CN212051097U - Glass production charging equipment - Google Patents

Abstract

The utility model discloses a glass production feeding equipment, including device casing, sealed apron, eccentric wheel and atress board, the articulated equipment chamber door that is fixed with in the outside of device casing, and the outside welded fastening of device casing has the liquid box of mixing, the outside laminating of mixing the liquid box is connected with driving motor, sealed apron is installed at the top of device casing, and the outside of sealed apron runs through and is provided with discharge pipe, the laminating is connected with the ash filtering net board directly over the discharge pipe, the outside through connection of device casing has the equipment layer board, and the bottom welding of equipment layer board has auxiliary wheel, be provided with the delivery track under the auxiliary wheel, driving motor's output is connected with simultaneously mixes liquid piece and revolving drum, and the outside welded fastening of revolving drum has the compounding blade. This glass production charging equipment adopts eccentric wheel and face gear, utilizes the inside vibration that produces of eccentric wheel pair device casing, accelerates the efficiency of material screening and derivation.

Description

Glass production charging equipment

Technical Field

The utility model relates to a glass production facility technical field specifically is a glass production feeding equipment.

Background

Before production, quartz sand, soda ash and feldspar are crushed, wet raw materials are dried, the problem that the water content inside the materials greatly affects the production quality of the glass is avoided, iron-containing impurities inside the raw materials are subjected to iron removal treatment, and then the glass batch is subjected to high-temperature melting in a tank furnace or a crucible furnace, so that the uniform and bubble-free liquid glass is formed and meets the forming requirements.

Present charging equipment stirs and throws the material to glass raw and other materials in the use, needs the vehicle, in the use, needs to consume a large amount of intensity of labour to be difficult to throw the scope of material according to the length adjustment of tank furnace or crucible kiln, be unfavorable for evenly throwing the material and mix, glass raw and other materials inside need add certain degree liquid material, in the liquid mixing process, be difficult to carry out the homogeneous mixing to the inside additive of liquid, influence the transparency degree of glass later stage solidification.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a glass production charging equipment to solve present charging equipment that proposes in the above-mentioned background art in the use, need consume a large amount of intensity of labour, and be difficult to throw the scope of material according to the length adjustment of tank furnace or crucible furnace, glass raw and other materials are inside to need add certain degree liquid material, at the liquid mixing in-process, are difficult to carry out the problem of homogeneous mixing to the inside additive of liquid.

In order to achieve the purpose, the utility model provides a glass production feeding device, which comprises a device shell, a sealing cover plate, an eccentric wheel and a stress plate, wherein the outer side of the device shell is fixedly hinged with a device box door, the outer side of the device shell is fixedly welded with a liquid mixing box body, the outer side of the liquid mixing box body is connected with a driving motor in a laminating way, the sealing cover plate is arranged at the top of the device shell, a discharge pipeline is arranged at the outer side of the sealing cover plate in a penetrating way, a dust filtering screen plate is connected just above the discharge pipeline in a laminating way, the outer side of the device shell is connected with a device supporting plate in a penetrating way, an auxiliary wheel is welded at the bottom of the device supporting plate, a conveying track is arranged just below the auxiliary wheel, the output end of the driving motor is simultaneously connected with a liquid mixing sheet and a rotary drum, the left and right sides welding of compounding blade has the magnet piece, one side nested connection of rotatory section of thick bamboo has the face gear, the inside welded fastening of device casing has the rectangle guide rail, and the nested connection has the screening otter board between the rectangle guide rail.

Preferably, the device shell and the equipment supporting plate form a sliding structure through the auxiliary wheel and the plane gear, the surface area of the equipment supporting plate is larger than that of the device shell, and the device shell is integrally in a conical structure.

Preferably, the connection surface of the liquid mixing box body and the device shell is of a gauze structure, and the device shell is connected with the discharge pipeline through an ash filtering screen plate.

Preferably, the mixing blades are annularly distributed on the outer side of the rotary cylinder, and the rotary cylinder and the liquid mixing piece are parallel to each other.

Preferably, the screening otter board is connected with the device shell through a rectangular guide rail, the width of the rectangular guide rail is half of the width of the screening otter board, and the number of the screening otter boards is two.

Preferably, the eccentric wheel, the stress plate, the device shell and the driving motor form a vibration structure, the output end of the driving motor is connected with the eccentric wheel, the stress plate is arranged right below the eccentric wheel, and the stress plate and the device shell are welded into an integral structure.

