeve 32 is collinear with the second rotating shaft 31. One end of the connecting sleeve 32, which is far away from the mounting plate 12, is rotatably connected with a shaft sleeve 33, the length direction of the shaft sleeve 33 is perpendicular to the axial direction of the second rotating shaft 31, two ends of the shaft sleeve 33 along the length direction extend to positions close to the rack 1, and the shaft sleeve 33 is fixedly connected to the lower end of the second rotating shaft 31. The shaft sleeve 33 is connected with a connecting shaft 34 corresponding to both sides of the second rotating shaft 31 in a rotating manner, the connecting shaft 34 is arranged along the length direction of the shaft sleeve 33, the axis of the connecting shaft 34 is perpendicular to the axis of the second rotating shaft 31, the connecting shaft 34 is fixedly connected with fourth face gears 342 arranged coaxially corresponding to the third face gears 341, the two fourth face gears 342 are arranged on both sides of the second rotating shaft 31, the fourth face gears 342 are engaged with the third face gears 341, and the two connecting shafts 34 are mutually far away from one end in the length direction and are fixedly connected with fifth face gears 343 arranged coaxially.

Referring to fig. 2 and 5, the equal rigid coupling in axle sleeve 33 length direction both ends has the diversion sleeve, the diversion sleeve is kept away from mounting panel 12 one side and is all rotated and be connected with second hob 35, second hob 35 all sets up along the tapered side wall of second grade mixing portion 3, second hob 35 is on a parallel with 3 lateral walls of second grade mixing portion, two second hobs 35 are by being close to mounting panel 12 one side to keeping away from mounting panel 12 one side to being close to the direction slope each other, one of them hob length extends to 3 lower extremes of second grade mixing portion and corresponds 14 positions departments of discharge gate, wherein another hob length direction extends to 3 middle part positions departments of second grade mixing portion. A sixth end face gear 344 which is coaxially arranged is fixedly connected to the second screw rod 35 at a position close to the fifth end face gear 343, and the sixth end face gear 344 is meshed with the fifth end face gear 343. One end of the second rotating shaft 31, which is far away from the mounting plate 12, is fixedly connected with a third screw rod 36, the third screw rod 36 is vertically arranged, and one end of the third screw rod 36, which is far away from the mounting plate 12 in the length direction, extends to the upper third position of the second-stage mixing part 3.

Referring to fig. 2 and 5, the first rotating shaft 21 rotates to drive the second rotating shaft 31 to rotate, the second rotating shaft 31 rotates to drive the third spiral rod 36 to rotate around the axis of the third rotating shaft, the second rotating shaft 31 also drives the shaft sleeve 33 and the connecting shaft 34 to horizontally rotate around the second rotating shaft 31, and the shaft sleeve 33 rotates to drive the turning sleeve and the second spiral rod 35 to rotate around the second rotating shaft 31; the connecting shaft 34 rotates around the second rotating shaft 31 to drive the fourth face gear 342 to rotate along the tooth surface of the third face gear 341, the fourth face gear 342 rotates to drive the connecting shaft 34 and the fifth face gear 343 to rotate around the axis thereof, and the fifth face gear 343 rotates to drive the sixth face gear 344 and the second screw 35 to rotate around the axis thereof.

The implementation principle of the high-efficient spherical graphite compounding device of the embodiment of the application is as follows: firstly, spherical graphite is put into a primary mixing part 2, a motor 16 drives a first rotating shaft 21 in the primary mixing part 2 to rotate, the first rotating shaft 21 drives a first spiral rod 27 to rotate around the first rotating shaft 21 through a rotating sleeve 23, the first spiral rod 27 rotates, simultaneously, a second end face gear 26 walks around the tooth surface of a first end face gear 25 so as to drive the first spiral rod 27 to rotate, the first spiral rod 27 rotates and revolves around the first rotating shaft 21, the spherical graphite is fully stirred and mixed in the primary mixing part 2, after a period of mixing, a sealing plate 13 is opened, the spherical graphite falls into a secondary mixing part 3 from a second feeding hole to be stirred and mixed, the sealing plate 13 is closed, the spherical graphite is continuously poured into the primary mixing part 2, the second rotating shaft 31 rotates along with the rotation of the first rotating shaft 21 in the secondary mixing part 3, the second rotating shaft 31 drives a connecting shaft 34 to rotate through a shaft sleeve 33, the fourth end gear 342 is driven to walk around the tooth surface of the third end gear 341 while the connecting shaft 34 rotates, so that the connecting shaft 34 rotates, the connecting shaft 34 rotates to drive the fifth end gear 343 to rotate, the fifth end gear 343 drives the sixth end gear 344 to rotate, so that the second screw rod 35 rotates, the second screw rod 35 rotates around the axis of the second rotating shaft 31 under the drive of the turning sleeve and the shaft sleeve 33, the second screw rod 35 rotates and revolves, so that the spherical graphite is continuously and fully stirred in the second mixing part 3, meanwhile, the second rotating shaft 31 also drives the third screw rod 36 to rotate, and is simultaneously stirred and mixed with the second screw rod 35 in the second mixing part, finally, the mixed spherical graphite is discharged from the discharge port 14, and at the moment, the spherical graphite in the first-stage mixing part 2 is mixed for a while being guided into the second mixing part 3, the circulation operation in turn saves the mixing time and increases the mixing efficiency.

