CN113663603A - Cobalt mud deep-processing system - Google Patents

Abstract

The invention discloses a cobalt mud deep processing system, which comprises a fixing frame, a raw material extruder and a processing box body, and further comprises: and the kneading mechanism is arranged in the processing box body and comprises a first kneading plate, a second kneading plate and a driving gear meshed with the first kneading plate and the second kneading plate, and the first kneading plate and the second kneading plate keep reciprocating motion through the driving gear so as to knead cobalt mud between the first kneading plate and the second kneading plate into cobalt mud strips. According to the cobalt mud deep processing system provided by the invention, the cobalt mud groups are input into the processing box body through the raw material extruder, the cobalt mud groups are kneaded into strips through the reciprocating motion of the first kneading plate and the second kneading plate of the kneading mechanism, and then the cobalt mud strips are cut into sections through the cutting mechanism arranged at the output end of the processing box body to form cobalt mud blocks, so that the cobalt mud blocks can be conveniently processed into round granules in the subsequent process, the existing first-stage main machine and second-stage main machine are replaced, and the damage of the cobalt mud strips and the secondary processing cost in the transfer process are further reduced.

Description

Cobalt mud deep-processing system

Technical Field

The invention relates to a cobalt mud deep processing system.

Background

The cobalt powder is easy to oxidize due to fine particles, dust is easy to raise in the production and use processes, the working environment is seriously affected, the problems of oxidation and dust raising of the cobalt powder raw material can be effectively reduced after the cobalt powder is prepared into large particles, and the cobalt powder is widely applied to the cobalt processing industry.

According to the publication date: 2013-03-27, the publication number is: the invention patent application of CN102240811B discloses a production method of granulated cobalt powder, which is characterized by comprising the following steps: (1) mixing the melted granulating agent with an organic solvent to obtain a granulating agent dispersion liquid; (2) under the condition of isolating oxygen, uniformly mixing the granulating agent dispersion liquid with cobalt powder; (3) kneading and granulating the cobalt powder; (4) vacuum drying to obtain granulated cobalt powder; in the step (1), the melting temperature of the granulating agent is 60-100 ℃; in the step (2), the granulating agent accounts for 2-4% of the mass of the cobalt powder, and the granulating agent dispersion liquid is sprayed on the cobalt powder in a spray form and is uniformly mixed by rolling; in the step, the vacuum drying temperature is 120-150 ℃. The main technical effects are as follows: the obtained granulated cobalt powder plays a role of large particles during the processing of the hard alloy, and plays a role of fine particles due to the evaporation of the granulating agent when being mixed and sintered with tungsten carbide; the oxidation resistance is good, the oxidation is not easy, the carbon balance of the hard alloy is kept in metallurgy, and the quality of the hard alloy is improved; can be stored for a long time and is convenient to transport; the fluidity is good, and the automatic pressing of the hard alloy is facilitated; the dust is little flying, and the method plays an important role in improving the production environment of the hard alloy and improving the occupational health.

The existing cobalt powder granulating process comprises the following steps: after making cobalt mud, make cobalt mud into the cobalt mud strip via first order host computer, enter into the second level host computer through transporting the cobalt mud strip again, cut into the cobalt mud piece with the cobalt mud strip, grind into cobalt grain through third level host computer again, in transporting the process by first order host computer to the second level host computer, long banding cobalt mud strip is difficult for transporting, causes the cobalt mud strip to damage easily, increases the secondary processing cost.

Disclosure of Invention

The invention aims to provide a cobalt mud deep processing system, and aims to solve the problems that strip-shaped cobalt mud strips are difficult to transport and easy to damage in the process of transferring from a primary host to a secondary host, and the secondary processing cost is increased.

In order to achieve the above purpose, the invention provides the following technical scheme: the utility model provides a cobalt mud deep-processing system, includes the mount, set up in the raw materials extruder of mount one end and set up in processing box on the mount still includes:

the kneading mechanism is arranged in the processing box body and comprises a first kneading plate, a second kneading plate and a driving gear meshed with the first kneading plate and the second kneading plate, and the first kneading plate and the second kneading plate keep reciprocating motion through the driving gear so as to knead cobalt mud between the first kneading plate and the second kneading plate into cobalt mud strips;

and the cutting mechanism is arranged on one side of the fixed frame and enables the cobalt mud strips to be cut into cobalt mud blocks through cutting blocks.

