CN114054176A

CN114054176A - Granulating equipment for producing high-carbon ferromanganese from manganese metal

Info

Publication number: CN114054176A
Application number: CN202111320167.2A
Authority: CN
Inventors: 罗兴友; 谭和宋; 张社军
Original assignee: Hunan Jiuding New Material Co ltd
Current assignee: Hunan Jiuding New Material Co ltd
Priority date: 2021-11-09
Filing date: 2021-11-09
Publication date: 2022-02-18

Abstract

The utility model relates to the field of granulation equipment, in particular to granulation equipment for producing high-carbon ferromanganese from manganese metal. The technical problem to be solved by the technical scheme is as follows: the existing high-carbon ferromanganese granulating equipment has insufficient uniformity for granulating high-carbon ferromanganese, and reduces the efficiency of subsequent production. The automatic feeding and discharging device comprises a supporting device, a discharging device, a granulating device, a servo motor, a bidirectional screw rod, a toothed belt, a screening baffle and a toothed belt wheel, wherein the discharging device for guiding materials is symmetrically and fixedly connected to the upper end face of the supporting device, two groups of mounting clamping plates are symmetrically and fixedly connected to the side end face of the supporting device, the bidirectional screw rod is rotatably clamped inside the mounting clamping plates, and the toothed belt wheel is fixedly connected to the end head of the side end face of the bidirectional screw rod. The beneficial effects of this technical scheme do: when using, the user can carry out abundant granulation to high carbon ferromanganese raw materials through the granulation cutter by two sets of squeeze rolls and smash to improve follow-up device and carry out the degree of consistency of granulation to high carbon ferromanganese raw materials.

Description

Granulating equipment for producing high-carbon ferromanganese from manganese metal

Technical Field

The utility model relates to the field of granulation equipment, in particular to granulation equipment for producing high-carbon ferromanganese from manganese metal.

Background

The high-carbon ferromanganese is an alloy consisting of manganese and iron, and is produced by a blast furnace method and an electric furnace, the high-carbon ferromanganese of the electric furnace is mainly used as a deoxidizer, a desulfurizer and an alloy additive for steel making, in addition, along with the improvement of the production process of the medium-low carbon ferromanganese, the high-carbon ferromanganese can also be applied to the production of the medium-low carbon ferromanganese, when the high-carbon ferromanganese is produced, granulation equipment is required to be used for preliminary production, but the existing granulation equipment cannot adjust the size of the produced granules according to the requirements of users, so that the practicability of the device is reduced, and when the production is carried out, the utilization efficiency of the equipment on power is insufficient, so that the production cost is improved.

Through patent search, there are the following known prior art solutions:

patent 1: the utility model discloses a granulating device for producing high-carbon ferromanganese by manganese metal, which comprises a shell, wherein an upper crushing plate is slidably connected to the inner side wall of the shell, a lower crushing plate is attached to the lower surface of the upper crushing plate, first springs are fixedly connected to the four corners of the lower surface of the lower crushing plate, a fixing plate is fixedly connected to the lower ends of the four first springs, a convex plate is integrally formed on the upper surface of the fixing plate, first through holes are uniformly formed in the fixing plate from top to bottom, blind grooves are formed in the lower surface of the lower crushing plate, second through holes are uniformly formed in the lower crushing plate from top to bottom, the granulating device does not use manpower for processing and crushing through extrusion crushing in the shell, a large amount of labor force is saved, and through holes which are distributed in a staggered mode are formed in the lower crushing plate and the upper crushing plate, the fragments with proper size can be discharged during the crushing process without further screening, thereby saving material resources.

Patent 2: the utility model discloses a high-carbon ferromanganese granulating device, which belongs to the technical field of high-carbon ferromanganese production, and solves the defects in the prior art by applying No. CN201320247383.3, application date, 20130509, granted announcement date, 20131120, and adopts the technical scheme that: a high-carbon ferromanganese granulating device comprises a first driving wheel, a second driving wheel and a driving mechanism, wherein the driving mechanism drives the first driving wheel to rotate, the first driving wheel is connected with the second driving wheel through a chain, a guide rail is arranged between the first driving wheel and the second driving wheel, an ingot mold frame is arranged on the guide rail in a matching manner, the ingot mold frame can slide along the guide rail through the driving of the chain, a plurality of ingot molds are arranged on the ingot mold frame, and a water spray pipe is arranged on the guide rail.

Through the above search, the above technical solutions cannot affect the novelty of the present invention, and the mutual combination of the above patent documents cannot destroy the creativity of the present invention.

Disclosure of Invention

The technical problem to be solved by the technical scheme is as follows: the existing high-carbon ferromanganese granulating equipment has insufficient uniformity for granulating high-carbon ferromanganese, and reduces the efficiency of subsequent production.

In order to realize the purpose, the utility model adopts the technical scheme that: a granulating device for producing high-carbon ferromanganese from manganese metal comprises a supporting device, a blanking device, a granulating device, a servo motor, a bidirectional screw rod, a toothed belt, a screening baffle plate and a toothed belt wheel, wherein the blanking device for guiding materials is symmetrically and fixedly connected to the upper end surface of the supporting device, two groups of mounting clamping plates are symmetrically and fixedly connected to the side end surface of the supporting device, a bidirectional screw rod is rotatably clamped in the mounting clamping plates, a toothed belt wheel is fixedly connected to the end head of the side end surface of the bidirectional screw rod, and the two groups of toothed belt wheels are meshed and rotationally connected through a toothed belt, a servo motor is fixedly connected at the position of the side end surface of the bidirectional screw rod, which deviates from the toothed belt wheels, the inner end face of the supporting device is connected with a granulating device through two-way screw rod symmetrical threads in a sliding mode, and a screening baffle is fixedly connected to the bottom end face of the supporting device.

