CN220634199U - High-efficient loading attachment is used to prilling tower - Google Patents

Abstract

The utility model relates to the technical field of refractory ceramic material processing, and discloses a high-efficiency feeding device for a granulating tower, which comprises a granulating tower body, a feeding device and a feeding device, wherein the granulating tower body is used for granulating refractory ceramic materials; the storage tank is used for storing liquid raw materials; the material conveying pipeline is connected to the top of the prilling tower body, and one end of the material conveying pipeline extends into the storage tank. This prilling tower is with high-efficient loading attachment, when using, filter the liquid raw materials of carrying through the filtration frame on the filter equipment, prevent that the raw materials of macroparticle from being carried the inside of prilling tower body, in order to avoid influencing the quality of the particulate ceramic material that forms, when dismantling the clearance to filter equipment, drive first gear and second gear engagement transmission through twisting the turning handle, make first shielding piece and second shielding piece reverse rotation to the bottom of filtration frame, in order to avoid dismantling the clearance to filter equipment when, the attached liquid raw materials of filtration frame bottom drips subaerial.

Description

High-efficient loading attachment is used to prilling tower

Technical Field

The utility model relates to the technical field of refractory ceramic material processing, in particular to a high-efficiency feeding device for a prilling tower.

Background

The ceramic material is inorganic non-metal material prepared with natural or synthetic compound and through forming and high temperature sintering, and has high smelting point, high hardness, high wear resistance, oxidation resistance and other advantages, and may be used as structural material and cutter material.

When the granulation tower in the related art is used, generally, liquid raw materials are pumped into the granulation tower for spraying, and before the liquid raw materials are thoroughly stirred uniformly, large-particle raw materials are often doped, and when the liquid raw materials enter the granulation tower to form granular ceramic materials, the quality of the formed granular ceramic materials is easily affected.

Disclosure of Invention

The utility model aims to provide a high-efficiency feeding device for a prilling tower, so as to solve the problems in the background technology.

The embodiment of the application adopts the following technical scheme:

the high-efficiency feeding device for the granulating tower comprises a granulating tower body and a feeding device, wherein the granulating tower body is used for granulating refractory ceramic materials; the storage tank is used for storing liquid raw materials; the material conveying pipeline is connected to the top of the prilling tower body, one end of the material conveying pipeline extends into the material storage tank, and liquid raw materials in the material storage tank can be conveyed into the prilling tower body; the filtering mechanism is connected to the material conveying pipeline and used for blocking large-particle raw materials from entering the granulating tower body, the filtering mechanism comprises a filtering frame and a shielding assembly arranged outside the filtering frame, the filtering frame can block the large-particle raw materials, the shielding assembly comprises a first shielding sheet and a second shielding sheet, and the first shielding sheet and the second shielding sheet can reversely rotate below the filtering frame; and the recovery mechanism is connected to the top of the prilling tower body and is used for collecting powdery raw materials formed by spraying liquid raw materials in the prilling tower body.

Preferably, the filtering mechanism further comprises a mounting frame, a communication hole is formed in the top of the mounting frame, and the filtering frame and the shielding assembly are both connected to the inner side of the communication hole.

Preferably, the first shielding piece is connected with a rotating handle, the rotating handle is rotationally connected with the filtering frame, the rotating handle is connected with a first gear, the second shielding piece is connected with a rotating shaft, the rotating shaft is rotationally connected with the filtering frame, a second gear is connected in the rotating shaft, and the second gear is meshed with the first gear.

Preferably, the left side of installing frame is connected with spacing slider, the right side of installing frame is provided with spacing spout, spacing spout corresponds the setting with spacing slider.

Preferably, the conveying pipeline comprises a first section, a mounting box and a second section which are sequentially connected from top to bottom.

Preferably, the left side of installation box is provided with the installing port, filtering mechanism peg graft in the installing port, the bottom of second section stretches into in the storage tank.

Preferably, the recovery mechanism comprises a recovery pipe and a fan connected in the recovery pipe.

Preferably, a drawing groove is formed in the right side of the mounting frame.

The beneficial effects of the utility model are as follows:

when using, filter the liquid raw materials of carrying through the filter frame on the filter equipment, prevent that the raw materials of macroparticle from being carried the inside of prilling tower body, in order to avoid influencing the quality of the particulate ceramic material that forms, when dismantling the clearance to filter equipment, drive first gear and second gear meshing transmission through twisting the turning handle, make first shielding piece and second shielding piece reverse rotation to the bottom of filter frame, in order to avoid dismantling the clearance to filter equipment when, the subaerial liquid raw materials drip of filter frame bottom adhesion.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It will be apparent to those skilled in the art from this disclosure that the drawings described below are merely exemplary and that other embodiments may be derived from the drawings provided without undue effort.