Preferably, the processing box further comprises reversing gear sets meshed with the driving gears, the reversing gear sets are symmetrically arranged on two sides of the processing box body, and the reversing gear sets enable the driving gears to keep reciprocating rotation through gear rings.

Preferably, the reversing gear set includes a driving wheel, and a first gear and a second gear engaged with the ring gear, and the driving wheel keeps the first gear and the second gear rotating, respectively, so as to keep the ring gear reciprocating.

Preferably, the reversing gear set further comprises a transmission connecting rod, wherein the transmission connecting rod is in transmission connection with the two reversing gear sets respectively and keeps unidirectional rotation through a driving motor.

Preferably, the device further comprises a driving gear, wherein the driving gear keeps reciprocating rotation through a gear ring and keeps reciprocating motion of the driving gear.

Preferably, at least one forming mechanism is arranged on the first kneading plate and the second kneading plate, and the forming mechanism cools and forms cobalt mud between the first kneading plate and the second kneading plate through a constant temperature part and a cooling part.

Preferably, the cooling device further comprises a connecting part, wherein the connecting part is connected with the constant temperature part and the cooling part at two ends respectively, and heat is transferred through the connecting part.

Preferably, the cutting mechanism further comprises a cam which is kept in one-way rotation by a transmission connecting rod and keeps the cutting block in reciprocating motion by the connecting rod.

Preferably, the cutting mechanism further comprises a cam which is kept in one-way rotation by a transmission connecting rod and keeps the cutting block in reciprocating motion by the connecting rod.

Preferably, the processing box further comprises an auxiliary wheel arranged in the processing box body, and the auxiliary wheel is matched with the first kneading plate and the second kneading plate to form a material extruding channel.

In the technical scheme, the cobalt mud deep processing system provided by the invention has the following beneficial effects: input the cobalt mud through raw materials extruder inside to processing box, the reciprocating motion of the first kneading board and the second kneading board of mechanism is rubbed to the rethread, make the cobalt mud group rub into the strip, the rethread sets up the cutting mechanism at processing box output, cut into the section with the cobalt mud strip, form the cobalt mud piece, make things convenient for follow-up processing to make the round grain, replace current first order host computer and second level host computer, and then reduce damage and the secondary operation cost of cobalt mud strip in the transportation.

Drawings

In order to more clearly illustrate the embodiments of the present application or technical solutions in the prior art, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments described in the present invention, and other drawings can be obtained by those skilled in the art according to the drawings.

Fig. 1 is a schematic perspective view of an embodiment of the present invention;

FIG. 2 is a schematic structural diagram of a forming mechanism according to an embodiment of the present invention;

FIG. 3 is a schematic structural view of a reversing gear set provided in accordance with an embodiment of the present invention;

fig. 4 is a schematic structural view of a kneading mechanism according to an embodiment of the present invention;

FIG. 5 is a schematic structural diagram of a cutting mechanism according to an embodiment of the present invention;

FIG. 6 is a schematic structural diagram of a movable position of the cutting mechanism according to an embodiment of the present invention;

FIG. 7 is a schematic diagram of an output tube structure according to an embodiment of the present invention;

FIG. 8 is a schematic structural diagram of a cutting base according to an embodiment of the present invention;

FIG. 9 is a schematic structural diagram of an installation position of an auxiliary wheel according to an embodiment of the present invention;

fig. 10 is a schematic view of an internal structure of a processing box according to an embodiment of the present invention.

Description of reference numerals:

1. a fixed mount; 2. a raw material extruder; 3. processing the box body; 31. mounting a plate; 32. a support frame; 33. a fixed tube; 34. an output pipe; 341. positioning blocks; 4. a kneading mechanism; 41. a drive gear; 42. a first kneading plate; 43. a second kneading plate; 44. a first toothed plate; 45. a second toothed plate; 5. a cutting mechanism; 51. cutting the block; 511. a first cutting block; 512. a second cutting block; 52. a cam; 53. a connecting rod; 54. cutting the base; 55. a fixing plate; 56. a limiting seat; 6. a reversing gear set; 61. a ring gear; 62. a drive wheel; 63. a first gear; 64. a second gear; 7. a transmission connecting rod; 8. a drive mechanism; 9. a driving gear; 10. a molding mechanism; 101. a constant temperature part; 102. a cooling section; 103. a connecting portion; 11. an auxiliary wheel; 111. a wheel carrier; 112. a leak-proof strip; 12. a discharge hopper.