The beneficial effects of this technical scheme do: when the device is used, a user can position an external high-carbon ferromanganese feeding device to the upper parts of the two groups of blanking devices, then the external connecting belt is connected with the outside of the fixed belt pulley, so that the subsequent power transmission for the blanking devices is convenient, and further the granulation operation of the high-carbon ferromanganese raw material is convenient, when the granulation is carried out, the external feeding device can convey the raw material to the inside of the blanking box body, at the moment, the two groups of fixed belt pulleys can drive the spiral blanking plate at the bottom to rotate due to the meshed connection of the fixed belt pulley and the external connecting belt, meanwhile, when the spiral blanking plate rotates, the spiral blanking plate is spirally arranged, so that the spiral blanking plate can spirally guide and press down the high-carbon ferromanganese raw materials with different sizes, thereby the raw material is guided to the inside of the supporting device from the bottom of the blanking devices, and then the user can start the two groups of connecting motors through the external control device, connection motor can drive the squeeze roll and rotate this moment, because mesh through connecting the gear between the upper and lower two sets of squeeze rolls and rotate the connection, and then can carry out relative rotation between the two sets of squeeze rolls about making, and when two sets of squeeze rolls rotated about, the granulation cutter does not take place spacing and contact, prevent that follow-up spacing influence granulation operation that takes place, space has between inside two sets of squeeze rolls of strutting arrangement and the granulation cutter, the raw materials that drops from unloading bottom of the case portion can just be fixed a position between the space, relative two sets of squeeze rolls can carry out abundant granulation crushing to high-carbon ferromanganese raw materials through the granulation cutter this moment, the raw materials after smashing falls to the upper portion of screening baffle, the screening baffle can be to the raw materials and then sieve many times, thereby improve the homogeneity of high-carbon ferromanganese granulation.

The technical problem to be solved by the improvement of the technical scheme is as follows: the existing granulating equipment can not adjust the size of the produced granules according to the requirements of users, thereby reducing the practicability of the device.

In order to realize the purposes, the utility model creates the technical scheme adopted after improvement: the supporting device comprises a limiting clamping groove, a supporting baffle, a fixing shell, a positioning sliding groove and a clamping sliding groove, the supporting baffle is fixedly connected to the center of the upper end face of the fixing shell and located at the upper end face of the supporting baffle, the limiting clamping groove is symmetrically formed in the upper end face of the fixing shell, the clamping sliding groove is symmetrically formed in the side end face of the fixing shell, and the positioning sliding groove is formed in the position, close to the clamping sliding groove, of the side end face of the fixing shell.

The beneficial effect after this technical scheme improves does: if need carry out adaptability to the size of high carbon ferromanganese granulation and adjust, user's accessible external control device starts servo motor, servo motor can drive anterior two-way lead screw and rotate this moment, when two-way lead screw rotates simultaneously, two-way lead screw can drive anterior toothed belt wheel and rotate, make two sets of toothed belt wheel can rotate simultaneously through toothed belt, and then make the two-way lead screw synchronous rotation of strutting arrangement both sides, two-way lead screw is when rotating, can drive two sets of prilling granulator of strutting arrangement inside simultaneously through the threaded sleeve and carry out synchronous entad or centrifugal displacement, make distance between two sets of relative granulation cutters become to imitate or the grow, thereby can conveniently carry out the granulation operation of equidimension not to high carbon ferromanganese.

The technical problem to be solved by the improvement of the technical scheme is as follows: when the high-carbon ferromanganese is granulated and produced, the efficiency of guiding the raw materials is insufficient.

In order to realize the purposes, the utility model creates the technical scheme adopted after improvement: unloader includes unloading box, spiral flitch, fixed belt pulley and installation baffle down, the up end center fixedly connected with installation baffle of unloading box, and be located the lower terminal surface of installation baffle rotates the joint and has spiral flitch down, the up end of installation baffle just rotates the joint to spiral flitch department and has fixed belt pulley down.

The beneficial effect after this technical scheme improves does: when leading the raw materials, the spiral flitch can rotate under the drive of fixed belt pulley under the spiral, and the spiral flitch can compress the high carbon ferromanganese raw materials and carry simultaneously under to make high carbon ferromanganese raw materials pressfitting on the upper portion of squeeze roll, improve the efficiency to the high carbon ferromanganese granulation.

The technical problem to be solved by the improvement of the technical scheme is as follows: when the device is used for production, the utilization efficiency of the device to the power is insufficient, and the production cost is improved.

In order to realize the purposes, the utility model creates the technical scheme adopted after improvement: the granulation device comprises a connection motor, a threaded sleeve, a connection gear, a granulation cutter, a squeeze roller and an unloading guide plate, wherein the threaded sleeve is fixedly connected with the side end face of the unloading guide plate symmetrically and is positioned on the inner end face of the unloading guide plate symmetrically and rotatably connected with the squeeze roller, the connection gear is fixedly connected with the side end face of the squeeze roller symmetrically and is positioned on the outer end face of the squeeze roller uniformly and equidistantly and fixedly connected with the granulation cutter, and the side end face of the unloading guide plate is directly connected with the connection motor to the squeeze roller on the upper portion.

The beneficial effect after this technical scheme improves does: when processing, connect the motor and can drive upper and lower two sets of squeeze rolls simultaneously through connecting the gear and carry out relative rotation for four squeeze rolls can carry out two liang of relative rotations, thereby furthest's improvement the granulation efficiency of device, also improved the utilization efficiency of device to power simultaneously.

The technical problem to be solved by the improvement of the technical scheme is as follows: when equipment is in transmission, the stability of direction is not enough, has reduced the stability of follow-up regulation and control.

In order to realize the purposes, the utility model creates the technical scheme adopted after improvement: the outer end face of the threaded sleeve is provided with a threaded groove, and the granulating device is matched with the positioning sliding groove through the threaded sleeve and then is in sliding clamping connection with the inner end face of the fixed shell.

The beneficial effect after this technical scheme improves does: the positioning sliding groove can provide enough guiding bases for the two groups of granulating devices, so that the subsequent granulating devices can conduct quick and stable guiding conveniently, and the guiding stability is improved.

