CN114394729B - Glass melting furnace batching and distributing equipment - Google Patents

Abstract

The invention relates to a glass melting furnace batching and distributing device, which comprises a cylindrical bin body, wherein a blanking plate is horizontally and fixedly arranged in the bin body, a plurality of blanking holes are annularly and uniformly formed in the inner side of the blanking plate, a plurality of material supplementing holes which are in one-to-one correspondence with the blanking holes are annularly and uniformly formed in the outer side of the blanking plate, a weighing bin corresponding to the blanking holes is arranged below the blanking holes, a weighing sensor is arranged below the weighing bin, blanking hole baffles which can be opened and closed are arranged at the blanking holes, a material supplementing bin is fixedly arranged below the material supplementing holes, a material supplementing pipe is arranged at the bottom of the material supplementing bin, and the discharge end of the material supplementing pipe corresponds to an opening at the top of the weighing bin; but storehouse body upper portion center department rotation be equipped with spill hopper, spill hopper bottom is equipped with the spherical spill stub bar, spill overhead evenly to have seted up a plurality of holes that spill the material, spill stub bar bottom has set firmly the connecting block, follow on the connecting block blanking plate radius radiation direction annular evenly is provided with a plurality of scrapers.

Description

Glass melting furnace batching and distributing equipment

Technical Field

The invention relates to the technical field of glass production, in particular to a batching and distributing device of a glass melting furnace.

Background

At present, glass production has two raw materials, one is a particle raw material with good fluidity, the other is fragment glass reproduction, and the two raw materials are required to be put into a smelting furnace for liquefaction. In-process at the raw materials entering smelting pot, the raw materials need be through the count of weighing, the cloth process of transportation, traditional cloth system adopts to pass through the pipeline with the raw materials and carries weighing on the weighing device more, transfer to the reprinting dolly after weighing on, later the reprinting dolly is put into the raw materials and is prepared for melting in the storage silo, this in-process, because of the nature of raw materials itself, the raw materials of granule class weigh the inaccuracy and transport the difficulty, fragment glass easily splashes and the noise is big, because far away between the factory equipment, each equipment seal is poor, make the problem of noise and dust outstanding, workman operating condition is abominable.

The applicant discloses a glass raw materials melting furnace distributing system at utility model with publication number CN214358596U, rises through the reprint structure and throws the material device with weighing and be connected, can throw the material device with the raw materials from weighing and transport the distributing vehicle in, descend through the reprint structure and be connected with the storage silo, can transport the raw materials from the distributing vehicle to the storage silo. This process is realized with PLC control system, has reduced workman's work load, has improved production efficiency, and the in-process raw materials transports in equipment all the time, and the leakproofness is good, and the noise is little. However, in the actual use process, the weighing of the raw materials cannot be accurately controlled, because the raw materials in the weighing bin reach the required weight after the weighing of the weighing sensor is finished, and the falling raw materials are arranged above the weighing bin, so that the weight of the falling raw materials is not easy to measure, and the actual weight and the preset weight of the raw materials in the weighing bin are inaccurate; and when the auxiliary materials are required to be added, the phenomenon of uneven mixing of the auxiliary materials and the raw materials exists. Aiming at the problems, the invention provides the material distributing equipment for the glass melting furnace, which can accurately control the weight of raw materials, and has uniform distribution of the raw materials and good tightness.

Disclosure of Invention

The invention aims to provide the batching and distributing equipment of the glass melting furnace, which can accurately control the weight of raw materials, and has uniform distribution of the raw materials and good tightness.

In order to solve the problems, the technical scheme adopted by the invention is as follows:

a glass melting furnace batching and distributing device comprises a cylindrical bin body, wherein a blanking plate is horizontally and fixedly arranged in the bin body, a plurality of blanking holes are annularly and uniformly formed in the inner side of the blanking plate, a plurality of material supplementing holes which are in one-to-one correspondence with the blanking holes are annularly and uniformly formed in the outer side of the blanking plate, a weighing bin corresponding to the blanking holes is arranged below the blanking holes, a weighing sensor is arranged below the weighing bin, blanking hole baffles which can be opened and closed are arranged at the blanking holes, a material supplementing bin is fixedly arranged below the material supplementing holes, a material supplementing tube is arranged at the bottom of the material supplementing bin, and the discharge end of the material supplementing tube corresponds to an opening in the top of the weighing bin;

but storehouse body upper portion center department rotation be equipped with spill hopper, spill hopper bottom is equipped with the spherical spill stub bar, spill overhead evenly to have seted up a plurality of holes that spill the material, spill stub bar bottom has set firmly the connecting block, follow on the connecting block blanking plate radius radiation direction annular evenly be provided with a plurality of with the scraper blade of blanking plate upper surface looks adaptation.