Detailed Description

In order to make the technical solutions of the present invention better understood, those skilled in the art will now describe the present invention in further detail with reference to the accompanying drawings.

As shown in fig. 1-10, a cobalt mud deep-processing system, including mount 1, set up in the raw materials extruder 2 of 1 one end of mount and set up the processing box 3 on mount 1, still include:

a kneading mechanism 4 arranged in the processing box 3, wherein the kneading mechanism 4 comprises a first kneading plate 42, a second kneading plate 43 and a driving gear 41 engaged with the first kneading plate and the second kneading plate 43, and the first kneading plate 42 and the second kneading plate 43 are kept reciprocating by the driving gear 41 so as to knead cobalt mud between the first kneading plate 42 and the second kneading plate 43 into cobalt mud strips;

and the cutting mechanism 5 is arranged on one side of the fixed frame 1 and enables the cobalt mud strips to be cut into cobalt mud blocks through the cutting block 51.

The processing box body 3 is supported by the arranged fixed frame 1, the cobalt mud is kneaded and molded by the kneading mechanism 4 in the processing box body 3, the cobalt mud is made into cobalt mud strips, the output end of the raw material extruder 2 is connected with the input end of the processing box body 3, the raw material extruder 2 on the fixed frame 1 has a heating function, cobalt mud groups are put into the raw material extruder 2 by workers, the cobalt mud groups are heated by the raw material extruder 2 to be softened and have certain viscosity, the cobalt mud groups cannot be loosened, the softened cobalt mud is conveyed into the processing box body 3 by the raw material extruder 2, the two ends of the first kneading plate 42 are respectively provided with a first toothed plate 44, the two ends of the second kneading plate 43 are respectively provided with a second toothed plate 45, at least one driving gear 41 is rotatably arranged on the inner walls of the two sides of the processing box body 3, the first kneading plate 42 is arranged in the processing box body 3 in a sliding manner, the first rubbing plate 42 is engaged with the driving gear 41 through the first toothed plate 44 disposed at two ends, so that the first rubbing plate 42 can keep sliding while the driving gear 41 keeps rotating, the second rubbing plate 43 and the first rubbing plate 42 are symmetrically disposed with the axial direction of the processing box 3 as a symmetric center, and the second rubbing plate 43 is slidably disposed inside the processing box 3, the second rubbing plate 43 is engaged with one side of the driving gear 41 opposite to the first toothed plate 44 through the second toothed plates 45 disposed at two sides, and the second toothed plate 45 keeps sliding through the rotation of the driving gear 41, when the driving gear 41 keeps rotating, the first toothed plate 44 and the second toothed plate 45 keep moving in opposite directions or in reverse directions, so that the first rubbing plate 42 connected with the first toothed plate 44 and the second rubbing plate 43 connected with the second toothed plate 45 keep sliding inside the processing box 3, the cutting mechanism 5 is disposed at one side of the fixing frame 1, cutting mechanism 5 is located the output of processing box 3, a cobalt mud strip for will follow the interior output of processing box 3 cuts into the piece, the round grain is made in the follow-up processing of being convenient for, keep the ascending reciprocating motion of vertical side to cut off fashioned cobalt mud strip through cutting block 51 and make the piece, be provided with support frame 32 between mount 1 and processing box 3, support frame 32 is the triangle-shaped structure, can increase the supporting role to processing box 3, prevent to make the inside production of processing box 3 rock when the kneading mechanism 4 of processing box 3 inside moves.

According to the invention, the cobalt mud mass is input into the processing box body 3 through the raw material extruder 2, and is kneaded into a strip shape through the reciprocating motion of the first kneading plate 42 and the second kneading plate 43 of the kneading mechanism 4, and then the cobalt mud strip is cut into sections through the cutting mechanism 5 arranged at the output end of the processing box body 3 to form cobalt mud blocks, so that the cobalt mud blocks can be conveniently processed into round granules, the existing first-stage main machine and second-stage main machine are replaced, and the damage of the cobalt mud strip and the secondary processing cost in the transfer process are reduced.

