CN220968818U - Ferromolybdenum smelting batching mixing arrangement - Google Patents

Abstract

The utility model discloses a ferromolybdenum smelting and proportioning mixing device which comprises a mixing tank, wherein a rotating motor is fixedly arranged at the upper end of the inner wall of the mixing tank, a mixing block is arranged at the output end of the rotating motor, a rotating shaft is arranged at the front side and the rear side of a conveying pipe, one end of the rotating shaft is connected with the inner wall of a supporting frame, a supporting sleeve groove is arranged at one side of the supporting frame, an extending supporting block is inserted into the inner wall of the supporting sleeve groove, a supporting sleeve plate is arranged at the upper end of the extending supporting block, and sliding beads are embedded at the lower end of the inner wall of the supporting sleeve plate. This ferromolybdenum smelting batching mixing arrangement can be through the dislocation rotation of compounding piece for stirring compounding effect is better, can reset the upset through the closure plate moreover, can effectively avoid feeding raise dust, can carry out pan feeding preliminary treatment through breaking up the piece moreover, avoids blocking up to the conveying pipeline can seal through the auger and carry, avoids the raise dust, and the conveying pipeline can overturn position adjustment through the pivot moreover, carries more in a flexible way.

Description

Ferromolybdenum smelting batching mixing arrangement

Technical Field

The utility model relates to the technical field of ferromolybdenum smelting ingredients, in particular to a ferromolybdenum smelting ingredient mixing device.

Background

Conventional raw materials required by ferromolybdenum smelting include molybdenum oxide, aluminum powder, iron scraps, steel particles, lime, fluorite and the like, and in order to ensure the smelting effect, mixing treatment is required before the ferromolybdenum is put into a smelting furnace, so that the required raw materials have strict requirements on granularity and are mostly in fine powder form.

The prior CN201586503U ferromolybdenum smelting furnace burden mixer has the advantages that as the mixing tanks are obliquely arranged and the spiral shoveling plates are arranged on the inner wall, the clockwise rotation mixing and the anticlockwise rotation automatic discharging of the mixing tanks can be realized, the automation degree is high, the mechanization degree of mixing equipment in the ferromolybdenum smelting industry is improved, and the labor intensity is reduced; the mixing time is short, the effect is good, the mixing uniformity of furnace burden is high, but the existing equipment is poor in stirring effect, the materials cannot be pretreated, blockage is easy to cause, flexible adjustment cannot be carried out, and dust is easy to cause during carrying and discharging, so that the ferromolybdenum smelting and proportioning mixing device is needed to solve the problems.

Disclosure of utility model

The utility model aims to provide a ferromolybdenum smelting burden mixing device, which solves the problems that a ferromolybdenum smelting burden mixer is poor in stirring effect, incapable of preprocessing materials, easy to cause blockage, incapable of flexibly adjusting conveying and easy to cause dust in conveying and discharging in the background art.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a ferromolybdenum smelting batching mixing arrangement, includes the blending tank, the pan feeding mouth is installed to blending tank upper end intercommunication, and the PLC controller is installed to its compounding tank front side, and the support frame is installed to compounding tank lower extreme edge, the intercommunication is installed to compounding tank lower extreme central point puts and is linked together the pipeline, and linked together pipeline lower extreme intercommunication and install the conveying pipeline, conveying pipeline one end cartridge is installed driving motor, and driving motor output installs the auger, conveying pipeline other end edge fixedly connected with concatenation thread groove, and the concatenation thread groove other end is installed the concatenation thread piece, concatenation thread piece other end edge fixedly connected with extension pipe, the feed inlet is installed to feed inlet inner wall upper end, and feed inlet inner wall side-mounting has the pivot that resets, the closure plate is installed to pivot one side that resets, feed inlet front side cartridge installs servo motor, and the servo motor output installs the piece that breaks up, break up the piece is installed in the inner wall cartridge of feed inlet, rotary motor output installs the auger, and rotary motor output installs the screw, feed end fixedly connected with the extension pipe in front of support frame and support frame, support sleeve one side and inner wall cartridge installation support frame, support sleeve inner wall front end and support sleeve installation support frame, support sleeve inner wall front side and support sleeve, support sleeve front end and support sleeve installation support frame.

Preferably, the conveying pipe and the auger are in overturning connection with the supporting frame through the rotating shaft, and the conveying pipe is in bending connection with the mixing tank through the communicating pipeline.

Preferably, the extension pipe is of a bending structure, and the extension pipe is spirally spliced and installed with the conveying pipe in the splicing thread groove through the splicing thread block.

Preferably, the closing plate is in reset turnover connection with the feeding port through a reset rotating shaft, the feeding port is of a grid structure, and the scattering blocks are in rotary movable connection with the feeding port through a servo motor.

Preferably, the mixing block is in rotary connection with the mixing tank through a rotary motor, and the mixing block is distributed in two groups of dislocation structures on the inner wall of the mixing tank.

Preferably, the support sleeve plate is sleeved and slidably mounted with the conveying pipe through the sliding beads, and the support sleeve plate is in two-section lifting connection with the support sleeve groove through the extension support block.