As an embodiment of the invention, the middle part of the spreading hopper is a cylinder body, an annular supporting plate is fixedly arranged outside the cylinder body, a second plane thrust ball bearing is sleeved below the supporting plate on the cylinder body, and the second plane thrust ball bearing is supported by the bin body through a bracket and a reinforcing plate; the barrel overcoat is equipped with a plurality of bearings, the bearing supports through support frame two.

In one embodiment of the present invention, a driven gear is sleeved outside the support plate, a reduction motor is fixedly mounted on the bracket, and a driving gear engaged with the driven gear is provided on an output shaft of the reduction motor.

As an embodiment of the invention, a fan-shaped supporting plate is fixedly arranged below the blanking plate through a connecting column, the blanking hole baffle is positioned between the supporting plate and the blanking plate, the supporting plate is a grating plate or a filter plate, and the inner end of the blanking hole baffle is connected with a rotary driving device; the center of the bottom of the blanking plate is fixedly provided with an installation column, the installation column is horizontally and fixedly provided with an installation plate, and the rotary driving device is fixedly arranged on the installation plate.

As an embodiment of the present invention, a brush or a scraping strip is disposed at the bottom edge of the blanking hole.

As an implementation mode of the invention, the whole connecting block is in a conical or horn shape with a closed bottom, and a first plane thrust ball bearing is arranged between the bottom and the blanking plate.

As an embodiment of the invention, the inner ends and the outer ends of the scrapers are fixedly connected with the inner ring and the outer ring respectively.

As an implementation mode of the invention, the top of the weighing bin is provided with an opening, the inner side bin wall is inclined outwards from top to bottom, the bottom of the outer side bin wall is provided with a discharge pipe in an inclined manner, and the discharge pipe is provided with a second valve.

As an embodiment of the present invention, the weighing bin is disposed on the weighing sensor through a first support frame, and the weighing bin is provided with a vibrating device.

As an implementation mode of the invention, a third support frame is arranged at the top of the bin body, a hollow pipe is arranged in the scattering hopper along the axis, a vibrator is arranged at the bottom end of the hollow pipe and is positioned in the scattering head, the upper end of the hollow pipe is connected with the third support frame, and a lead of the vibrator passes through the hollow pipe and is led out from the upper end.

Adopt the produced beneficial effect of above-mentioned technical scheme to lie in:

the glass melting furnace material distribution equipment provided by the invention discharges materials to the weighing bin through the blanking hole, the actual weighing of the weighing sensor is reduced by a certain weight compared with the preset weighing, after the weighing is finished, the blanking hole is blocked by the blanking hole baffle, then the material is supplemented in a trickle manner through the material supplementing bin, and the material supplementing is stopped when the preset weighing is reached, so that the accurate control on the weight of the raw materials can be greatly improved.

Evenly spill the material on the blanking plate through spilling the stub bar, along with spilling the difference of hopper rotation speed, under centrifugal force and action of gravity, the ejection of compact speed of raw materials and the distribution area on the blanking plate are also different, and unloading speed can be adjusted according to actual production. In addition, when adding the auxiliary material, the auxiliary material can directly be added in spilling the hopper, is spilled out along with the raw materials from spilling the hopper, and the auxiliary material can realize the evenly distributed on the blanking plate, sets up the stirring rake at the hollow tube middle part, can also make raw materials and auxiliary material mix when descending through the barrel, further makes raw materials and auxiliary material misce bene.

Drawings

Fig. 1 is a schematic structural view of the present invention.

Fig. 2 is a schematic sectional view at a-a in fig. 1.

Fig. 3 is a partially enlarged schematic view of a portion a of fig. 1.

Fig. 4 is a partially enlarged schematic view of fig. 1 at B.

FIG. 5 is a schematic view showing the construction of the scrapers, the inner ring and the outer ring in the present invention.

