CN117839473A - Furnace burden mixer for ferromolybdenum smelting - Google Patents

Abstract

The invention relates to the technical field of mixing, and discloses a charge mixer for ferromolybdenum smelting, which comprises a mixing box, wherein supporting sleeves are respectively and fixedly arranged at the centers of two ends of the mixing box, supporting frames are respectively and fixedly arranged at the bottoms of two ends of the mixing box, first shaft sleeves are respectively and rotatably arranged in the supporting sleeves, first spiral sheets are fixedly arranged between the first shaft sleeves through supporting rods, second shaft sleeves are respectively and rotatably arranged in the first shaft sleeves, a roller is fixedly arranged between the second shaft sleeves, second spiral sheets are fixedly arranged on the circumferential sides of the roller, a central shaft is fixedly arranged between the supporting frames, and the central shaft is rotatably assembled in the second shaft sleeves; a transmission component is arranged between the central shaft and the roller, and an agitating piece is arranged on the transmission component. In order to solve the problem of poor mixing effect, the invention changes the shape of the mixing cavity and increases the action area of the furnace burden, the first spiral slice and the second spiral slice; the rotating stirring piece can stir and disturb the circularly conveyed furnace burden so as to improve the mixing effect.

Description

Furnace burden mixer for ferromolybdenum smelting

Technical Field

The invention relates to the technical field of mixing, in particular to a furnace burden mixer for ferromolybdenum smelting.

Background

The ferromolybdenum smelting is carried out by adopting an aluminothermic reduction method, is an automatic reaction, and does not need to add substances such as fuel and the like; the furnace burden is required to be stored separately, aluminum particles, a heating agent and oxide powder cannot be stacked together for storage, and the mixed smelting furnace burden is required to be smelted immediately.

The prepared raw materials enter a bin of a smelting workshop for standby through a conveyor, a batching process is carried out in an automatic batching machine, the batching machine accurately measures and displays the weight according to the process requirement, then the raw materials are input into a mixer for mixing according to the process requirement sequence, and various raw materials (mainly 6 kinds of industrial molybdenum oxide, ferrosilicon powder, aluminum powder, sodium nitrate, iron ore powder and steel scraps) are required to be fully mixed when the burden is mixed so as to ensure the quality of a ferromolybdenum finished product.

The blendor that uses at present mainly comprises mixing box, speed reducer group and double screw piece, and speed reducer group can drive inside and outside integrative double screw piece synchronous rotation, because of the spiral direction difference of screw piece to can carry the furnace charge that is close to mixing box center department to one side, the furnace charge that is close to mixing box lateral wall carries to the opposite side, forms after the circulation transport, in order to reach the abundant effect of mixing, but the mixing chamber volume in the mixing box is great, and the effective action face of screw piece is less again, leads to mixing time longer, influences production efficiency.

Therefore, in order to improve the mixing effect, a charge mixer for ferromolybdenum smelting is provided.

Disclosure of Invention

The invention aims to provide a burden mixer for ferromolybdenum smelting, which solves the problems in the background technology by improving the burden mixing effect.

In order to achieve the above purpose, the present invention provides the following technical solutions:

the furnace burden mixer for ferromolybdenum smelting comprises a mixing box, wherein supporting sleeves are respectively and fixedly arranged at the centers of two ends of the mixing box, supporting frames are respectively and fixedly arranged at the bottoms of two ends of the mixing box, first shaft sleeves are respectively and rotatably arranged in the supporting sleeves, first spiral sheets are fixedly arranged between the first shaft sleeves through supporting rods, the bottoms of the inner sides of the mixing box are abutted against the first spiral sheets, second shaft sleeves are respectively and rotatably arranged in the first shaft sleeves, a roller is fixedly arranged between the second shaft sleeves, second spiral sheets are fixedly arranged at the circumference sides of the roller, a central shaft is fixedly arranged between the supporting frames, and the central shaft is rotatably assembled in the second shaft sleeves and penetrates through the roller; a transmission assembly is arranged between the central shaft and the roller, a stirring piece is arranged on the transmission assembly, the stirring piece is positioned on the inner side of the first spiral sheet, and the stirring piece and the second spiral sheet are arranged in a staggered manner; the support frames are provided with driving assemblies, and the driving assemblies are used for rotating the second shaft sleeve and the first shaft sleeve; and a discharging component is arranged at the lower side of the mixing box.