Compared with the prior art, the beneficial effects of the utility model are that: the glass production feeding device comprises a feeding device,

1. the eccentric wheel and the plane gear are adopted, the eccentric wheel is utilized to vibrate the interior of the device shell, the efficiency of screening and guiding out materials is accelerated, impurities are prevented from being blocked on the surface of the screening screen plate, the plane gear is utilized to drive the auxiliary wheel to rotate, the auxiliary wheel is utilized to drive the device shell to horizontally move, the device shell can conveniently horizontally throw the materials,

2. adopt and strain grey otter board and equipment layer board, utilize and strain the dust of grey otter board in to the air and filter, conveniently carry out the edulcoration to the raw and other materials that filter mixing process and handle, and then reduce the inside impurity content of raw and other materials to utilize equipment layer board drive device casing to remove, ensure the stability of device casing in removal and course of working.

Drawings

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

FIG. 2 is a schematic view of the internal structure of the device housing of the present invention;

FIG. 3 is a schematic top view of the device housing of the present invention;

fig. 4 is a schematic view of the screening net plate of the present invention.

In the figure: 1. a device housing; 2. an equipment box door; 3. a liquid mixing box body; 4. a drive motor; 5. sealing the cover plate; 6. a discharge conduit; 7. a dust screen plate; 8. an equipment pallet; 9. an auxiliary wheel; 10. a conveying track; 11. mixing liquid tablets; 12. a rotary drum; 13. mixing blades; 14. a magnet sheet; 15. a face gear; 16. a rectangular guide rail; 17. screening a screen plate; 18. an eccentric wheel; 19. a stress plate.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-4, the present invention provides a technical solution: a glass production charging device comprises a device shell 1, a device box door 2, a liquid mixing box body 3, a driving motor 4, a sealing cover plate 5, a discharge pipeline 6, an ash filtering screen plate 7, a device supporting plate 8, auxiliary wheels 9, a conveying track 10, a liquid mixing piece 11, a rotary cylinder 12, material mixing blades 13, a magnet piece 14, a plane gear 15, a rectangular guide rail 16, a screening screen plate 17, an eccentric wheel 18 and a stress plate 19, wherein the device box door 2 is fixedly hinged to the outer side of the device shell 1, the liquid mixing box body 3 is fixedly welded to the outer side of the device shell 1, the driving motor 4 is connected to the outer side of the liquid mixing box body 3 in a laminating mode, the sealing cover plate 5 is installed at the top of the device shell 1, the discharge pipeline 6 penetrates through the outer side of the sealing cover plate 5, the ash filtering screen plate 7 is connected to the position right above the discharge pipeline 6 in a laminating mode, the device supporting plate 8 penetrates through the outer side of the, a conveying track 10 is arranged right below the auxiliary wheel 9, the output end of the driving motor 4 is connected with a liquid mixing piece 11 and a rotating cylinder 12 at the same time, the outer side of the rotating cylinder 12 is welded and fixed with a material mixing blade 13, the left side and the right side of the material mixing blade 13 are welded with a magnet piece 14, one side of the rotating cylinder 12 is connected with a plane gear 15 in an embedded mode, a rectangular guide rail 16 is welded and fixed inside the device shell 1, and a screening screen plate 17 is connected between the rectangular guide rails 16 in an embedded mode.

The device shell 1 and the equipment supporting plate 8 form a sliding structure through the auxiliary wheels 9 and the plane gear 15, the surface area of the equipment supporting plate 8 is larger than that of the device shell 1, the device shell 1 is integrally in a conical structure, the position of the device shell 1 is conveniently fed according to the length of the tank furnace, and the daily feeding automation degree is improved.

Mix liquid box 3 and device casing 1 and be connected the face and be yarn network structure, and device casing 1 is connected through filter dust otter board 7 with discharge pipe 6, conveniently blows the dust of material inside to raw and other materials edulcoration in-process, reduces the inside impurity content of raw and other materials.

Mixing blade 13 is the annular and distributes in the outside of a rotatory section of thick bamboo 12, and a rotatory section of thick bamboo 12 is parallel to each other with mixing liquid piece 11, utilizes mixing blade 13 to stir the material, and the convenience is adsorbed the inside iron impurity of material.

Screening otter board 17 is connected through rectangular guide 16 with device casing 1, and rectangular guide 16's width is half of screening otter board 17 width to screening otter board 17's quantity is two sets of, utilizes screening otter board 17 to filter the material that does not conform to the size, ensures the effect that the material mixes and dissolves.