Wherein: 1 bin body, 2 scattering bins, 2-1 scattering heads, 2-1-1 scattering holes, 2-2 barrel bodies, 2-3 feed openings, 3 connecting blocks, 4 scraping plates, 4-1 inner rings, 4-2 outer rings, 5 blanking plates, 6 planar thrust ball bearing I, 7 blanking holes, 8 material supplementing holes, 9 blanking hole baffle plates, 10 supporting plates, 11 connecting columns, 12 oil cylinder rods, 13 rotary oil cylinders, 14 mounting plates, 15 mounting columns, 16 material supplementing bins, 17 material supplementing pipes, 18 valve I, 19 material weighing bins, 20 arc parts, 21 material discharging pipes, 22 valve II, 23 material weighing sensors, 24 bearings, 25 supporting plates, 26 driven gears, 27 driving gears, 28 speed reducing motors, 29 supporting frames I, 30 supporting frames II, 31 brackets, 32 reinforcing plates, 33 vibrators, 34 hollow pipes, 35, clamping blocks 36 springs, 37 supporting frames III, 38 rotating bins, 39 planar thrust ball bearing II, a plurality of material supplementing holes, a plurality of the shape of the, 40 stirring paddle.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the following description of the present invention is given for clarity and completeness.

The glass melting furnace burden distribution equipment shown in fig. 1 and 2 comprises a cylindrical bin body 1, wherein a blanking plate 5 is horizontally and fixedly arranged in the middle of the bin body 1, a plurality of blanking holes 7 are annularly and uniformly formed in the inner side of the blanking plate 5, a plurality of material supplementing holes 8 which are in one-to-one correspondence with the blanking holes 7 are annularly and uniformly formed in the outer side of the blanking plate 5, weighing bins 19 corresponding to the blanking holes 7 are arranged below the blanking holes 7, weighing sensors 23 are arranged below the weighing bins 19, blanking hole baffles 9 which can be opened and closed are arranged at the blanking holes 7, material supplementing bins 16 are fixedly arranged below the material supplementing holes 8, material supplementing pipes 17 are arranged at the bottoms of the material supplementing bins 16, and the discharge ends of the material supplementing pipes 17 correspond to openings in the tops of the weighing bins 19;

the bin body is characterized in that a material scattering hopper 2 is arranged at the center of the upper portion of the bin body 1 in a self-rotating mode, a spherical material scattering head 2-1 is arranged at the bottom of the material scattering hopper 2, a plurality of material scattering holes 2-1-1 are uniformly formed in the material scattering head 2-1, a connecting block 3 is fixedly arranged at the bottom of the material scattering head 2-1, a plurality of scraping plates 4 matched with the upper surface of the blanking plate 5 are uniformly and annularly arranged on the connecting block 3 in the radial radiation direction of the radius of the blanking plate 5, and the scraping plates 4 are used for scraping raw materials which do not fall into the blanking holes 7 and the material supplementing holes 8.

The glass melting furnace material distribution equipment provided by the invention discharges materials to the weighing bin 19 through the blanking hole 7, the actual weighing of the weighing sensor 23 is reduced by a certain weight compared with the preset weighing, after the weighing is finished, the blanking hole 7 is blocked by the blanking hole baffle 9, then the material is supplemented in a trickle mode through the material supplementing bin 16, and the material supplementing is stopped when the preset weighing is reached, so that the accurate control on the weight of the raw materials can be greatly improved. The blanking plate 5 is uniformly sprinkled by the sprinkling head 2-1, the discharging speed of the raw materials and the annular distribution area on the blanking plate 5 are different under the action of centrifugal force and gravity along with the different rotating speeds of the sprinkling hopper 2, and the blanking speed can be adjusted according to actual production.

As shown in fig. 1 and 3, a cylinder 2-2 is arranged in the middle of the scattering hopper 2, an annular support plate 25 is fixedly arranged outside the cylinder 2-2, a second planar thrust ball bearing 39 is sleeved on the cylinder 2-2 below the support plate 25, and the second planar thrust ball bearing 39 is supported by the bin body 1 through a bracket 31 and a reinforcing plate 32; a plurality of bearings 24 are sleeved outside the barrel body 2-2, the bearings 24 are supported by a second support frame 30, in the embodiment, two bearings 24 are arranged and are respectively positioned above and below the second plane thrust ball bearing 39, and the second support frame 30 comprises an annular sleeve matched with the outer ring of the bearing 24 and a plurality of connecting plates for connecting the annular sleeve and the inner wall of the bin body 1. The upper part of the scattering hopper 2 penetrates out of the top of the bin body 1 to form a funnel-shaped feeding opening 2-3.

In this embodiment, a driven gear 26 is sleeved outside the supporting plate 25, a speed reduction motor 28 is fixedly arranged on the bracket 31, a driving gear 27 engaged with the driven gear 26 is arranged on an output shaft of the speed reduction motor 28, and the speed reduction motor 28 drives the discharge hopper 2 to rotate.