Fixed mounting has mounting panel 31 on the outer wall of processing box 3, drive gear 41 rotates and sets up between the inner wall of processing box 3 and mounting panel 31, the both sides of processing box 3 all are provided with reversing gear set 6, reversing gear set 6 of both sides can match first pinion rack 44 of first kneading board 42 both sides and second pinion rack 45 of second kneading board 43 both sides better, make first kneading board 42, second kneading board 43 can steadily keep sliding in processing box 3 inside, the arc wall has been seted up on the outer wall of processing box 3, the outer wall of ring gear 61 rotates and sets up inside the arc wall, and can keep rotating along the inner wall of arc wall, reversing gear set 6 makes first kneading board 42, second kneading board 43 keeps reciprocating sliding along processing box 3 inner wall through making ring gear 61 keep reciprocating rotation.

Further, the driving wheel 62 is of an incomplete gear structure, the driving wheel 62 is rotatably connected to the outer wall of the mounting plate 31 through a bearing, the outer wall of the mounting plate 31 is rotatably provided with a first gear 63 and a second gear 64, the first gear 63 and the second gear 64 are respectively meshed with the gear ring 61, so that the gear ring 61 can be kept to rotate through the rotation of the first gear 63 and the second gear 64, the first gear 63 and the second gear 64 are symmetrically distributed about the driving wheel 62, the driving wheel 62 keeps rotating, the driving wheel 62 is firstly meshed with the first gear 63, the gear ring 61 keeps rotating in a forward direction through the first gear 63, then the driving wheel 62 keeps rotating continuously, the driving wheel 62 is meshed with the second gear 64, the second gear 64 keeps rotating, and the gear ring 61 rotates in a reverse direction through the rotation of the second gear 64.

Actuating mechanism 8 is preferred driving motor, its output and the fixed welding of transmission connecting rod 7, make transmission connecting rod 7 keep the same rotational speed rather than the output through driving motor, mounting panel 31 is installed at the top symmetry of processing box 3, transmission connecting rod 7 rotates and sets up between two mounting panels 31, and the both ends of transmission connecting rod 7 run through respectively and extend to the outer wall of two mounting panels 31, driving motor fixed mounting is on the outer wall of raw materials extruder 2 one side, when using, driving motor drive transmission connecting rod 7 keeps rotating, drive wheel 62 fixed mounting is on the outer wall of transmission connecting rod 7, when transmission connecting rod 7 keeps rotating under driving motor's drive, transmission connecting rod 7 makes drive wheel 62 keep synchronous rotation.

The driving gear 9 is fixedly mounted on the outer wall of one side of the gear ring 61, so that the driving gear 9 can keep rotating while the gear ring 61 keeps rotating, the driving gear 9 keeps synchronously rotating along with the gear ring 61, the driving gear 9 is meshed with the driving gear 41, when the driving gear 9 keeps rotating along with the gear ring 61, the driving gear 41 is meshed and rotates under the action of the driving gear 9, further, the first toothed plate 44 and the second toothed plate 45 meshed with the driving gear 41 keep sliding inside the processing box 3, finally, the first rubbing plate 42 and the second rubbing plate 43 keep sliding inside the processing box 3, the thickness of the driving gear 9 is smaller than that of the driving gear 41, and when the processing device is used, the driving gear 9 keeps the same rotating speed under the rotation of the gear ring 61, and enables the driving gear 41 to rotate through gear transmission.

