CN216460028U - Raw material distribution device for production of continuous casting crystallizer casting powder - Google Patents

Abstract

The utility model relates to the technical field of inorganic non-metallic materials, in particular to a raw material distribution device for the production of continuous casting crystallizer casting powder, which comprises a raw material tank, a feeding pipe and a material pusher; the head tank is used for storing and screening the raw materials, and the filling tube is used for the transfer of raw materials, and the stoker is used for promoting the ejection of compact to two feed openings with the transfer raw materials in the filling tube. The utility model discloses the head tank is used for storing and screening the raw materials, and the filling tube is used for the transfer of raw materials, and the stoker is used for promoting the ejection of compact to two feed openings with the transfer raw materials in the filling tube, and the screening has been accomplished before the export of raw materials tank comes out to the raw materials, piles up the raw materials in to the filling tube through inferior screen cloth, can make the raw materials dispersion fall, and the distribution is loose, does not agglomerate, promotes more easily. The material pushing device starts from the middle and moves once to two ends respectively, so that the material distributing work of two material feeding ports can be finished, manual feeding is not needed, and the efficiency is obviously improved.

Description

Raw material distribution device for production of continuous casting crystallizer casting powder

Technical Field

The utility model relates to the technical field of inorganic non-metallic material, in particular to a raw material distribution device for the production of continuous casting crystallizer covering slag.

Background

In the production process of the covering slag of the continuous casting crystallizer, raw material particles need to be crushed to a certain granularity and then quantitatively added into a reactor for processing such as mixing, and when a multi-line reactor is produced simultaneously, if the reactor is manually fed one by one, time and labor are wasted.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, the utility model discloses a raw material distribution device for production of continuous casting crystallizer covering slag.

The specific technical scheme is as follows:

a raw material distribution device for the production of continuous casting crystallizer casting powder comprises a raw material tank, a feeding pipe and a material pusher; the middle part of the raw material tank is detachably provided with a primary screen, the bottom outlet is square, a through hole is formed in the left and right directions for installing a secondary screen, and a vibrator is arranged outside the raw material tank; the feeding pipe is a horizontal square pipe, one end of the feeding pipe is closed, the other end of the feeding pipe is provided with a horizontal jack, a middle vertical opening is communicated with an outlet of the raw material tank, and a feed opening A and a feed opening B are respectively arranged after two vacant positions are reserved at two ends of the feeding pipe; the material pushing device comprises a solid block, a hollow block and a solid block which are sequentially and integrally connected from left to right, the solid block is a cubic block with six closed surfaces, the hollow block is a U-shaped cube with a left surface, a right surface and a lower surface opened and a hollow upper surface, the left surface and the right surface of the hollow block are respectively fixed with the solid blocks on two sides, a horizontal connecting rod is fixed by one solid block, and the connecting rod penetrates out of the jack and then is connected with the handle.

The secondary screen comprises two square frames which are integrally connected left and right, the length of each frame is 1/2 of the width of the outlet of the raw material tank, the height of each frame is equal to the height of the outlet through hole, and the projection of each frame in the vertical direction just covers the outlet; the upper surface of the left side frame is a horizontal baffle plate, the right side frame is provided with an inclined sieve plate along the diagonal direction, and the sieve plate is provided with meshes and is smaller than the mesh size of the primary sieve.

And the left end and the right end of the two frames are respectively processed with a limiting strip up and down and are clamped at the two ends of the through hole of the outlet.

One side of the two frames is provided with a handle.

The bottom surface area and the height of the solid block are respectively equal to the bottom surface area and the height of the vacant position.

The hollow area on the hollow block is larger than the cross section area of the outlet and can cover the cross section of the outlet.

Compared with the prior art, the utility model discloses following beneficial technological effect has:

the utility model discloses the head tank is used for storing and screening the raw materials, and the filling tube is used for the transfer of raw materials, and the stoker is used for promoting the ejection of compact to two feed openings with the transfer raw materials in the filling tube, and the screening has been accomplished before the export of head tank comes out to the raw materials, piles up the raw materials in to the filling tube through inferior screen cloth, can make the raw materials dispersion fall, and the distribution is loose, does not agglomerate, promotes more easily. The material pushing device starts from the middle and moves once to two ends respectively, so that the material distributing work of two material feeding ports can be finished, manual feeding is not needed, and the efficiency is obviously improved.