The technical problem to be solved by the improvement of the technical scheme is as follows: when equipment is transmitting, stability is not enough, and the efficiency of subsequent production is reduced.

In order to realize the purposes, the utility model creates the technical scheme adopted after improvement: the thread groove is in threaded connection with the bidirectional screw rod, and the granulating device is matched with the bidirectional screw rod through the thread groove and then is in threaded sliding connection with the outer end face of the supporting device.

The beneficial effect after this technical scheme improves does: the thread groove is connected with the thread of the bidirectional screw rod, so that the transmission stability between the devices can be effectively improved, and meanwhile, the thread connection can effectively improve the adjusting accuracy.

The technical problem to be solved by the improvement of the technical scheme is as follows: when the raw materials are guided, the stability of the guide is insufficient, and the efficiency of subsequent processing is reduced.

In order to realize the purposes, the utility model creates the technical scheme adopted after improvement: the upper and lower two groups of extrusion rollers are meshed through a connecting gear to be rotationally connected, and the outer edge of the spiral discharging plate is attached to the inner wall of the discharging box body.

The beneficial effect after this technical scheme improves does: big end down on the flitch is down in the spiral, and flitch outside and unloading box laminating are down in the spiral simultaneously for the raw materials of carrying can extrude, conveniently follow-up granulation operation of carrying on.

The technical problem to be solved by the improvement of the technical scheme is as follows: the equipment can not carry out quick even screening to the high carbon ferromanganese of granulation, has reduced follow-up efficiency to high carbon ferromanganese processing.

In order to realize the purposes, the utility model creates the technical scheme adopted after improvement: the screening baffle is including the spacing frame that is used for supporting, even equidistance fixed joint filter the cardboard and the guide cylinder of fixed connection in filtering the cardboard bottom in four groups inside the spacing frame.

The beneficial effect after this technical scheme improves does: the inside four groups of filtering cardboards and four groups of guide cylinders that are equipped with of spacing, spacing can shunt the raw materials that the granulation was accomplished to the follow-up filtering cardboard of furthest's improvement sieves the degree of consistency of selecting to the raw materials that the granulation was accomplished.

Drawings

Fig. 1 is an exploded view of the body of the present invention.

Fig. 2 is an assembly view of the main body of the present invention.

FIG. 3 is a schematic structural diagram of the supporting device of the present invention.

FIG. 4 is a schematic view of the blanking device of the present invention.

Fig. 5 is an exploded view of a pelletizing device according to the utility model.

Fig. 6 is an assembly view of a granulating apparatus according to the present invention.

The text labels in the figure are as follows: 1. a support device; 2. a blanking device; 3. a granulation device; 4. a servo motor; 5. a bidirectional screw rod; 6. a toothed belt; 7. screening the baffle plate; 8. a toothed belt pulley; 11. a limiting clamping groove; 12. a support baffle; 13. a stationary housing; 14. positioning the chute; 15. clamping the sliding chute; 21. a blanking box body; 22. a spiral blanking plate; 23. fixing the belt pulley; 24. installing a guide plate; 31. connecting a motor; 32. a threaded sleeve; 33. a connecting gear; 34. a granulation cutter; 35. a squeeze roll; 36. and a blanking guide plate.

Detailed Description

The following detailed description of the present invention is given for the purpose of better understanding technical solutions of the present invention by those skilled in the art, and the present description is only exemplary and explanatory and should not be construed as limiting the scope of the present invention in any way.

Example 1:

as shown in fig. 1-2, a granulation apparatus for producing high-carbon ferromanganese from manganese metal comprises a support device 1, a blanking device 2, a granulation device 3, a servo motor 4, a bidirectional screw rod 5, a toothed belt 6, a screening baffle 7 and toothed belt wheels 8, wherein the blanking device 2 for guiding material is symmetrically and fixedly connected to the upper end surface of the support device 1, two sets of mounting clamping plates are symmetrically and fixedly connected to the side end surface of the support device 1, the bidirectional screw rod 5 is rotatably clamped inside the mounting clamping plates, the toothed belt wheels 8 are fixedly connected to the end of the side end surface of the bidirectional screw rod 5, the two sets of toothed belt wheels 8 are meshed and rotatably connected through the toothed belt wheels 6, the servo motor 4 is fixedly connected to the side end surface of the bidirectional screw rod 5, which is deviated from the inner end surface of the toothed belt wheels 8, the granulation device 3 is slidably connected to the side end surface of the support device 1 through the bidirectional screw rod 5, and the bottom end face of the supporting device 1 is fixedly connected with a screening baffle 7, when in use, a user can position an external high-carbon ferromanganese feeding device to the upper parts of the two groups of blanking devices 2, then an external connecting belt is connected with the outside of the fixed belt pulley 23, so that the subsequent power transmission for the blanking devices 2 is facilitated, and further the granulation operation of the high-carbon ferromanganese raw materials is facilitated, when in granulation, the external feeding device can convey the raw materials to the inside of the blanking box body 21, at the moment, the two groups of fixed belt pulleys 23 can drive the spiral blanking plate 22 at the bottom to rotate due to the meshed connection of the fixed belt pulley 23 and the external connecting belt, and meanwhile, when the spiral blanking plate 22 rotates, the spiral blanking plate 22 is spirally arranged, so that the spiral blanking plate 22 can spirally guide and press the high-carbon ferromanganese raw materials with different sizes, thereby make the raw materials from the bottom of unloader 2 to the inside of strutting arrangement 1, user's accessible external control device starts two sets of connection motors 31 afterwards, connect motor 31 this moment and can drive squeeze roll 35 and rotate, because the meshing rotation connection is carried out through connecting gear 33 between two sets of upper and lower squeeze roll 35, and then can make relative rotation between two sets of upper and lower squeeze roll 35, and when two sets of upper and lower squeeze roll 35 rotated, granulation cutter 34 did not take place spacing and contact, prevent that follow-up spacing from taking place to influence the granulation operation, have the space between two sets of squeeze roll 35 and the granulation cutter 34 in strutting arrangement 1 inside, the raw materials that drop from the bottom of unloading box 21 can just be positioned between the space, two sets of relative squeeze roll 35 can carry out abundant granulation crushing to high carbon ferromanganese raw materials through granulation cutter 34 at this moment, the raw materials after smashing fall to the upper portion of screening baffle 7, screening baffle 7 can be to the raw materials and then sieve many times to improve the homogeneity of high carbon ferromanganese granulation, and then improved the efficiency of processing the raw materials.