The structures, proportions, sizes, etc. shown in the present specification are shown only for the purposes of illustration and description, and are not intended to limit the scope of the utility model, which is defined by the claims, so that any structural modifications, changes in proportions, or adjustments of sizes, which do not affect the efficacy or the achievement of the present utility model, should fall within the ambit of the technical disclosure.

FIG. 1 is a schematic perspective view of the present utility model;

FIG. 2 is an enlarged schematic view of the structure of FIG. 1A according to the present utility model;

FIG. 3 is a schematic perspective view of a filter mechanism according to the present utility model;

FIG. 4 is a schematic side perspective view of the filter mechanism of the present utility model;

fig. 5 is a schematic view of a part of a cross-sectional structure of a filtering mechanism of the present utility model.

In the figure: 1. a prilling tower body; 2. a storage tank; 3. a material conveying pipeline; 31. a first section; 32. a mounting box; 33. a second section; 4. a filtering mechanism; 41. a mounting frame; 42. a communication hole; 43. a limit sliding block; 44. limiting sliding grooves; 45. a filter frame; 46. a shielding assembly; 461. a first shielding sheet; 462. a rotating handle; 463. a first gear; 464. a second shielding sheet; 465. a rotating shaft; 466. a second gear; 47. an opening; 48. a drawing groove; 5. a recovery mechanism; 51. a recovery pipe; 52. a blower.

Detailed Description

The following describes the embodiments of the present utility model further with reference to the drawings.

As shown in fig. 1 to 5, the high-efficiency feeding device for the prilling tower; including the prilling tower body 1 for carry out the granulation to refractory ceramic material, the front side of prilling tower body 1 is provided with storage tank 2 for store liquid raw materials, be connected with conveying pipeline 3 on the prilling tower body 1, in the one end of conveying pipeline 3 stretches into storage tank 2, can carry the liquid raw materials in the storage tank 2 to prilling tower body 1 in, install filter mechanism 4 on the conveying pipeline 3, be used for filtering the liquid raw materials of carrying, still be connected with recovery mechanism 5 on the prilling tower body 1, be used for collecting the liquid raw materials and spray the powdered raw materials of formation in prilling tower body 1, in order to follow-up to shaping granule ceramic material's screening.

As shown in fig. 1, the top of the prilling tower body 1 is connected with a material conveying pipeline 3 and a recovery mechanism 5 (the prilling tower body 1 is in the prior art, and is not described in detail herein), the material conveying pipeline 3 includes a first section 31, a mounting box 32 and a second section 33, which are sequentially connected from top to bottom, the first section 31 is connected with the prilling tower body 1, the bottom end of the second section 33 extends into the material storage tank 2, a pump is connected to the first section 31, power is provided for the material conveying pipeline 3 to pump liquid raw materials (not shown in the figure), the recovery mechanism 5 includes a recovery pipeline 51 connected to the prilling tower body 1, the bottom end of the recovery pipeline 51 extends into the material storage tank 2, and a fan 52 is connected to the inside of the recovery pipeline 51.

The pumping pump is started, the liquid raw materials stored in the storage tank 2 can be conveyed to the prilling tower body 1 through the conveying pipeline 3 and sprayed, so that granular refractory ceramic materials are formed, the fan 52 is started, the powdery wear-resistant ceramic materials formed by spraying the liquid raw materials are conveyed to the storage tank 2 again, meanwhile, gas is introduced into the liquid raw materials in the storage tank 2 to form bubbles, the liquid raw materials stored in the storage tank 2 are stirred through the cracking of the bubbles, and the liquid raw materials are prevented from precipitating.

As shown in fig. 1-5, the left and right sides of the installation box 32 are provided with an installation opening, the filter mechanism 4 comprises an installation frame 41 inserted in the installation box 32, the top of the installation frame 41 is provided with a communication hole 42, the communication hole 42 is respectively communicated with the first section 31 and the second section 33, the left side of the installation frame 41 is connected with a limit sliding block 43, the right side of the installation frame 41 is provided with a limit sliding groove 44, an opening 47 and a drawing groove 48, the limit sliding groove 44 is correspondingly arranged with the limit sliding block 43, the filter mechanism 4 is pulled through the drawing groove 48, the connection between the two filter mechanisms 4 is facilitated through the limit sliding groove 44 and the limit sliding block 43, the inner side of the communication hole 42 is connected with a filter frame 45, the outer side of the filter frame 45 is connected with a shielding assembly 46, the shielding assembly 46 comprises a first shielding piece 461 and a second shielding piece 464 which are arranged at the outer side of the filter frame 45, the front end of the first shielding piece 461 and the second shielding piece 464 are arc-shaped, the front end of the first shielding piece 461 is connected with a rotating handle 462, the rotating handle 462 is connected to the filter frame 45, the front end 464 is positioned in the shielding opening 47 so as to be convenient for pulling the filter mechanism 4, the inner side of the filter mechanism 45 is convenient to be connected with a first rotating shaft 463, the rotating shaft 465 is meshed with a second rotating shaft 463, and a rotating shaft 465 is connected to a rotating shaft 465.