Drawings

FIG. 1 is a schematic structural view of a raw material distribution device of the present invention;

FIG. 2 is a schematic view of the raw material tank of the present invention;

FIG. 3 is a schematic view of the three-dimensional structure of the secondary screen of the present invention;

FIG. 4 is a schematic view of the plane structure of the secondary screen of the present invention;

FIG. 5 is a schematic view of the three-dimensional structure of the material pusher of the present invention;

FIG. 6 is a schematic view of the material stacking operation of the material distribution device of the present invention;

FIG. 7 is a schematic diagram of the material pushing and distributing operation of the feed opening A of the material distributing device of the present invention;

fig. 8 is the material distribution working diagram of the feed opening B of the material distribution device of the present invention.

In the figure, 1, a raw material tank; 2. a primary screen mesh; 3. a secondary screen; 4. a vibrator; 5. an outlet; 6. a feed tube; 7. a pusher; 8. a connecting rod; 9. a handle; 10. a feed opening A; 11. a feed opening B; 12. a baffle plate; 13. a sieve plate; 14. a limiting strip; 15. a handle; 16. compacting; 17. empty blocks; 18. raw materials; 19. a jack; 20. a vacancy.

Detailed Description

The present invention is further described with reference to the accompanying drawings, but the scope of the present invention is not limited by the accompanying drawings.

Fig. 1 is the utility model discloses raw materials distributor structure schematic diagram, fig. 2 is the utility model discloses raw material tank structure schematic diagram, fig. 3 is the utility model discloses inferior screen cloth spatial structure schematic diagram, fig. 4 is the utility model discloses inferior screen cloth planar structure schematic diagram, fig. 5 is the utility model discloses ejector three-dimensional structure schematic diagram, as shown in the figure: the utility model discloses a raw material distribution device for the production of continuous casting crystallizer covering slag, which comprises a raw material tank 1, a feeding pipe 6 and a material pusher 7; a primary screen 2 is detachably mounted in the middle of the raw material tank 1, an outlet 5 at the bottom is square, a secondary screen 3 is mounted in a through hole formed in the left and right direction, and a vibrator 4 is mounted outside the raw material tank 1; the feeding pipe 6 is a horizontal square pipe, one end of the feeding pipe is closed, the other end of the feeding pipe is provided with a horizontal jack 19, a middle vertical opening is communicated with the outlet 5 of the raw material tank 1, and a feed opening A10 and a feed opening B11 are respectively arranged after a vacancy 20 is reserved at each of the two ends of the feeding pipe; the material pushing device 7 comprises a solid block 16, an empty block 17 and a solid block 16 which are sequentially and integrally connected from left to right, the solid block 16 is a cubic block with six closed sides, the empty block 17 is a U-shaped cube with a left side, a right side and a lower side open and a hollow upper side, the left side and the right side of the empty block 17 are respectively fixed with the solid blocks 16 on two sides, a horizontal connecting rod 8 is fixed by one solid block 16, and the connecting rod 8 penetrates out of an insertion hole 19 and then is connected with a handle 9.

The secondary screen 3 comprises two square frames which are integrally connected left and right, the length of each frame is 1/2 of the width of the outlet 5 of the raw material tank 1, the height of each frame is equal to the height of a through hole of the outlet 5, and the projection of each frame in the vertical direction just covers the outlet 5; the upper surface of the left side frame is a horizontal baffle 12, the right side frame is provided with an inclined sieve plate 13 along the diagonal direction, and the sieve plate 13 is provided with meshes and is smaller than the mesh size of the primary sieve 2.

The left end and the right end of the two frames are respectively processed with a limiting strip 14 up and down which are clamped at the two ends of the through hole of the outlet 5. One of the two frames is provided with a handle 15 on one side. The bottom surface area and height of the solid block 16 are equal to the bottom surface area and height of the void 20, respectively. The hollow area above the hollow block 17 is larger than the cross-sectional area of the outlet 5 and can cover the cross-section of the outlet 5.