As shown in fig. 1, 2 and 4, a fan-shaped or annular supporting plate 10 is fixedly arranged below the blanking plate 5 through a plurality of connecting columns 11, the blanking hole baffle 9 is fan-shaped and is positioned between the supporting plate 10 and the blanking plate 5, the supporting plate 10 is a grating plate or a filter plate, the inner end of the blanking hole baffle 9 is connected with a rotary driving device, so that the blanking hole baffle 9 swings back and forth between the supporting plate 10 and the blanking plate 5 to open and close and block the blanking holes 7, and enough space is reserved between adjacent blanking holes 7 for the blanking hole baffle 9 to stay; the center of the bottom of the blanking plate 5 is fixedly provided with an installation column 15, the installation column 15 is horizontally and fixedly provided with an installation plate 14, and the rotation driving device is fixedly arranged on the installation plate 14, in the embodiment, the rotation driving device is a rotation oil cylinder 13, and an oil cylinder rod 12 of the rotation driving device is connected with the inner end of the blanking hole baffle 9. As a further optimization, the supporting plate 10 is provided with a through hole at a position corresponding to the blanking hole 7, so that raw materials are prevented from falling on the grid plate or the filter plate.

As further optimization, the bottom edge of the blanking hole 7 is provided with a brush or a scraping strip, so that the raw materials are prevented from being brought out of the weighing bin 19 when the blanking hole 7 is opened by the blanking hole baffle 9.

The whole connecting block 3 is conical or horn-shaped with a closed bottom, so that material guiding is facilitated, and a planar thrust ball bearing I6 is arranged between the bottom and the blanking plate 5 and can be used for bearing.

As a further optimization, as shown in FIG. 5, the inner ends and the outer ends of the plurality of scrapers 4 are fixedly connected with the inner ring 4-1 and the outer ring 4-2 respectively, so that the integral structure of the scrapers 4 is more stable.

The top opening of the weighing bin 19 and the inner side bin wall are inclined outwards from top to bottom to form an arc-shaped part 20, so that the materials can be discharged conveniently, the bottom of the outer side bin wall is inclined to form a material discharging pipe 21, and a valve II 22 is arranged on the material discharging pipe 21. The weighing bin 19 is arranged on the weighing sensor 23 through a first support frame 29, and the vibrating device is arranged on the weighing bin 19, so that discharging can be accelerated, and blocking is prevented.

As further optimization, as shown in fig. 1, a third support frame 37 is arranged at the top of the bin body 1, a hollow tube 34 is arranged in the scattering hopper 2 along the axis, a vibrator 33 is arranged at the bottom end of the hollow tube 34, the vibrator 33 is positioned in the scattering head 2-1, the upper end of the hollow tube 34 is connected with the third support frame 37, a lead of the vibrator 33 is led out from the upper end after passing through the hollow tube 34, and the vibrator 33 is arranged, so that the raw material can be prevented from being blocked in the scattering head 2-1, and the raw material and auxiliary material can be mixed conveniently. As further optimization, a via hole is formed in the middle of the horizontal part of the third support frame 37, the upper end of the hollow tube 34 is limited by a clamping block 35 after penetrating out of the via hole in the third support frame 37, and a damping spring 36 is arranged between the clamping block 35 and the horizontal part of the third support frame 37, so that vibration and noise can be greatly reduced.

The third support frame 37 is further provided with a material transferring hopper 38 for adding raw materials and auxiliary materials, when the auxiliary materials are added, the auxiliary materials can be directly added into the material scattering hopper 2, and the auxiliary materials can be uniformly distributed on the blanking plate 5 along with the scattering of the raw materials from the material scattering hopper 2-1. As a further optimization, the stirring paddle 40 is arranged in the middle of the hollow pipe 34, so that the raw materials and the auxiliary materials can be mixed when descending through the cylinder 2-2, and the raw materials and the auxiliary materials are further uniformly mixed.

The first valve 18 and the second valve 22 are both solenoid valves. Still include the controller, gear motor 28, a plurality of rotatory hydro-cylinder 13, valve 18 and valve two 22 with the controller electrical property links to each other, and after the storehouse 19 of weighing that corresponds was weighed and is accomplished, the pilot lamp that sets up on the storehouse body 1 and weigh storehouse 19 and correspond is bright, carries out corresponding row of the storehouse 19 of weighing through arranging material pipe 21 and arranges the material, carries out the production of next process, owing to set up a plurality of storehouses 19 of weighing, a plurality of storehouses 19 of weighing arrange in turn, has improved the efficiency of weighing greatly, has shortened production cycle. When the utility model is used in actual production, the lower part of the bin body 1 is also provided with a support column or a support to lift the bin body 1, so that the discharging pipe 21 can discharge materials conveniently.