Eccentric wheel 18, atress board 19, device casing 1 and driving motor 4 constitute vibrations structure, and driving motor 4's output is connected with eccentric wheel 18 to be provided with atress board 19 under eccentric wheel 18, atress board 19 and device casing 1 welding formula structure as an organic whole in addition, the inside vibration that produces of eccentric wheel 18 device, the convenient screening otter board 17 filters the impurity of material inside.

The working principle is as follows: when the glass production charging equipment is used, as shown in fig. 1 to 3, an operator firstly fixes a conveying rail 10 at the top of a tank furnace or a crucible furnace, then pours different types of raw materials into the interior of a device shell 1, installs a sealing cover plate 5 at the top of the device shell 1, then opens a driving motor 4, drives a rotary cylinder 12 to rotate by using the driving motor 4, drives a mixing blade 13 and a magnet sheet 14 to rotate by using the rotary cylinder 12, adsorbs iron impurities in the materials by using the magnet sheet 14, mixes and stirs liquid materials by using a mixing sheet 11, fuses the liquid materials and solid materials with each other, and stirs continuously;

as shown in fig. 1 to 4, a plane gear 15 connected to an output end of a driving motor 4 is connected to a plane gear 15 connected to an auxiliary wheel 9, the driving motor 4 is then turned on, the driving motor 4 drives the plane gear 15 to rotate, the plane gear 15 drives the plane gear 15 to rotate, the auxiliary wheel 9 is driven to rotate by the plane gear 15, the auxiliary wheel 9 drives the device housing 1 and the equipment box door 2 to slide inside the conveying track 10, an operator can open a discharge valve at the bottom of the device housing 1 and vibrate the surface of the stress plate 19 by using an eccentric wheel 18, the screening net plate 17 filters the inside of the material, glass raw materials are poured into the inside of the tank furnace or the crucible furnace, the equipment box door 2 is then opened to take out the screening net plate 17 from the inside of the rectangular guide rail 16, and raw materials which do not conform to the size are led out.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.

Claims (6)

1. The utility model provides a glass production charging equipment, includes device casing (1), sealed apron (5), eccentric wheel (18) and atress board (19), its characterized in that: the device is characterized in that an equipment box door (2) is hinged and fixed on the outer side of a device shell (1), a liquid mixing box body (3) is welded and fixed on the outer side of the device shell (1), a driving motor (4) is attached to the outer side of the liquid mixing box body (3), a sealing cover plate (5) is installed at the top of the device shell (1), a discharge pipeline (6) penetrates through the outer side of the sealing cover plate (5), an ash filtering screen plate (7) is attached to the position right above the discharge pipeline (6), an equipment supporting plate (8) penetrates through the outer side of the device shell (1), an auxiliary wheel (9) is welded at the bottom of the equipment supporting plate (8), a conveying track (10) is arranged right below the auxiliary wheel (9), a liquid mixing sheet (11) and a rotating cylinder (12) are connected to the output end of the driving motor (4) at the same time, and a material mixing blade (13) is welded and fixed on, the left and right sides welding of compounding blade (13) has magnet piece (14), one side nested connection of rotatory section of thick bamboo (12) has face gear (15), the inside welded fastening of device casing (1) has rectangular guide rail (16), and nested connection has screening otter board (17) between rectangular guide rail (16).

2. The glass production charging apparatus of claim 1, wherein: the device shell (1) and the equipment supporting plate (8) form a sliding structure through the auxiliary wheel (9) and the plane gear (15), the surface area of the equipment supporting plate (8) is larger than that of the device shell (1), and the device shell (1) is integrally in a conical structure.

3. The glass production charging apparatus of claim 1, wherein: the liquid mixing box body (3) and the device shell (1) are connected through a gauze structure, and the device shell (1) is connected with the discharge pipeline (6) through an ash filtering screen plate (7).

4. The glass production charging apparatus of claim 1, wherein: the mixing blades (13) are annularly distributed on the outer side of the rotary cylinder (12), and the rotary cylinder (12) and the mixing blade (11) are parallel to each other.

5. The glass production charging apparatus of claim 1, wherein: the screening net plates (17) are connected with the device shell (1) through rectangular guide rails (16), the width of the rectangular guide rails (16) is half of the width of the screening net plates (17), and the number of the screening net plates (17) is two.

6. The glass production charging apparatus of claim 1, wherein: the vibration device is characterized in that the eccentric wheel (18), the stress plate (19), the device shell (1) and the driving motor (4) form a vibration structure, the output end of the driving motor (4) is connected with the eccentric wheel (18), the stress plate (19) is arranged under the eccentric wheel (18), and the stress plate (19) and the device shell (1) are welded into an integral structure.

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