Example 2:

as shown in fig. 3, as a further optimization scheme of the above embodiment: a granulating device for producing high-carbon ferromanganese from manganese metal comprises a supporting device 1, a blanking device 2, a granulating device 3, a servo motor 4, a bidirectional screw rod 5, a toothed belt 6, a screening baffle 7 and toothed belt wheels 8, wherein the blanking device 2 for guiding material is symmetrically and fixedly connected to the upper end face of the supporting device 1, two groups of mounting clamping plates are symmetrically and fixedly connected to the side end face of the supporting device 1, the bidirectional screw rod 5 is rotatably clamped in the mounting clamping plates, the toothed belt wheels 8 are fixedly connected to the end heads of the side end faces of the bidirectional screw rod 5, the two groups of toothed belt wheels 8 are meshed and rotatably connected through the toothed belt 6, the servo motor 4 is fixedly connected to the position deviating from the toothed belt wheels 8 on the side end face of the bidirectional screw rod 5, the inner end face of the supporting device 1 is slidably connected with the granulating device 3 through the symmetrical threads of the bidirectional screw rod 5, and a screening baffle 7 is fixedly connected to the bottom end surface of the supporting device 1. The supporting device 1 comprises a limiting clamping groove 11, a supporting baffle 12, a fixed shell 13, a positioning chute 14 and a clamping chute 15, the supporting baffle 12 is fixedly connected to the center of the upper end face of the fixed shell 13, the limiting clamping groove 11 is symmetrically arranged on the upper end face of the supporting baffle 12, the clamping chute 15 is symmetrically arranged on the side end face of the fixed shell 13, the positioning chute 14 is arranged on the side end face of the fixed shell 13 close to the clamping chute 15, if the size of the high-carbon ferromanganese granulation needs to be adaptively adjusted, a user can start the servo motor 4 through an external control device, the servo motor 4 can drive the front bidirectional screw rod 5 to rotate, and meanwhile, when the bidirectional screw rod 5 rotates, the bidirectional screw rod 5 can drive the front toothed belt wheel 8 to rotate, so that the two groups of toothed belt wheels 8 can simultaneously rotate through the toothed belt 6, and then make the two-way lead screw 5 synchronous rotation of strutting arrangement 1 both sides, two-way lead screw 5 can drive two sets of prilling granulator 3 of strutting arrangement 1 inside simultaneously through threaded sleeve 32 and carry out synchronous centripetal or centrifugal displacement when rotating for the distance between two sets of relative granulation cutters 34 becomes effective or grow, thereby can conveniently carry out the granulation operation of equidimension to high carbon ferromanganese.

Example 3:

as shown in fig. 4, as a further optimization scheme of the above embodiment: a granulating device for producing high-carbon ferromanganese from manganese metal comprises a supporting device 1, a blanking device 2, a granulating device 3, a servo motor 4, a bidirectional screw rod 5, a toothed belt 6, a screening baffle 7 and toothed belt wheels 8, wherein the blanking device 2 for guiding material is symmetrically and fixedly connected to the upper end face of the supporting device 1, two groups of mounting clamping plates are symmetrically and fixedly connected to the side end face of the supporting device 1, the bidirectional screw rod 5 is rotatably clamped in the mounting clamping plates, the toothed belt wheels 8 are fixedly connected to the end heads of the side end faces of the bidirectional screw rod 5, the two groups of toothed belt wheels 8 are meshed and rotatably connected through the toothed belt 6, the servo motor 4 is fixedly connected to the position deviating from the toothed belt wheels 8 on the side end face of the bidirectional screw rod 5, the inner end face of the supporting device 1 is slidably connected with the granulating device 3 through the symmetrical threads of the bidirectional screw rod 5, and a screening baffle 7 is fixedly connected to the bottom end surface of the supporting device 1. Support arrangement 1 includes spacing draw-in groove 11, supporting baffle 12, fixed casing 13, location spout 14 and joint spout 15, fixed casing 13's up end center department fixedly connected with supporting baffle 12, and be located spacing draw-in groove 11 has been seted up to supporting baffle 12's up end symmetry, joint spout 15 has been seted up to fixed casing 13's side end plane symmetry, and is located fixed casing 13's side end face is close to joint spout 15 department and has seted up location spout 14. Unloader 2 includes unloading box 21, spiral unloading board 22, fixed pulley 23 and installation baffle 24, the up end center department fixedly connected with installation baffle 24 of unloading box 21, and is located the lower terminal surface of installation baffle 24 rotates the joint and has spiral unloading board 22, the up end of installation baffle 24 just rotates the joint to spiral unloading board 22 department and has fixed pulley 23, when leading to the raw materials, spiral unloading board 22 can rotate under fixed pulley 23's drive, and spiral unloading board 22 can compress the high-carbon ferromanganese raw materials simultaneously and carry to make high-carbon ferromanganese raw materials pressfitting on the upper portion of squeeze roll 35, improve the efficiency to the high-carbon ferromanganese granulation.