The embodiment of the application has the effect of increasing the mixing efficiency of the helical mixer.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: equivalent changes in structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (9)

1. The utility model provides a high-efficient spherical graphite compounding device, includes frame (1), its characterized in that: the frame (1) is provided with a first-stage mixing part (2) and a second-stage mixing part (3), the frame (1) corresponds to the first-stage mixing part (2) and is provided with a first feed inlet, the frame (1) corresponds to the second-stage mixing part (3) and is provided with a discharge outlet (14), the frame (1) corresponds to the first-stage mixing part (2) and is provided with a mounting plate (12) between the second-stage mixing part (3), the first-stage mixing part (2) and the second-stage mixing part (3) can be communicated, the frame (1) corresponds to be provided with a first rotating shaft (21) in the first-stage mixing part (2), the frame (1) corresponds to be provided with a motor (16) in the first rotating shaft (21), the motor (16) can drive the first rotating shaft (21) to rotate, the first rotating shaft (21) is provided with a first spiral rod (27) which can rotate, the first spiral rod (27) is provided with a second spiral gear (26), the frame (1) corresponds to be provided with a first end face gear (25) in the position of the second end face gear (26), the first end face gear (27) corresponds to be provided with a second-rotating shaft (31) in the second-rotating shaft (31), and a shaft sleeve (33) is fixedly connected to the second rotating shaft (31), a connecting shaft (34) is rotationally connected to the shaft sleeve (33), and second spiral rods (35) capable of rotating are arranged at two ends of the shaft sleeve (33) corresponding to two ends of the connecting shaft (34).

2. The efficient spherical graphite mixing device according to claim 1, characterized in that: mounting panel (12) correspond second pivot (31) position department rigid coupling has third face gear (341), second pivot (31) are worn to locate third face gear (341), two connecting axle (34) correspond third face gear (341) position department equal rigid coupling has fourth face gear (342), fourth face gear (342) with third face gear (341) meshing realizes connecting axle (34) rotation.

3. The efficient spherical graphite mixing device according to claim 1, characterized in that: the equal rigid coupling in axle sleeve (33) length direction both ends has the diversion sleeve, second hob (35) rotate connect in the diversion sleeve, connecting axle (34) are close to the equal rigid coupling in second hob (35) one end has fifth face gear (343), second hob (35) are close to the equal rigid coupling in connecting axle (34) one end has sixth face gear (344), fifth face gear (343) with sixth face gear (344) meshing realizes second hob (35) rotation.

4. The efficient spherical graphite mixing device according to claim 1, characterized in that: the mounting plate (12) diameter both ends have all been seted up the second feed inlet, mounting plate (12) are inserted and are equipped with closing plate (13) corresponding second feed inlet position department.

5. The efficient spherical graphite mixing device according to claim 1, characterized in that: first pivot (21) correspond first hob (27) position department rigid coupling has rotation sleeve (23), first hob (27) rotate connect in rotate sleeve (23), it corresponds to rotate sleeve (23) first hob (27) rotate the junction and all are provided with deep groove ball bearing (28), deep groove ball bearing (28) outer lane rigid coupling in rotate sleeve (23), the inner circle rigid coupling in first hob (27).

6. The efficient spherical graphite mixing device according to claim 1, characterized in that: the upside of the mounting plate (12) corresponds to the position of the second rotating shaft (31) and is provided with a plane thrust bearing (37), and the plane thrust bearing (37) is rotationally connected with the second rotating shaft (31).

7. A high-efficient spherical graphite compounding device according to claim 5, characterized in that: mounting panel (12) upside corresponds it has support sleeve (24) to rotate sleeve (23) position department rigid coupling, support sleeve (24) rotate connect in rotate sleeve (23), support sleeve (24) can be right first hob (27) play the supporting role.

8. The efficient spherical graphite mixing device according to claim 1, characterized in that: and one end of the second rotating shaft (31) far away from the mounting plate (12) is fixedly connected with a third spiral rod (36) which is coaxially arranged.

9. The efficient spherical graphite mixing device according to claim 1, characterized in that: frame (1) correspond one-level mixing portion (2) with access door (15) have all been seted up to second grade mixing portion (3) lateral wall.

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