Specifically, the transmission assembly includes transfer line, second bevel gear and first bevel gear, the even fixed mounting of center pin has first bevel gear, the rotary drum is evenly installed to the circumference side of cylinder, the transfer line is installed to the rotary drum internal rotation, the one end fixed mounting of transfer line has the second bevel gear, second bevel gear and first bevel gear meshing assembly, the other end and the stirring piece fixed mounting of transfer line.

Specifically, the support sleeve is all stretched out at the both ends of first axle sleeve, the both ends of center pin all stretch out first axle sleeve.

Specifically, the central shaft and the second shaft sleeve, the second shaft sleeve and the first shaft sleeve, and the first shaft sleeve and the supporting sleeve are all assembled in a rotating way through bearings.

Specifically, the drive assembly includes gear motor, drive straight-tooth wheel and driven straight-tooth wheel, equal fixed mounting of support frame has gear motor, equal fixed mounting of gear motor's output has drive straight-tooth wheel, the one end or both ends of second axle sleeve one end or both ends of first axle sleeve are equal fixed mounting have driven straight-tooth wheel, drive straight-tooth wheel and driven straight-tooth wheel meshing assembly.

Specifically, the bearing seat is fixedly arranged on the upper surface of the support frame, and the output end of the speed reducing motor is rotationally assembled with the bearing seat.

Specifically, the discharging component comprises a material plate and a pushing cylinder, two material plates which are arranged in a split mode are hinged to the bottom of the mixing box, the pushing cylinder is arranged below the material plate, a first supporting seat is rotatably assembled at the cylinder body end of the pushing cylinder, a second supporting seat is rotatably assembled at the push rod end of the pushing cylinder, and the upper end of the second supporting seat is fixedly assembled with the material plate.

Specifically, the material plates are provided with the engagement grooves on one side close to each other, and the engagement grooves on two sides are arranged in a vertically staggered mode.

Specifically, the furnace burden conveying directions of the first spiral slice and the second spiral slice are opposite.

Specifically, the stirring piece is a straight plate or a spiral fan blade.

Advantageous effects

Through the arrangement of the roller, the shape of the mixing cavity can be changed, so that no furnace burden exists at the center of the mixing box, the acting area of the furnace burden, the first spiral slice and the second spiral slice is increased, and the mixing effect of cyclic conveying of the furnace burden is better;

the stirring device comprises a central shaft, a transmission assembly, a stirring piece and other structures, wherein the stirring piece can be rotated after being transmitted by the transmission assembly when the roller drives the second spiral piece to rotate, so that stirring and stirring are carried out on circularly conveyed furnace burden, and the mixing effect is further improved;

the driving component which is flexibly arranged can ensure the power demand of the rotation of the first shaft sleeve and the second shaft sleeve, and the discharging component has good tightness during mixing and is thoroughly discharged during discharging.

Drawings

FIG. 1 is a schematic front view of the structure of the present invention;

FIG. 2 is a schematic cross-sectional view of the structure of the present invention;

FIG. 3 is a schematic perspective view of the structure at the drum of the present invention;

FIG. 4 is a schematic cross-sectional view of the structure at the drive assembly of the present invention;

FIG. 5 is a schematic cross-sectional view of the structure at the transmission assembly of the present invention;

FIG. 6 is a schematic cross-sectional view of the structure in the direction A-A of FIG. 1;

fig. 7 is a schematic enlarged view of the structure at the engagement groove of the present invention.