Example 4:

as shown in fig. 5-6, as a further optimization of the above embodiment: a granulating device for producing high-carbon ferromanganese from manganese metal comprises a supporting device 1, a blanking device 2, a granulating device 3, a servo motor 4, a bidirectional screw rod 5, a toothed belt 6, a screening baffle 7 and toothed belt wheels 8, wherein the blanking device 2 for guiding material is symmetrically and fixedly connected to the upper end face of the supporting device 1, two groups of mounting clamping plates are symmetrically and fixedly connected to the side end face of the supporting device 1, the bidirectional screw rod 5 is rotatably clamped in the mounting clamping plates, the toothed belt wheels 8 are fixedly connected to the end heads of the side end faces of the bidirectional screw rod 5, the two groups of toothed belt wheels 8 are meshed and rotatably connected through the toothed belt 6, the servo motor 4 is fixedly connected to the position deviating from the toothed belt wheels 8 on the side end face of the bidirectional screw rod 5, the inner end face of the supporting device 1 is slidably connected with the granulating device 3 through the symmetrical threads of the bidirectional screw rod 5, and a screening baffle 7 is fixedly connected to the bottom end surface of the supporting device 1. Support arrangement 1 includes spacing draw-in groove 11, supporting baffle 12, fixed casing 13, location spout 14 and joint spout 15, fixed casing 13's up end center department fixedly connected with supporting baffle 12, and be located spacing draw-in groove 11 has been seted up to supporting baffle 12's up end symmetry, joint spout 15 has been seted up to fixed casing 13's side end plane symmetry, and is located fixed casing 13's side end face is close to joint spout 15 department and has seted up location spout 14. Unloader 2 includes unloading box 21, spiral unloading board 22, fixed pulley 23 and installation baffle 24, the up end center fixedly connected with installation baffle 24 of unloading box 21, and is located the lower terminal surface of installation baffle 24 rotates the joint and has spiral unloading board 22, the up end of installation baffle 24 just to spiral unloading board 22 department rotate the joint and have fixed pulley 23. The granulating device 3 comprises a connecting motor 31, a threaded sleeve 32, a connecting gear 33, a granulating cutter 34, an extrusion roller 35 and a blanking guide plate 36, the threaded sleeve 32 is symmetrically and fixedly connected with the side end surface of the blanking guide plate 36, and the inner end surface of the blanking guide plate 36 is symmetrically and rotatably clamped with an extrusion roller 35, the side end surface of the extrusion roller 35 is symmetrically and fixedly connected with a connecting gear 33, and the outer end surface of the extrusion roller 35 is uniformly and fixedly connected with granulation cutters 34 at equal intervals, the extrusion roller 35 at the upper part of the side end surface of the blanking guide plate 36 is fixedly connected with a connecting motor 31, during processing, the connecting motor 31 can drive the upper and lower two groups of squeezing rollers 35 to rotate relatively through the connecting gear 33, so that the four squeezing rollers 35 can rotate relatively in pairs, thereby furthest improving the granulation efficiency of the device and simultaneously improving the utilization efficiency of the device to power.

Example 5:

as shown in fig. 3-5, as a further optimization of the above embodiment: a granulating device for producing high-carbon ferromanganese from manganese metal comprises a supporting device 1, a blanking device 2, a granulating device 3, a servo motor 4, a bidirectional screw rod 5, a toothed belt 6, a screening baffle 7 and toothed belt wheels 8, wherein the blanking device 2 for guiding material is symmetrically and fixedly connected to the upper end face of the supporting device 1, two groups of mounting clamping plates are symmetrically and fixedly connected to the side end face of the supporting device 1, the bidirectional screw rod 5 is rotatably clamped in the mounting clamping plates, the toothed belt wheels 8 are fixedly connected to the end heads of the side end faces of the bidirectional screw rod 5, the two groups of toothed belt wheels 8 are meshed and rotatably connected through the toothed belt 6, the servo motor 4 is fixedly connected to the position deviating from the toothed belt wheels 8 on the side end face of the bidirectional screw rod 5, the inner end face of the supporting device 1 is slidably connected with the granulating device 3 through the symmetrical threads of the bidirectional screw rod 5, and a screening baffle 7 is fixedly connected to the bottom end surface of the supporting device 1. Support arrangement 1 includes spacing draw-in groove 11, supporting baffle 12, fixed casing 13, location spout 14 and joint spout 15, fixed casing 13's up end center department fixedly connected with supporting baffle 12, and be located spacing draw-in groove 11 has been seted up to supporting baffle 12's up end symmetry, joint spout 15 has been seted up to fixed casing 13's side end plane symmetry, and is located fixed casing 13's side end face is close to joint spout 15 department and has seted up location spout 14. Unloader 2 includes unloading box 21, spiral unloading board 22, fixed pulley 23 and installation baffle 24, the up end center fixedly connected with installation baffle 24 of unloading box 21, and is located the lower terminal surface of installation baffle 24 rotates the joint and has spiral unloading board 22, the up end of installation baffle 24 just to spiral unloading board 22 department rotate the joint and have fixed pulley 23. Prilling granulator 3 is including connecting motor 31, threaded sleeve 32, connecting gear 33, granulation cutter 34, squeeze roll 35 and unloading baffle 36, the side end face symmetry fixedly connected with threaded sleeve 32 of unloading baffle 36, and is located the interior end face symmetry of unloading baffle 36 rotates the joint and has squeeze roll 35, the side end face symmetry fixedly connected with connecting gear 33 of squeeze roll 35, and is located the even equidistance fixedly connected with granulation cutter 34 of the outer end face of squeeze roll 35, the side end face of unloading baffle 36 is just to the squeeze roll 35 fixedly connected with connecting motor 31 on upper portion. Threaded groove has been seted up to the outer terminal surface of threaded sleeve 32, prilling granulator 3 passes through threaded

sleeve

32 and 14 looks adaptations of location spout and then the slip joint at the inner terminal surface of fixed casing 13, and location spout 14 can provide sufficient direction basis for two sets of prilling granulator 3, makes things convenient for follow-up prilling granulator 3 to carry out rapid and stable direction, improves the stability of direction.