The forming mechanism 10 is at least one arranged on the outer walls of the first rubbing plate 42 and the second rubbing plate 43, the forming mechanism 10 comprises a constant temperature part 101 and a cooling part 102, the constant temperature part 101 is arranged on one side of the first rubbing plate 42 close to the raw material extruder 2, the cooling part 102 is arranged at one end of the first rubbing plate 42 far away from the raw material extruder 2, the cooling part 102 is preferably a semiconductor chilling plate, the semiconductor chilling plate is arranged in a linear array, the distance between every two semiconductor chilling plates is 10cm, the semiconductor chilling plates are arranged at intervals, heat conduction can be facilitated, the heat dissipation effect on the semiconductor chilling plates is increased, an exhaust fan 104 is fixedly arranged outside the cooling part 102 and used for rapidly dissipating heat generated by the semiconductor chilling plates to prevent the semiconductor chilling plates from being damaged due to overheating in the using process, and the constant temperature part 101 is preferably a heating plate, the heating sheets generate heat, the first rubbing plate 42 conducts the temperature, the outer wall of the first rubbing plate 42 has a certain temperature through heat transmission, the cobalt mud is prevented from being solidified before being formed in the rubbing process, when the cobalt mud is used, the raw material extruder 2 heats the cobalt mud and outputs the cobalt mud into the processing box body 3 through the output end of the cobalt mud, one end, close to the raw material extruder 2, of the first rubbing plate 42 has a certain temperature, the cobalt mud can be kept warm, the cobalt mud is prevented from being cooled before being rubbed and formed in the rubbing process, then the cobalt mud in the processing box body 3 can be rubbed into strips through the reciprocating motion of the first rubbing plate 42 and the second rubbing plate 43, the cobalt mud strips can be contacted with one end, far away from the raw material extrusion plate, of the first rubbing plate 42 under the action of the semiconductor refrigerating sheets, the temperature of one end, far away from the raw material extrusion plate, of the first rubbing plate 42 is lower, the cobalt mud strip between the first kneading plate 42 and the second kneading plate 43 can be cooled, solidified and formed. The outer walls of the first kneading plate 42 and the second kneading plate 43 are respectively provided with an oblique bulge, the oblique bulges can convey the cobalt mud strips between the first kneading plate 42 and the second kneading plate 43 to one direction, when the cobalt mud strip processing device is used, when the first kneading plate 42 and the second kneading plate 43 keep reciprocating sliding, the oblique bulges on the outer walls of the first kneading plate 42 and the second kneading plate 43 can convey the cobalt mud strips to the output end direction of the processing box body 3, and further the cobalt mud strips in the processing box body 3 are extruded out of the processing box body 3.

The connecting part 103 is connected between the constant temperature part 101 and the cooling part 102, the connecting part 103 is preferably a copper sheet with the width of 10cm, the copper sheet has excellent heat conducting performance, and a part of heat generated by the semiconductor refrigeration sheet of the cooling part 102 can be conducted to the heating sheet of the constant temperature part 101, so that the energy consumption is reduced.

The cutting mechanism 5 further comprises a cam 52, the cam 52 is fixedly installed on the outer wall of the transmission connecting rod 7, when the transmission connecting rod 7 keeps rotating, the cam 52 keeps rotating synchronously, a shaft rod is fixedly installed on the outer wall of the cam 52, one end of a connecting rod 53 is rotatably connected to the outer wall of the shaft rod, the other end of the connecting rod 53 is rotatably connected to the outer wall of the cam 52, and when the cam 52 keeps rotating, the cutting block 51 can keep sliding in a cutting base 54 through the pulling of the connecting rod 53.