In the figure: the device comprises a mixing box 1, a first spiral sheet 2, a central shaft 3, a roller 4, a second spiral sheet 5, a transmission component 6, a transmission rod 61, a second bevel gear 62, a first bevel gear 63, a discharging component 7, a material plate 71, a pushing cylinder 72, a driving component 8, a bearing seat 81, a speed reducing motor 82, a driving spur gear 83, a driven spur gear 84, a first shaft sleeve 9, a supporting sleeve 10, a second shaft sleeve 11, a stirring piece 12 and a supporting frame 13.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Examples

As shown in fig. 1, the invention provides a charge mixer for ferromolybdenum smelting, which comprises a mixing box 1, wherein the mixing box 1 is a rectangular box body with an upper opening, and the bottom of the mixing box is arc-shaped; the centers of the two ends of the mixing box 1 are respectively and fixedly provided with a supporting sleeve 10, the bottoms of the two ends of the mixing box 1 are respectively and fixedly provided with a supporting frame 13, the interiors of the supporting sleeves 10 are respectively and rotatably provided with a first shaft sleeve 9, first screw plates 2 are fixedly arranged between the first shaft sleeves 9 through supporting rods, the bottoms of the interiors of the mixing box 1 are propped against the first screw plates 2, the interiors of the first shaft sleeves 9 are respectively and rotatably provided with a second shaft sleeve 11, a roller 4 is fixedly arranged between the second shaft sleeves 11, the circumference sides of the roller 4 are fixedly provided with a second screw plate 5, a central shaft 3 is fixedly arranged between the supporting frames 13, and the central shaft 3 is rotatably assembled in the second shaft sleeves 11 and penetrates through the roller 4; the central shaft 3 plays a supporting role, the rotating second shaft sleeve 11 can synchronously drive the roller 4 and the second spiral piece 5 to rotate so as to convey the burden close to the roller 4, and the rotating first shaft sleeve 9 can drive the first spiral piece 2 to rotate so as to convey the burden close to the mixing box 1.

The arrangement of the roller 4 can occupy the space in the center of the mixing box 1, so that a cylindrical-like mixing cavity is formed between the mixing box 1 and the roller 4, and the contact efficiency of the first spiral slice 2 and the second spiral slice 5 with the furnace burden is increased.

The direction of charge transport of the first flight 2 and the second flight 5 are opposite, and two modes are realized:

one is that the spiral directions of the first spiral sheet 2 and the second spiral sheet 5 are the same but the rotation directions are opposite, and the other is that the spiral directions of the first spiral sheet 2 and the second spiral sheet 5 are opposite but the rotation directions are the same as shown in figure 3, so that the effect of opposite conveying directions of furnace burden can be achieved, and the effect of internal and external circulation conveying of furnace burden is formed.

As shown in fig. 2, a transmission component 6 is arranged between the central shaft 3 and the roller 4, the transmission component 6 is provided with an agitating piece 12, the central shaft 3 is not moved when the roller 4 rotates, and the agitating piece 12 can simultaneously rotate everywhere after being transmitted by the transmission component 6; the stirring pieces 12 are positioned on the inner side of the first spiral sheet 2, so that the stirring pieces 12 and the first spiral sheet 2 can be prevented from being interfered by movement, the stirring pieces 12 and the second spiral sheet 5 are arranged in a staggered manner, and the stirring pieces can be uniformly distributed, thereby being beneficial to full stirring.

The supporting frames 13 are provided with driving components 8, the driving components 8 are used for rotating the second shaft sleeve 11 and the first shaft sleeve 9, and the rotation direction is set according to whether the spiral directions of the first spiral sheet 2 and the second spiral sheet 5 are the same.

The discharging component 7 is arranged on the lower side of the mixing box 1, the complete mixing box 1 can be formed when the discharging component 7 is closed, and the mixed furnace burden can be put down into the smelting furnace for smelting when the discharging component 7 is opened.

Through the arrangement of the structure, the furnace burden can be mixed more fully, and the mixing efficiency is higher.