Example 6:

as shown in fig. 4-6, as a further optimization of the above embodiment: a granulating device for producing high-carbon ferromanganese from manganese metal comprises a supporting device 1, a blanking device 2, a granulating device 3, a servo motor 4, a bidirectional screw rod 5, a toothed belt 6, a screening baffle 7 and toothed belt wheels 8, wherein the blanking device 2 for guiding material is symmetrically and fixedly connected to the upper end face of the supporting device 1, two groups of mounting clamping plates are symmetrically and fixedly connected to the side end face of the supporting device 1, the bidirectional screw rod 5 is rotatably clamped in the mounting clamping plates, the toothed belt wheels 8 are fixedly connected to the end heads of the side end faces of the bidirectional screw rod 5, the two groups of toothed belt wheels 8 are meshed and rotatably connected through the toothed belt 6, the servo motor 4 is fixedly connected to the position deviating from the toothed belt wheels 8 on the side end face of the bidirectional screw rod 5, the inner end face of the supporting device 1 is slidably connected with the granulating device 3 through the symmetrical threads of the bidirectional screw rod 5, and a screening baffle 7 is fixedly connected to the bottom end surface of the supporting device 1. Support arrangement 1 includes spacing draw-in groove 11, supporting baffle 12, fixed casing 13, location spout 14 and joint spout 15, fixed casing 13's up end center department fixedly connected with supporting baffle 12, and be located spacing draw-in groove 11 has been seted up to supporting baffle 12's up end symmetry, joint spout 15 has been seted up to fixed casing 13's side end plane symmetry, and is located fixed casing 13's side end face is close to joint spout 15 department and has seted up location spout 14. Unloader 2 includes unloading box 21, spiral unloading board 22, fixed pulley 23 and installation baffle 24, the up end center fixedly connected with installation baffle 24 of unloading box 21, and is located the lower terminal surface of installation baffle 24 rotates the joint and has spiral unloading board 22, the up end of installation baffle 24 just to spiral unloading board 22 department rotate the joint and have fixed pulley 23. Prilling granulator 3 is including connecting motor 31, threaded sleeve 32, connecting gear 33, granulation cutter 34, squeeze roll 35 and unloading baffle 36, the side end face symmetry fixedly connected with threaded sleeve 32 of unloading baffle 36, and is located the interior end face symmetry of unloading baffle 36 rotates the joint and has squeeze roll 35, the side end face symmetry fixedly connected with connecting gear 33 of squeeze roll 35, and is located the even equidistance fixedly connected with granulation cutter 34 of the outer end face of squeeze roll 35, the side end face of unloading baffle 36 is just to the squeeze roll 35 fixedly connected with connecting motor 31 on upper portion. The outer end surface of the threaded sleeve 32 is provided with a threaded groove, and the granulating device 3 is matched with the positioning chute 14 through the threaded sleeve 32 and then is slidably clamped on the inner end surface of the fixed shell 13. Thread groove and two-way lead screw 5 carry out threaded connection, just prilling granulator 3 is through thread groove and 5 looks adaptations of two-way lead screw and then screw thread sliding connection at strutting arrangement 1's outer terminal surface, and the threaded connection of thread groove and two-way lead screw 5 can effectively improve driven stability between the device, and threaded connection can effectively improve the accurate nature of regulation simultaneously.

Example 7:

as shown in fig. 2-5, as a further optimization of the above embodiment: a granulating device for producing high-carbon ferromanganese from manganese metal comprises a supporting device 1, a blanking device 2, a granulating device 3, a servo motor 4, a bidirectional screw rod 5, a toothed belt 6, a screening baffle 7 and toothed belt wheels 8, wherein the blanking device 2 for guiding material is symmetrically and fixedly connected to the upper end face of the supporting device 1, two groups of mounting clamping plates are symmetrically and fixedly connected to the side end face of the supporting device 1, the bidirectional screw rod 5 is rotatably clamped in the mounting clamping plates, the toothed belt wheels 8 are fixedly connected to the end heads of the side end faces of the bidirectional screw rod 5, the two groups of toothed belt wheels 8 are meshed and rotatably connected through the toothed belt 6, the servo motor 4 is fixedly connected to the position deviating from the toothed belt wheels 8 on the side end face of the bidirectional screw rod 5, the inner end face of the supporting device 1 is slidably connected with the granulating device 3 through the symmetrical threads of the bidirectional screw rod 5, and a screening baffle 7 is fixedly connected to the bottom end surface of the supporting device 1. Support arrangement 1 includes spacing draw-in groove 11, supporting baffle 12, fixed casing 13, location spout 14 and joint spout 15, fixed casing 13's up end center department fixedly connected with supporting baffle 12, and be located spacing draw-in groove 11 has been seted up to supporting baffle 12's up end symmetry, joint spout 15 has been seted up to fixed casing 13's side end plane symmetry, and is located fixed casing 13's side end face is close to joint spout 15 department and has seted up location spout 14. Unloader 2 includes unloading box 21, spiral unloading board 22, fixed pulley 23 and installation baffle 24, the up end center fixedly connected with installation baffle 24 of unloading box 21, and is located the lower terminal surface of installation baffle 24 rotates the joint and has spiral unloading board 22, the up end of installation baffle 24 just to spiral unloading board 22 department rotate the joint and have fixed pulley 23. Prilling granulator 3 is including connecting motor 31, threaded sleeve 32, connecting gear 33, granulation cutter 34, squeeze roll 35 and unloading baffle 36, the side end face symmetry fixedly connected with threaded sleeve 32 of unloading baffle 36, and is located the interior end face symmetry of unloading baffle 36 rotates the joint and has squeeze roll 35, the side end face symmetry fixedly connected with connecting gear 33 of squeeze roll 35, and is located the even equidistance fixedly connected with granulation cutter 34 of the outer end face of squeeze roll 35, the side end face of unloading baffle 36 is just to the squeeze roll 35 fixedly connected with connecting motor 31 on upper portion. The outer end surface of the threaded sleeve 32 is provided with a threaded groove, and the granulating device 3 is matched with the positioning chute 14 through the threaded sleeve 32 and then is slidably clamped on the inner end surface of the fixed shell 13. The thread groove is in threaded connection with the bidirectional screw rod 5, and the granulating device 3 is matched with the bidirectional screw rod 5 through the thread groove and then is in threaded sliding connection with the outer end face of the supporting device 1. Carry out meshing rotation through connecting gear 33 between the upper and lower two sets of squeeze rolls 35 and connect, flitch 22's outward flange and the inner wall of unloading box 21 are laminated down in the spiral and are connected, and flitch 22 is big-end-up down in the spiral, and flitch 22 outside and unloading box 21 laminating down in the spiral simultaneously for the raw materials of carrying can extrude, convenient follow-up granulation operation that carries on.