The cutting base 54 is preferably of a double-layer structure, a through groove is formed in the middle shaft of the upper surface of the cutting base 54, the through groove is used for forming cobalt mud blocks through cutting, the lower layer of the double-layer structure is used for communicating the discharge hopper 12, the discharge hopper 12 is welded on the outer wall of one side of the fixing frame 1 and used for receiving cobalt powder blocks falling from the cutting base 54, the cobalt powder blocks are divided into materials, the formed cobalt powder blocks are conveyed into the sub-packaging bags, and workers can transport the cobalt powder blocks conveniently. The cutting base 54 is provided with a first cutting block 511 and a second cutting block 512, wherein the first cutting block 511 is fixedly arranged on the inner wall of one side of the passing groove, the second cutting block 512 is fixedly arranged on the inner wall of one side of the passing groove opposite to the first cutting block 511, fixing plates 55 are respectively and fixedly arranged on two sides of the passing groove, the cutting block 51 is connected between the two fixing plates 55 in a sliding manner, the cutting block 51 keeps sliding in the fixing plates 55 through a cam 52 and a connecting rod 53, a third cutting block 51 matched with the first cutting block 511 and a fourth cutting block 51 matched with the second cutting block 512 are fixedly arranged on the outer wall of one side of the cutting block 51, when in use, the raw material extruder 2 continuously conveys cobalt mud into the processing box body 3, and conveys the cobalt mud strips out of the processing box body 3 through the conveying action exerted on the cobalt mud strips by the reciprocating motion of the first kneading plate 42 and the second kneading plate 43, after the cobalt mud strip passes through the interior of the processing box body 3, the cobalt mud strip is solidified and formed, and can be cut by hard metal, one end of the cobalt mud strip moves forwards to a position between the first cutting block 511 and the second cutting block 512 under the conveying action, then under the action of the cam 52, the cam 52 drives the connecting rod 53 to rotate by keeping unidirectional rotation, under the rotation of the cam 52, the connecting rod 53 keeps rotating, the cutting block 51 at the other end of the connecting rod 53 is driven and pulled, the cutting block 51 firstly keeps moving vertically upwards along the fixing plate 55 under the action of the connecting rod 53, at the moment, the cam 52 keeps rotating continuously, so that the connecting rod 53 keeps rotating continuously, under the action of the connecting rod 53, after the cutting block 51 vertically upwards reaches a limit position, the connecting rod 53 is pushed by the rotation of the cam 52, the cutting block 51 is pushed by pushing and keeps moving vertically downwards along the outer wall of the fixing plate 55 under the action of the connecting rod 53, and then the third cutting block 51 and the fourth cutting block 51 arranged on the cutting block 51 are matched with the first cutting block 511 and the second cutting block 512 arranged on the cutting base 54, so that the first cutting block 511 and the second cutting block 512 are respectively matched with the third cutting block 51 and the fourth cutting block 51, the outer walls of two sides of the formed cobalt mud strip are cut off, the original strip-shaped cobalt mud strip is cut into blocks similar to a cylinder, the subsequent processing and the grinding into spherical particles are facilitated, a limiting seat 56 is fixedly arranged on the outer wall of one side of the cutting base 54, a limiting hole is formed in the outer wall of the limiting seat 56, and the formed cobalt powder strip can reach the inside of the cutting base 54 through the limiting hole.

A fixed pipe 33 is fixedly arranged at one end of the processing box body 3, namely the input end of the processing box body 3, the fixed pipe 33 is fixedly communicated with the output end of the raw material extruder 2, the raw material extruder 2 can heat the cobalt powder group and extrude the cobalt powder group into the fixed pipe 33, the cobalt powder group enters the processing box body 3 through the fixed pipe 33, the cobalt mud group is gradually extruded between the first rubbing plate 42 and the second rubbing plate 43 along with the continuous extrusion action of the raw material extruder 2, the cobalt mud group is rubbed into a regular cylindrical strip shape through the rubbing mechanism 4, an output pipe 34 is fixedly arranged at the other end of the processing box body 3, namely the output end of the processing box body 3, when the rubbing mechanism 4 rubs and shapes the cobalt mud strip and continuously conveys the cobalt mud strip, one end of the cobalt mud strip continuously moves towards the output end of the processing box body 3, a positioning block 341 is movably connected to the inner part of the output pipe 34 through a screw thread piece, the outer wall of one side of the positioning block 341 and the outer wall of one side of the second kneading plate 43 are in the same horizontal plane or slightly lower than the outer wall of one side of the second kneading plate 43, so that when the formed cobalt mud strip moves towards the output pipe 34 under the action of the kneading mechanism 4, the formed cobalt mud strip does not collide with the port of the output pipe 34. The inner walls of two sides of the processing box body 3 are fixedly provided with a wheel frame 111, the wheel frame 111 is connected with an auxiliary wheel 11 in a rotating way, the auxiliary wheel 11 can keep free rotation in the wheel frame 111, the auxiliary wheel 11 is used for contacting with cobalt mud lumps and assisting the first kneading plate 42 and the second kneading plate 43 in kneading and forming the cobalt mud lumps, in the using process, under the action of the raw material extruder 2, the heated cobalt mud lumps with certain shaping reach the inside of the processing box body 3 through the fixed pipe 33, the cobalt mud lumps are kept in rotary motion through the first kneading plate 42 and the second kneading plate 43 of the kneading mechanism 4, and because the auxiliary wheel 11 can keep free rotation in the wheel frame 111, when the cobalt mud lumps keep reciprocating motion under the action of the first kneading plate 42 and the second kneading plate 43, because the auxiliary wheel 11 keeps contact with the outer wall of the cobalt mud strips, under the rotation of the cobalt mud strips, the auxiliary wheel 11 keeps rotation, and (5) auxiliary forming of the cobalt mud strips. The leakage-proof strips 112 are respectively and fixedly arranged between the fixed pipe 33 and the output pipe 34, the number of the leakage-proof strips 112 is four, and the four leakage-proof strips 112 are respectively arranged on two sides of every two auxiliary wheels 11, so that two sides of the auxiliary wheels 11 are isolated from the inner part of the processing box body 3.