Specifically, as shown in fig. 5, the transmission assembly 6 includes a transmission rod 61, a second bevel gear 62 and a first bevel gear 63, the central shaft 3 is uniformly and fixedly provided with the first bevel gear 63, the circumference side of the drum 4 is uniformly provided with the drum, the drum penetrates through the drum 4, the transmission rod 61 is rotatably arranged in the drum through a bearing and a clamp spring, the bearing is used for reducing the rotation resistance, the clamp spring can avoid the axial movement of the transmission rod 61, one end of the transmission rod 61 is fixedly provided with the second bevel gear 62, the second bevel gear 62 is meshed and assembled with the first bevel gear 63, and the other end of the transmission rod 61 is fixedly assembled with the stirring piece 12; during operation, the central shaft 3 and the first bevel gear 63 are fixed, the rotating drum 4 can drive the transmission rod 61 to rotate circumferentially, so that the second bevel gear 62 walks along the first bevel gear 63, thereby rotating the transmission rod 61 and the stirring piece 12 to stir the furnace burden by the stirring piece 12, preferably, the diameter of the second bevel gear 62 is larger than that of the first bevel gear 63, the transmission ratio can be changed, and the transmission rod 61 and the stirring piece 12 can rotate more easily.

Further, the stirring member 12 is a straight plate or a spiral blade, and can be replaced by other stirring members according to the required stirring mode.

Specifically, as shown in fig. 4, both ends of the first shaft sleeve 9 protrude out of the supporting sleeve 10, both ends of the central shaft 3 protrude out of the first shaft sleeve 9, and enough transmission space is reserved for the arrangement of the driving assembly 8; the bearing is rotatably assembled between the central shaft 3 and the second shaft sleeve 11, between the second shaft sleeve 11 and the first shaft sleeve 9 and between the first shaft sleeve 9 and the supporting sleeve 10 so as to reduce rotation resistance, and the bearing is also positioned through the positioning barrel and the end cover which is in threaded connection, so that the positioning of the bearing is in the prior art and is not repeated herein.

Specifically, the driving assembly 8 comprises a gear motor 82, a driving spur gear 83 and a driven spur gear 84, the gear motor 82 is fixedly mounted on the supporting frame 13, the driving spur gear 83 is fixedly mounted at the output end of the gear motor 82, the driven spur gear 84 is fixedly mounted at one or both ends of the second shaft sleeve 11 and one or both ends of the first shaft sleeve 9, and the driving spur gear 83 and the driven spur gear 84 are meshed and assembled; the gear motor 82 is operative to rotatably drive the spur gear 83 such that the engaged driven spur gear 84 drives the second hub 11 and the first hub 9.

The form of arrangement of the drive assembly 8:

in the first form, when the volume of the mixing cavity is smaller, as shown in fig. 4, each supporting frame 13 is respectively provided with a driving component 8, one end of the second shaft sleeve 11 and one end of the first shaft sleeve 9 are respectively provided with a driven spur gear 84, and the driven spur gears 84 are not arranged at the same end; after the arrangement, one driving component 8 is used for rotating the second shaft sleeve 11, the other driving component 8 is used for rotating the first shaft sleeve 9, the power requirements of the rotation of the first spiral sheet 2 and the second spiral sheet 5 can be met, and the separately arranged driving components 8 are sufficient in installation space and convenient to maintain.

In the second form, when the volume of the mixing cavity is larger, two driving assemblies 8 are respectively arranged on each supporting frame 13, and driven spur gears 84 are respectively arranged at two ends of the second shaft sleeve 11 and two ends of the first shaft sleeve 9; after the arrangement, a pair of driving assemblies 8 are used for synchronously rotating the second shaft sleeve 11, and the other pair of driving assemblies 8 are used for synchronously rotating the first shaft sleeve 9, so that the power requirements of the rotation of the first spiral sheet 2 and the second spiral sheet 5 can be met, and the power is more abundant, and meanwhile, the stress on the first spiral sheet 2 and the second spiral sheet 5 is more uniform.