Example 8:

as shown in fig. 2-6, as a further optimization of the above embodiment: a granulating device for producing high-carbon ferromanganese from manganese metal comprises a supporting device 1, a blanking device 2, a granulating device 3, a servo motor 4, a bidirectional screw rod 5, a toothed belt 6, a screening baffle 7 and toothed belt wheels 8, wherein the blanking device 2 for guiding material is symmetrically and fixedly connected to the upper end face of the supporting device 1, two groups of mounting clamping plates are symmetrically and fixedly connected to the side end face of the supporting device 1, the bidirectional screw rod 5 is rotatably clamped in the mounting clamping plates, the toothed belt wheels 8 are fixedly connected to the end heads of the side end faces of the bidirectional screw rod 5, the two groups of toothed belt wheels 8 are meshed and rotatably connected through the toothed belt 6, the servo motor 4 is fixedly connected to the position deviating from the toothed belt wheels 8 on the side end face of the bidirectional screw rod 5, the inner end face of the supporting device 1 is slidably connected with the granulating device 3 through the symmetrical threads of the bidirectional screw rod 5, and a screening baffle 7 is fixedly connected to the bottom end surface of the supporting device 1. Support arrangement 1 includes spacing draw-in groove 11, supporting baffle 12, fixed casing 13, location spout 14 and joint spout 15, fixed casing 13's up end center department fixedly connected with supporting baffle 12, and be located spacing draw-in groove 11 has been seted up to supporting baffle 12's up end symmetry, joint spout 15 has been seted up to fixed casing 13's side end plane symmetry, and is located fixed casing 13's side end face is close to joint spout 15 department and has seted up location spout 14. Unloader 2 includes unloading box 21, spiral unloading board 22, fixed pulley 23 and installation baffle 24, the up end center fixedly connected with installation baffle 24 of unloading box 21, and is located the lower terminal surface of installation baffle 24 rotates the joint and has spiral unloading board 22, the up end of installation baffle 24 just to spiral unloading board 22 department rotate the joint and have fixed pulley 23. Prilling granulator 3 is including connecting motor 31, threaded sleeve 32, connecting gear 33, granulation cutter 34, squeeze roll 35 and unloading baffle 36, the side end face symmetry fixedly connected with threaded sleeve 32 of unloading baffle 36, and is located the interior end face symmetry of unloading baffle 36 rotates the joint and has squeeze roll 35, the side end face symmetry fixedly connected with connecting gear 33 of squeeze roll 35, and is located the even equidistance fixedly connected with granulation cutter 34 of the outer end face of squeeze roll 35, the side end face of unloading baffle 36 is just to the squeeze roll 35 fixedly connected with connecting motor 31 on upper portion. The outer end surface of the threaded sleeve 32 is provided with a threaded groove, and the granulating device 3 is matched with the positioning chute 14 through the threaded sleeve 32 and then is slidably clamped on the inner end surface of the fixed shell 13. The thread groove is in threaded connection with the bidirectional screw rod 5, and the granulating device 3 is matched with the bidirectional screw rod 5 through the thread groove and then is in threaded sliding connection with the outer end face of the supporting device 1. The upper and lower two groups of squeezing rollers 35 are connected in a meshing rotation mode through a connecting gear 33, and the outer edge of the spiral blanking plate 22 is attached to the inner wall of the blanking box body 21. Screening baffle 7 filters cardboard and the guide cylinder of fixed connection in filtering the cardboard bottom including the spacing frame that is used for supporting, even equidistance fixing clip joint in four groups of spacing frame inside, and spacing frame is inside to be equipped with four groups and to filter cardboard and four groups guide cylinder, and spacing frame can shunt the raw materials that the granulation was accomplished to follow-up filtration cardboard of improvement of at utmost sieves the degree of consistency of selecting to the raw materials that the granulation was accomplished.

The working principle of the utility model is as follows: if the high-carbon ferromanganese raw material is required to be granulated, a user can position an external high-carbon ferromanganese feeding device to the upper parts of the two groups of blanking devices 2, then connect the external connecting belt with the outside of the fixed belt pulley 23, so as to conveniently and subsequently transmit power to the blanking devices 2 and further conveniently carry out granulation operation on the high-carbon ferromanganese raw material, when granulation is carried out, the external feeding device can convey the raw material to the inside of the blanking box body 21, at the moment, the two groups of fixed belt pulleys 23 can drive the spiral blanking plate 22 at the bottom to rotate due to the meshed connection of the fixed belt pulley 23 and the external connecting belt, and simultaneously, when the spiral blanking plate 22 rotates, the spiral blanking plate 22 can carry out spiral guiding and pressing on high-carbon ferromanganese raw materials with different sizes due to the spiral arrangement of the spiral blanking plate 22, so that the raw material is guided to the inside of the supporting device 1 from the bottom of the blanking device 2, then, a user can start the two groups of connecting motors 31 through an external control device, at the moment, the connecting motors 31 can drive the squeeze rollers 35 to rotate, because the upper and lower groups of squeeze rollers 35 are meshed through the connecting gears 33 and rotate to be connected, so that the upper and lower groups of squeeze rollers 35 can rotate relatively, when the upper and lower groups of squeeze rollers 35 rotate, the granulation cutters 34 do not limit and contact, the subsequent limitation is prevented from influencing the granulation operation, a gap is formed between the two groups of squeeze rollers 35 and the granulation cutters 34 in the supporting device 1, the raw material falling from the bottom of the blanking box body 21 can be just positioned between the gaps, at the moment, the two groups of opposite squeeze rollers 35 can fully granulate and crush the high-carbon ferromanganese raw material through the granulation cutters 34, the crushed raw material falls to the upper part of the screening baffle 7, the screening baffle 7 can screen the raw material for multiple times, and the uniformity of the high-carbon ferromanganese granulation is improved, further improving the efficiency of processing the raw materials, if the size of the high-carbon ferromanganese granulation needs to be adaptively adjusted, a user can start the servo motor 4 through an external control device, at the moment, the servo motor 4 can drive the front bidirectional screw rod 5 to rotate, meanwhile, when the bidirectional screw rod 5 rotates, the bidirectional screw rod 5 can drive the front toothed belt wheel 8 to rotate, so that the two groups of toothed belt wheels 8 can rotate simultaneously through the toothed belt 6, thereby leading the bidirectional screw rods 5 at the two sides of the supporting device 1 to synchronously rotate, when the bidirectional screw rods 5 rotate, can simultaneously drive the two groups of granulating devices 3 in the supporting device 1 to synchronously move centripetally or centrifugally through the threaded sleeve 32, the distance between the two sets of opposite granulating cutters 34 is changed or enlarged, so that the granulating operation of the high-carbon ferromanganese can be conveniently carried out in different sizes.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. The principles and embodiments of the present invention are explained herein using specific examples, which are presented only to assist in understanding the method and its core concepts of the present invention. The foregoing is only a preferred embodiment of the present invention, and it should be noted that there are objectively infinite specific structures due to the limited character expressions, and it will be apparent to those skilled in the art that a plurality of modifications, decorations or changes may be made without departing from the principle of the present invention, and the above technical features may be combined in a suitable manner; such modifications, variations, combinations, or adaptations of the utility model using its spirit and scope, as defined by the claims, may be directed to other uses and embodiments.