While certain exemplary embodiments of the present invention have been described above by way of illustration only, it will be apparent to those of ordinary skill in the art that the described embodiments may be modified in various different ways without departing from the spirit and scope of the invention. Accordingly, the drawings and description are illustrative in nature and should not be construed as limiting the scope of the invention.

Claims (10)

1. The utility model provides a cobalt mud deep-processing system, includes mount (1), set up in raw materials extruder (2) of mount (1) one end and set up in processing box (3) on mount (1), its characterized in that still includes:

the kneading mechanism (4) is arranged in the processing box body (3), the kneading mechanism (4) comprises a first kneading plate (42), a second kneading plate (43) and a driving gear (41) meshed with the first kneading plate and the second kneading plate, and the first kneading plate (42) and the second kneading plate (43) keep reciprocating motion through the driving gear (41) so as to knead cobalt mud between the first kneading plate (42) and the second kneading plate (43) into cobalt mud strips;

and the cutting mechanism (5) is arranged on one side of the fixed frame (1) and enables the cobalt mud strips to be cut into cobalt mud blocks through a cutting block (51).

2. The cobalt mud deep processing system as claimed in claim 1, further comprising a reversing gear set (6) meshed with the driving gear (41), wherein the reversing gear set (6) is symmetrically arranged at two sides of the processing box body (3) and keeps the driving gear (41) to rotate back and forth through a gear ring (61).

3. The cobalt sludge further processing system according to claim 2, wherein the reversing gear set (6) comprises a driving wheel (62) and a first gear (63) and a second gear (64) which are meshed with a gear ring (61), and the first gear (63) and the second gear (64) are respectively kept rotating by the driving wheel (62) so as to keep the gear ring (61) in a reciprocating motion.

4. The cobalt mud deep processing system according to claim 3, characterized by further comprising a transmission connecting rod (537), wherein the transmission connecting rod (537) is respectively in transmission connection with the two reversing gear sets (6), and is kept in unidirectional rotation by a driving mechanism (8).

5. A cobalt sludge further processing system according to claim 3, further comprising a driving gear (9), wherein the driving gear (9) keeps reciprocating rotation through a gear ring (61) and keeps reciprocating motion of the driving gear (41).

6. The cobalt mud deep processing system according to claim 1, wherein at least one forming mechanism (10) is arranged on the first kneading plate (42) and the second kneading plate (43), and the cobalt mud between the first kneading plate (42) and the second kneading plate (43) is formed through cooling by a constant temperature part (101) and a cooling part (102).

7. The cobalt mud deep processing system according to claim 6, further comprising a connecting part (103), wherein the two ends of the connecting part (103) are respectively connected with the constant temperature part (101) and the cooling part (102), and heat is transferred through the connecting part (103).

8. A cobalt sludge further processing system according to claim 7, characterized in that the cutting mechanism (5) further comprises a cam (52), the cam (52) is kept in one-way rotation by a transmission connecting rod (537) and keeps the cutting block (51) in reciprocating motion by a connecting rod (53).

9. A cobalt sludge further processing system according to claim 1, wherein the cutting mechanism (5) further comprises a cutting base (54) cooperating with the cutting block (51) for cutting the cobalt sludge strip into pieces by reciprocating movement of the cutting block (51).

10. The cobalt mud deep processing system according to claim 1, further comprising an auxiliary wheel (11) arranged in the processing box body (3), wherein the auxiliary wheel (11) is matched with the first kneading plate (42) and the second kneading plate (43) to form an extruding channel.

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