When in use, the method comprises the following steps:

(1) stockpile

Firstly, the pusher 7 is pushed to the middle part of the feeding pipe 6, so that the empty block 17 is positioned under the outlet 5, the handle 15 is pushed, and the baffle plate 12 of the secondary screen 3 is pushed to correspond to the outlet. Adding a raw material 18 into the raw material tank 1, starting the vibrator 4, then vibrating and screening the raw material 18 on the primary screen 2, leaving large particles on the primary screen 2, and allowing small particles to flow to a baffle plate at an outlet through the primary screen 2; at this time, the pull handle 15 is pulled to pull the sieve plate 13 of the secondary sieve 3 to correspond to the outlet, and the sieved raw material 18 gradually falls from the sieve plate 13 into the hollow top surface of the empty block 17 and is accumulated at the bottom of the empty block 17, as shown in fig. 6.

(2) Pushing material

When the material needs to be pushed to the feed opening A: pulling the handle 9, the solid block 17 of the pusher 7 pushes the raw material accumulated at the bottom of the hollow block 17 to move to the feeding opening a until the solid block 17 at the other side is pushed into the vacant position 20, and the raw material at the bottom of the hollow block 17 just reaches the feeding opening a to flow out, as shown in fig. 7.

When pushing materials to the feed opening B is required: similarly, the handle 9 is pushed, the solid block 17 of the pusher 7 pushes the raw material accumulated at the bottom of the hollow block 17 to move to the discharge port B until the solid block 17 at the other side pushes the empty position 20, and the raw material at the bottom of the hollow block 17 just reaches the discharge port B to flow out, as shown in fig. 8.

Claims (6)

1. A raw material distribution device for producing continuous casting crystallizer casting powder is characterized in that: comprises a raw material tank (1), a feeding pipe (6) and a pusher (7); the middle part of the raw material tank (1) is detachably provided with a primary screen (2), a bottom outlet (5) is square, a through hole is formed in the left direction and the right direction to install a secondary screen (3), and a vibrator (4) is arranged outside the raw material tank (1); the feeding pipe (6) is a horizontal square pipe, one end of the feeding pipe is closed, the other end of the feeding pipe is provided with a horizontal jack (19), a middle vertical opening is communicated with an outlet (5) of the raw material tank (1), and a feed opening A (10) and a feed opening B (11) are respectively arranged after a vacancy (20) is reserved at each of the two ends of the feeding pipe; the material pushing device (7) comprises a solid block (16), an empty block (17) and a solid block (16) which are sequentially and integrally connected from left to middle and right, the solid block (16) is a cubic block with six closed sides, the empty block (17) is a hollow U-shaped cube with a left side, a right side and a lower side open and an upper side, the left side and the right side of the empty block (17) are respectively fixed with the solid blocks (16) on two sides, a horizontal connecting rod (8) is fixed by the solid block (16), and the connecting rod (8) penetrates out of an inserting hole (19) and then is connected with a handle (9).

2. The raw material distribution device for the production of mold flux of a continuous casting crystallizer as set forth in claim 1, wherein: the secondary screen (3) comprises two square frames which are integrally connected left and right, the length of each frame is 1/2 of the width of the outlet (5) of the raw material tank (1), the height of each frame is equal to the height of a through hole of the outlet (5), and the projection of each frame in the vertical direction just covers the outlet (5); the upper surface of the left side frame is a horizontal baffle (12), the right side frame is provided with an inclined sieve plate (13) along the diagonal direction, the sieve plate (13) is provided with a sieve mesh, and the mesh size of the sieve mesh is smaller than that of the primary sieve mesh (2).

3. The raw material distribution device for the production of mold flux of a continuous casting crystallizer as set forth in claim 2, wherein: the left end and the right end of the two frames are respectively processed with a limiting strip (14) up and down which are clamped at the two ends of the through hole of the outlet (5).

4. The raw material distribution device for the production of mold flux of a continuous casting crystallizer as set forth in claim 2, wherein: one side of the two frames is provided with a handle (15).

5. The raw material distribution device for the production of mold flux of a continuous casting crystallizer as set forth in claim 1, wherein: the bottom surface area and the height of the solid block (16) are respectively equal to the bottom surface area and the height of the vacant position (20).

6. The raw material distribution device for the production of mold flux of a continuous casting crystallizer as set forth in claim 1, wherein: the hollow area on the hollow block (17) is larger than the cross section area of the outlet (5) and can cover the cross section of the outlet (5).

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