Although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art may still make modifications to the technical solutions described in the foregoing embodiments, or may substitute some technical features of the embodiments; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims (9)

1. The utility model provides a glass melting furnace batching cloth equipment which characterized in that: the blanking device comprises a cylindrical bin body (1), wherein a blanking plate (5) is horizontally and fixedly arranged in the bin body (1), a plurality of blanking holes (7) are annularly and uniformly formed in the inner side of the blanking plate (5), a plurality of feeding holes (8) which are in one-to-one correspondence with the blanking holes (7) are annularly and uniformly formed in the outer side of the blanking plate (5), a weighing bin (19) corresponding to the blanking holes (7) is arranged below the blanking holes (7), a weighing sensor (23) is arranged below the weighing bin (19), blanking hole baffles (9) which can be opened and closed are arranged at the blanking holes (7), a feeding bin (16) is fixedly arranged below the feeding holes (8), a feeding pipe (17) is arranged at the bottom of the feeding bin (16), and the discharge end of the feeding pipe (17) corresponds to an opening at the top of the weighing bin (19);

a material scattering hopper (2) is arranged at the center of the upper part of the bin body (1) in a self-rotating manner, a spherical material scattering head (2-1) is arranged at the bottom of the material scattering hopper (2), a plurality of material scattering holes (2-1-1) are uniformly formed in the material scattering head (2-1), a connecting block (3) is fixedly arranged at the bottom of the material scattering head (2-1), and a plurality of scraping plates (4) matched with the upper surface of the blanking plate (5) are uniformly arranged on the connecting block (3) in an annular manner along the radial direction of the blanking plate (5);

the middle part of the scattering hopper (2) is provided with a cylinder body (2-2), an annular supporting plate (25) is fixedly arranged outside the cylinder body (2-2), a second plane thrust ball bearing (39) is sleeved below the supporting plate (25) on the cylinder body (2-2), and the second plane thrust ball bearing (39) is supported by the bin body (1) through a bracket (31) and a reinforcing plate (32); a plurality of bearings (24) are sleeved outside the cylinder body (2-2), and the bearings (24) are supported by a second support frame (30).

2. The glass melting furnace batch distribution apparatus of claim 1, wherein: the supporting plate (25) is sleeved with a driven gear (26), the bracket (31) is fixedly provided with a speed reducing motor (28), and an output shaft of the speed reducing motor (28) is provided with a driving gear (27) meshed with the driven gear (26).

3. The glass melting furnace batch distribution apparatus of claim 1, wherein: a fan-shaped supporting plate (10) is fixedly arranged below the blanking plate (5) through a connecting column (11), the blanking hole baffle (9) is positioned between the supporting plate (10) and the blanking plate (5), the supporting plate (10) is a grating plate or a filter plate, and the inner end of the blanking hole baffle (9) is connected with a rotary driving device; the center of the bottom of the blanking plate (5) is fixedly provided with a mounting column (15), a mounting plate (14) is horizontally and fixedly arranged on the mounting column (15), and the rotary driving device is fixedly arranged on the mounting plate (14).

4. The glass melting furnace batch distribution apparatus of claim 3, wherein: and a brush or a scraping strip is arranged at the bottom edge of the blanking hole (7).

5. The glass melting furnace batch distribution apparatus of claim 1, wherein: the connecting block (3) is integrally conical or trumpet-shaped with a closed bottom, and a first plane thrust ball bearing (6) is arranged between the bottom and the blanking plate (5).

6. The glass melting furnace batch distribution apparatus of claim 1, wherein: the inner ends and the outer ends of the scrapers (4) are respectively fixedly connected with the inner ring (4-1) and the outer ring (4-2).

7. The glass melting furnace batch distribution apparatus of claim 1, wherein: the top opening of the weighing bin (19), the inner side bin wall are inclined outwards from top to bottom, the bottom of the outer side bin wall is inclined and provided with a material discharging pipe (21), and a second valve (22) is arranged on the material discharging pipe (21).

8. The glass melting furnace batch distribution apparatus of claim 1, wherein: the weighing bin (19) is arranged on the weighing sensor (23) through a first support frame (29), and a vibration device is arranged on the weighing bin (19).

9. The glass melting furnace batch distribution plant according to any one of claims 1 to 8, characterized in that: the bin body (1) is provided with a support frame III (37) at the top, a hollow pipe (34) is arranged in the scattering hopper (2) along the axis, a vibrator (33) is arranged at the bottom end of the hollow pipe (34), the vibrator (33) is positioned in the scattering head (2-1), the upper end of the hollow pipe (34) is connected with the support frame III (37), and a lead of the vibrator (33) is led out from the upper end after passing through the hollow pipe (34).

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