Compared with the prior art, the utility model has the beneficial effects that: this ferromolybdenum smelting batching mixing arrangement can be through the dislocation rotation of compounding piece for stirring compounding effect is better, can reset the upset through the closure plate moreover, can effectively avoid feeding raise dust, can carry out pan feeding preliminary treatment through breaking up the piece moreover, avoids blocking up to the conveying pipeline can seal through the auger and carry, avoids the raise dust, and the conveying pipeline can overturn position adjustment through the pivot moreover, carries more in a flexible way.

Drawings

FIG. 1 is a front view of a ferromolybdenum smelting burden mixing device;

FIG. 2 is a cross-sectional view of a ferromolybdenum smelting burden mixing device of the present utility model;

FIG. 3 is an enlarged view of the ferromolybdenum smelting burden mixing device at A in FIG. 2;

FIG. 4 is an enlarged view of the ferromolybdenum smelting burden mixing device of the present utility model at B in FIG. 2;

FIG. 5 is an enlarged view of the ferromolybdenum smelting burden mixing device at C in FIG. 2;

Fig. 6 is an enlarged view of the ferromolybdenum smelting burden mixing device at D in fig. 2 according to the present utility model.

In the figure: 1. mixing tank, 2, feed inlet, 3, PLC controller, 4, support frame, 5, conveying pipeline, 6, extension pipe, 7, auger, 8, rotating electrical machines, 9, closing plate, 10, driving motor, 11, compounding piece, 12, support the cover groove, 13, extension supporting shoe, 14, concatenation thread groove, 15, concatenation thread piece, 16, feed inlet, 17, the pivot that resets, 18, break up the piece, 19, servo motor, 20, communication pipeline, 21, pivot, 22, support the cover board, 23, the sliding bead, 24, locking knob.

Detailed Description

The following description of the embodiments of the present utility model 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 utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-6, the present utility model provides a technical solution: a ferromolybdenum smelting and proportioning mixing device comprises a mixing tank 1, a feed inlet 2, a PLC controller 3, a support frame 4, a feed conveying pipe 5, an extension pipe 6, a packing auger 7, a rotating motor 8, a sealing plate 9, a driving motor 10, a mixing block 11, a support sleeve groove 12, an extension support block 13, a splicing thread groove 14, a splicing thread block 15, a feed inlet 16, a reset rotating shaft 17, a scattering block 18, a servo motor 19, a communicating pipe 20, a rotating shaft 21, a support sleeve plate 22, a sliding bead 23 and a locking knob 24, wherein the feed inlet 2 is arranged at the upper end of the mixing tank 1 in a communicating way, the PLC controller 3 is arranged at the front side of the mixing tank 1, the support frame 4 is arranged at the edge of the lower end of the mixing tank 1, the communicating pipe 20 is arranged at the central position of the lower end of the mixing tank 1 in a communicating way, the feed conveying pipe 5 is arranged at the lower end of the communicating pipe 20 in a communicating way, the feed conveying pipe 5 and the packing auger 7 are connected with the support frame 4 in a turnover way through the rotating shaft 21, and the conveying pipe 5 is connected with the mixing tank 1 in a bending and communicating way through the communicating pipe 20, so that the conveying pipe 5 and the packing auger 7 are convenient for overturning position adjustment, the conveying is more flexible, one end of the conveying pipe 5 is inserted and combined with the driving motor 10, the packing auger 7 is arranged at the output end of the driving motor 10, the edge of the other end of the conveying pipe 5 is fixedly connected with the splicing thread groove 14, the splicing thread block 15 is arranged at the other end of the splicing thread groove 14, the extending pipe 6 is fixedly connected with the extending pipe 6 at the other end edge of the splicing thread block 15, the extending pipe 6 is spirally spliced and arranged with the conveying pipe 5 in the splicing thread groove 14 through the splicing thread block 15, thus the extending pipe 6 is convenient for carrying out the extending adjustment of the conveying pipe 5, the use is more convenient, the upper end of the inner wall of the feeding hole 2 is provided with the feeding hole 16, the side surface of the inner wall of the feeding hole 16 is provided with the reset rotating shaft 17, the closing plate 9 is installed to pivot 17 one side that resets, closing plate 9 is the upset of resetting through pivot 17 and feed inlet 16 and is connected, and feed inlet 16 is grid structure, break up the piece 18 and be rotatory swing joint with feed inlet 2 through servo motor 19, make closing plate 9 conveniently reset the upset, conveniently carry out effectual raise dust, and can break up the piece 18 and break up the preliminary treatment to the material, feed inlet 2 front side cartridge installs servo motor 19, and servo motor 19 output installs breaks up piece 18, break up piece 18 and be in feed inlet 2 inner wall cartridge installation, mix tank 1 inner wall upper end fixed mounting has rotating electrical machines 8, and rotating electrical machines 8 output installs mixing piece 11, mix piece 11 is swivelling joint through rotating electrical machines 8 and mix tank 1, and mix piece 11 is two sets of dislocation structure distribution in mix tank 1 inner wall, make mix piece 11 conveniently carry out more efficient compounding stirring like this, work efficiency is better, the front and back side of conveying 5 installs pivot 21, and 21 one end are connected with support frame 4 inner wall, support frame 4 one side cartridge 12 is installed to support sleeve 12, support sleeve 12 is installed to support sleeve 22, support sleeve 13 and is installed to support sleeve 13, support sleeve 22 is installed to support sleeve 13, support sleeve 13 is installed to support sleeve 13, the end is convenient for the end is installed to mix piece, and is connected to the inside sleeve 13 is connected to the inside roll-down, and mix piece is connected to mix sleeve 13 is convenient to carry out the mix material to carry out efficient mixing stirring.