Further, bearing seats 81 are fixedly arranged on the upper surface of the supporting frame 13, and the output end of a gear motor 82 is assembled with the bearing seats 81 in a rotating way; the output end of the gear motor 82 can be supported through the arrangement of the bearing seat 81, and the stress capability of the driving spur gear 83 is improved.

Specifically, as shown in fig. 6, the discharging component 7 includes a material plate 71 and a pushing cylinder 72, the bottom of the mixing box 1 is hinged with two material plates 71 which are arranged in a split way, and the shape of the material plates 71 is matched with the bottom of the mixing box 1 and is arc-shaped; correspondingly, the bottom of the mixing box 1 is provided with a discharge hole for installing the charging plate 71, and the length of the discharge hole is the same as that of the mixing box 1, so that the size of the charging plate 71 is maximized, and the rapid discharge is facilitated; a pushing cylinder 72 is arranged below the material plate 71, a first supporting seat is rotatably assembled at the cylinder body end of the pushing cylinder 72, the upper end of the first supporting seat is fixedly assembled with the mixing box 1, a second supporting seat is rotatably assembled at the pushing rod end of the pushing cylinder 72, and the upper ends of the second supporting seats are fixedly assembled with the material plate 71 respectively; the pushing cylinder 72 is selected according to the conditions of the production workshop, and can be a hydraulic cylinder, an air cylinder or an electric cylinder, the pushing cylinder 72 is controlled to simultaneously extend out of the pushing rod end to close the two material plates 71, the pushing cylinder 72 is controlled to simultaneously shrink the pushing rod end to open the two material plates 71, and the pushing cylinder 72 can swing adaptively during stretching due to the rotating assembly of the cylinder body end and the first supporting seat and the rotating assembly of the pushing rod end and the second supporting seat, so that the opening and closing actions are smoothly completed.

Further, as shown in fig. 7, the adjacent side of the material plates 71 is provided with engagement grooves, the engagement grooves on both sides are arranged vertically in a staggered manner, and when the two material plates 71 are closed, the engagement grooves are offset in a staggered manner, so that the tightness of the mixing box 1 can be ensured, and the leakage of the furnace burden from the gap can be avoided.

The working mode of this embodiment will be described with the setting condition of the driving component 8 in the first form:

after the batching machine accurately measures various raw materials according to the weight required by the process, the raw materials are sequentially put into a mixing cavity through a conveyor, one driving component 8 drives a roller 4 and a second spiral sheet 5 to rotate through a second shaft sleeve 11, the other driving component 8 drives a first spiral sheet 2 to rotate through a first shaft sleeve 9, and the conveying directions of the rotation of the second spiral sheet 5 and the first spiral sheet 2 are opposite, so that the burden close to the roller 4 is conveyed to one side, the burden close to a mixing box 1 is conveyed to the other side, and the circulating mixing is completed in the mixing cavity;

meanwhile, the rotary drum 4 can rotate the stirring piece 12 after being driven by the driving component 6, stirring and stirring the circularly conveyed furnace burden, and improving the mixing effect and the mixing efficiency;

after the mixing is finished, the driving assembly 8 is stopped, the discharging assembly 7 opens the material plate 71 to discharge the mixed furnace burden downwards into the smelting furnace for smelting, and thus the mixed furnace burden is circulated, and the production efficiency can be improved.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims (10)

1. The ferromolybdenum is smelted and is used furnace charge blendor, including mixing box (1), its characterized in that: the novel spiral stirring device is characterized in that supporting sleeves (10) are respectively and fixedly arranged at the centers of two ends of the mixing box (1), supporting frames (13) are respectively and fixedly arranged at the bottoms of two ends of the mixing box (1), first shaft sleeves (9) are respectively and rotatably arranged in the supporting sleeves (10), first spiral sheets (2) are fixedly arranged between the first shaft sleeves (9) through supporting rods, the bottoms of the inner sides of the mixing box (1) are abutted against the first spiral sheets (2), second shaft sleeves (11) are respectively and rotatably arranged in the first shaft sleeves (9), a roller (4) is fixedly arranged between the second shaft sleeves (11), a central shaft (3) is fixedly arranged between the supporting frames (13), and the central shaft (3) is rotatably assembled in the second shaft sleeves (11) and penetrates through the roller (4);