Claims

1. The granulating equipment for producing high-carbon ferromanganese from manganese metal is characterized in that: the automatic granulating device comprises a supporting device (1), a blanking device (2), a granulating device (3), a servo motor (4), a bidirectional screw rod (5), a toothed belt (6), a screening baffle plate (7) and toothed belt wheels (8), wherein the blanking device (2) for guiding materials is symmetrically and fixedly connected to the upper end face of the supporting device (1), two groups of mounting clamping plates are symmetrically and fixedly connected to the side end face of the supporting device (1), the bidirectional screw rod (5) is rotatably clamped inside the mounting clamping plates, the toothed belt wheels (8) are fixedly connected to the end faces of the side end faces of the bidirectional screw rod (5), the two groups of toothed belt wheels (8) are meshed and rotatably connected through the toothed belt (6), the servo motor (4) is fixedly connected to the end faces of the side end faces of the bidirectional screw rod (5), the inner end face of the supporting device (1) is slidably connected with the granulating device (3) through symmetrical threads of the bidirectional screw rod (5), and a screening baffle (7) is fixedly connected to the bottom end surface of the supporting device (1).

2. The granulation equipment for producing high-carbon ferromanganese from manganese metal as claimed in claim 1, wherein: strutting arrangement (1) is including spacing draw-in groove (11), supporting baffle (12), set casing (13), location spout (14) and joint spout (15), the up end center fixedly connected with supporting baffle (12) of set casing (13) department, and be located spacing draw-in groove (11) have been seted up to the up end symmetry of supporting baffle (12), joint spout (15) have been seted up to the side end symmetry of set casing (13), and are located the side end of set casing (13) is close to joint spout (15) department and has seted up location spout (14).

3. The granulation equipment for producing high-carbon ferromanganese from manganese metal as claimed in claim 2, wherein: unloader (2) are including unloading box (21), spiral flitch (22), fixed pulley (23) and installation baffle (24) down, fixedly connected with installation baffle (24) are located at the up end center of unloading box (21), and are located the lower terminal surface of installation baffle (24) rotates the joint and has spiral flitch (22) down, the up end of installation baffle (24) just to spiral flitch (22) department rotation joint have fixed pulley (23) down.

4. The granulation equipment for producing high-carbon ferromanganese from manganese metal as claimed in claim 3, wherein: prilling granulator (3) are including connecting motor (31), threaded sleeve (32), connecting gear (33), granulation cutter (34), squeeze roll (35) and unloading baffle (36), the side end symmetry fixedly connected with threaded sleeve (32) of unloading baffle (36), and be located the interior terminal surface symmetry of unloading baffle (36) rotates the joint and has squeeze roll (35), the side end symmetry fixedly connected with connecting gear (33) of squeeze roll (35), and be located the even equidistance fixedly connected with granulation cutter (34) of the outer terminal surface of squeeze roll (35), the side end of unloading baffle (36) is just locating fixedly connected with connecting motor (31) to squeeze roll (35) on upper portion.

5. The granulation equipment for producing high-carbon ferromanganese from manganese metal as claimed in claim 4, wherein: the outer end face of the threaded sleeve (32) is provided with a threaded groove, and the granulating device (3) is matched with the positioning chute (14) through the threaded sleeve (32) and then is in sliding clamping connection with the inner end face of the fixed shell (13).

6. The granulation equipment for producing high-carbon ferromanganese from manganese metal as claimed in claim 5, wherein: the thread groove is in threaded connection with the bidirectional screw rod (5), and the granulating device (3) is matched with the bidirectional screw rod (5) through the thread groove and then is in threaded sliding connection with the outer end face of the supporting device (1).

7. The granulation equipment for producing high-carbon ferromanganese from manganese metal as claimed in claim 6, wherein: the upper and lower two groups of extrusion rollers (35) are connected in a meshing rotation mode through a connecting gear (33), and the outer edge of the spiral blanking plate (22) is attached to the inner wall of the blanking box body (21).

8. The granulation facility for producing high-carbon ferromanganese from manganese metal as claimed in claim 7, wherein: the screening baffle (7) comprises a limiting frame for supporting, four groups of filtering clamping plates which are fixedly clamped inside the limiting frame at equal intervals and a guide cylinder which is fixedly connected to the bottom of the filtering clamping plates.