Working principle: when the ferromolybdenum smelting and proportioning mixing device is used, the device is firstly assembled and installed, then the device is connected with a power supply, then materials are injected into a feeding port 2, so that a closing plate 9 is turned and opened through a reset rotating shaft 17, then a scattering block 18 is driven to rotate through a servo motor 19 to scatter and pretreat the materials, after feeding is completed, the ferromolybdenum smelting and proportioning mixing device can be automatically closed through the closing plate 9, then a mixing block 11 is driven to rotate in a staggered mode through a rotating motor 8 to carry out efficient mixing, then a packing auger 7 is driven to rotate through a driving motor 10 to conduct diversion conveying on the mixed materials through a conveying pipe 5, and when the conveying position needs to be adjusted, the conveying pipe 5 is turned and adjusted through a rotating shaft 21, then lifting support is carried out through an extension supporting block 13 and a locking knob 24 to conduct stable material guiding, so that the ferromolybdenum smelting and proportioning mixing device is used.

Although the present utility model has been described with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements and changes may be made without departing from the spirit and principles of the present utility model.

Claims (6)

1. The utility model provides a ferromolybdenum smelting batching mixing arrangement, includes compounding jar (1), pan feeding mouth (2) are installed in compounding jar (1) upper end intercommunication, and PLC controller (3) are installed to its compounding jar (1) front side, and support frame (4) are installed at compounding jar (1) lower extreme edge, its characterized in that: the utility model discloses a mixing tank, including compounding jar (1), feed inlet (16) are installed to compounding jar (1) lower extreme central point put intercommunication, and feed inlet (16) inner wall side-mounting has reset pivot (17), closing plate (9) are installed to reset pivot (17) one side, auger (7) are installed to feed inlet (2) front side plug-in, and servo motor (19) output is installed and is broken up piece (18), break up piece (18) are installed in feed inlet (2) inner wall plug-in, splice thread piece (15) are installed to splice thread piece (14) other end, splice thread piece (15) other end edge fixedly connected with extension pipe (6), feed inlet (2) inner wall upper end is installed feed inlet (16), and feed inlet (16) inner wall side-mounting has reset pivot (17), closing plate (9) are installed to reset pivot (17) one side, servo motor (19) output is installed to feed inlet (2) front side plug-in, break up piece (18) are installed in feed inlet (2) inner wall plug-in and are installed, compounding jar (1) inner wall (8) is installed to rotate, and feed inlet (8) are installed with feed inlet (21) and are installed to feed inlet (16) inner wall side-side (8) rotary support frame (21), support sleeve groove (12) are installed to support frame (4) one side, and support sleeve groove (12) inner wall cartridge is installed and is extended supporting shoe (13), extend supporting shoe (13) upper end and install support sleeve plate (22), and support sleeve plate (22) inner wall lower extreme is inlayed and is installed sliding bead (23), support sleeve groove (12) front side upper end cartridge is installed locking knob (24).

2. The ferromolybdenum smelting burden mixing device according to claim 1, wherein: the conveying pipe (5) and the auger (7) are in overturning connection with the supporting frame (4) through the rotating shaft (21), and the conveying pipe (5) is in bending communication connection with the mixing tank (1) through the communication pipeline (20).

3. The ferromolybdenum smelting burden mixing device according to claim 2, wherein: the extension pipe (6) is of a bending structure, and the extension pipe (6) is spirally spliced and installed with the conveying pipe (5) in the splicing thread groove (14) through the splicing thread block (15).

4. A ferromolybdenum smelting batch mixing device according to claim 3, wherein: the sealing plate (9) is in reset and overturning connection with the feed inlet (16) through a reset rotating shaft (17), the feed inlet (16) is of a grid structure, and the scattering blocks (18) are in rotary and movable connection with the feed inlet (2) through a servo motor (19).

5. The ferromolybdenum smelting burden mixing device according to claim 4, wherein: the mixing block (11) is in rotary connection with the mixing tank (1) through the rotary motor (8), and the mixing block (11) is distributed in two groups of dislocation structures on the inner wall of the mixing tank (1).

6. The ferromolybdenum smelting burden mixing device according to claim 5, wherein: the supporting sleeve plate (22) is sleeved with the conveying pipe (5) through the sliding beads (23) in a sliding mode, and the supporting sleeve plate (22) is connected with the supporting sleeve groove (12) in a two-section lifting mode through the extending supporting blocks (13).