a transmission assembly (6) is arranged between the central shaft (3) and the roller (4), a stirring piece (12) is arranged on the transmission assembly (6), the stirring piece (12) is positioned on the inner side of the first spiral sheet (2), and the stirring piece (12) and the second spiral sheet (5) are arranged in a staggered mode;

the driving assemblies (8) are arranged on the supporting frames (13), and the driving assemblies (8) are used for rotating the second shaft sleeve (11) and the first shaft sleeve (9);

the discharging component (7) is arranged on the lower side of the mixing box (1).

2. The charge mixer for ferromolybdenum smelting according to claim 1, wherein: the transmission assembly (6) comprises a transmission rod (61), a second bevel gear (62) and a first bevel gear (63), the first bevel gear (63) is uniformly and fixedly arranged on the central shaft (3), the rotary drum is uniformly arranged on the circumference side of the rotary drum (4), the transmission rod (61) is rotatably arranged in the rotary drum, the second bevel gear (62) is fixedly arranged at one end of the transmission rod (61), the second bevel gear (62) is meshed with the first bevel gear (63) for assembly, and the other end of the transmission rod (61) is fixedly assembled with the stirring piece (12).

3. The charge mixer for ferromolybdenum smelting according to claim 1, wherein: the two ends of the first shaft sleeve (9) are respectively extended out of the supporting sleeve (10), and the two ends of the central shaft (3) are respectively extended out of the first shaft sleeve (9).

4. A charge mixer for ferromolybdenum smelting according to claim 3, wherein: the bearing is used for rotatably assembling the central shaft (3) and the second shaft sleeve (11), the second shaft sleeve (11) and the first shaft sleeve (9) and the supporting sleeve (10).

5. The charge mixer for ferromolybdenum smelting according to claim 1, wherein: the driving assembly (8) comprises a gear motor (82), a driving spur gear (83) and a driven spur gear (84), the gear motor (82) is fixedly installed on the supporting frame (13), the driving spur gear (83) is fixedly installed at the output end of the gear motor (82), the driven spur gear (84) is fixedly installed at one end or two ends of the second shaft sleeve (11) and one end or two ends of the first shaft sleeve (9), and the driving spur gear (83) and the driven spur gear (84) are meshed and assembled.

6. The charge mixer for ferromolybdenum smelting according to claim 5, wherein: the upper surface of support frame (13) is all fixed mounting has bearing frame (81), the output of gear motor (82) and bearing frame (81) rotate the assembly.

7. The charge mixer for ferromolybdenum smelting according to claim 1, wherein: the discharging assembly (7) comprises a material plate (71) and a pushing cylinder (72), two material plates (71) which are arranged in a split mode are hinged to the bottom of the mixing box (1), pushing cylinders (72) are arranged below the material plates (71), first supporting seats are rotatably assembled at cylinder body ends of the pushing cylinders (72), second supporting seats are fixedly assembled with the mixing box (1) at upper ends of the first supporting seats, and second supporting seats are rotatably assembled at push rod ends of the pushing cylinders (72), and upper ends of the second supporting seats are fixedly assembled with the material plates (71) respectively.

8. The charge mixer for ferromolybdenum smelting according to claim 7, wherein: the material plates (71) are provided with engagement grooves on one sides close to each other, and the engagement grooves on two sides are arranged in a vertically staggered mode.

9. The charge mixer for ferromolybdenum smelting according to claim 1, wherein: the furnace burden conveying directions of the first spiral slice (2) and the second spiral slice (5) are opposite.

10. The charge mixer for ferromolybdenum smelting according to claim 1, wherein: the stirring piece (12) is a straight plate or a spiral fan blade.