The large-particle raw material in the liquid raw material is filtered by the filter frame 45 to avoid affecting the quality of the formed granular ceramic material.

The turning handle 462 is screwed to drive the first gear 463 and the second gear 466 to engage and drive, so that the first shielding piece 461 and the second shielding piece 464 reversely rotate to the bottom of the filter frame 45, and liquid raw material attached to the bottom of the filter frame 45 is prevented from dripping on the ground when the filter mechanism 4 is disassembled and cleaned.

Working principle: the pumping pump is started, the liquid raw materials stored in the storage tank 2 can be conveyed to the prilling tower body 1 through the conveying pipeline 3 and sprayed, so that granular refractory ceramic materials are formed, when the liquid raw materials pass through the filtering mechanism 4, large granular raw materials in the liquid raw materials are filtered through the filtering frame 45, when the filtering mechanism 4 is disassembled and cleaned, the rotating handle 462 is screwed to drive the first gear 463 and the second gear 466 to be meshed and driven, the first shielding piece 461 and the second shielding piece 464 are reversely rotated to the bottom of the filtering frame 45, the liquid raw materials dropped from the bottom of the filtering frame 45 fall to the inner sides of the first shielding piece 461 and the second shielding piece 464, the filtering mechanism 4 is pushed at the moment, the filtering mechanism 4 is separated from the mounting box 32, the fan 52 is started, so that powdery wear-resistant ceramic materials formed by spraying the liquid raw materials are conveyed into the storage tank 2 again, meanwhile, air bubbles are formed in the liquid raw materials in the storage tank 2, and the liquid raw materials stored in the storage tank 2 are stirred through the breakage of the air bubbles.

Claims (8)

1. High-efficient loading attachment is used to prilling tower, its characterized in that includes:

the granulation tower body (1) is used for granulating the refractory ceramic material;

a storage tank (2) for storing a liquid raw material;

the material conveying pipeline (3) is connected to the top of the prilling tower body (1), one end of the material conveying pipeline (3) stretches into the material storage tank (2), and liquid raw materials in the material storage tank (2) can be conveyed into the prilling tower body (1);

the filtering mechanism (4) is connected to the conveying pipeline (3) and used for blocking large-particle raw materials from entering the granulating tower body (1), the filtering mechanism (4) comprises a filtering frame (45) and a shielding assembly (46) arranged outside the filtering frame (45), the filtering frame (45) can block the large-particle raw materials, the shielding assembly (46) comprises a first shielding sheet (461) and a second shielding sheet (464), and the first shielding sheet (461) and the second shielding sheet (464) can reversely rotate to the lower part of the filtering frame (45);

and the recovery mechanism (5) is connected to the top of the prilling tower body (1) and is used for collecting powdery raw materials formed by spraying liquid raw materials in the prilling tower body (1).

2. The efficient loading device for a prilling tower according to claim 1, wherein: the filtering mechanism (4) further comprises a mounting frame (41), a communication hole (42) is formed in the top of the mounting frame (41), and the filtering frame (45) and the shielding assembly (46) are both connected to the inner side of the communication hole (42).

3. The efficient loading device for a prilling tower according to claim 1, wherein: be connected with on first shielding piece (461) and rotate handle (462), rotate handle (462) and filter frame (45) and be connected with first gear (463) on rotating handle (462), be connected with pivot (465) on second shielding piece (464), pivot (465) are connected with filter frame (45) rotation, be connected with second gear (466) on pivot (465), meshing connection between second gear (466) and first gear (463).

4. The efficient feeding device for a prilling tower according to claim 2, wherein: the left side of installing frame (41) is connected with spacing slider (43), the right side of installing frame (41) is provided with spacing spout (44), spacing spout (44) correspond setting with spacing slider (43).

5. The efficient loading device for a prilling tower according to claim 1, wherein: the material conveying pipeline (3) comprises a first section (31), an installation box (32) and a second section (33) which are sequentially connected from top to bottom.

6. The efficient loading device for the prilling tower according to claim 5, wherein: the left side of installation box (32) is provided with the installing port, filtering mechanism (4) are pegged graft in the installing port, the bottom of second section (33) stretches into in storage tank (2).

7. The efficient loading device for a prilling tower according to claim 1, wherein: the recovery mechanism (5) comprises a recovery pipeline (51) and a fan (52) connected in the recovery pipeline (51).

8. The efficient feeding device for a prilling tower according to claim 2, wherein: the right side of the mounting frame (41) is provided with a drawing groove (48).