CN219560373U - Hierarchical formula granule screening preparation structure - Google Patents

Abstract

The utility model relates to the technical field of vitamin processing, and particularly discloses a hierarchical particle screening preparation structure which comprises an inner screening filter cylinder, an outer screening filter cylinder and two groups of side supporting seats; the outer screen filter cylinder is sleeved on the outer side of the inner screen filter cylinder, the inner screen filter cylinder is connected with a connecting frame for fixing the outer screen filter cylinder, a first stabilizing seat for supporting the inner screen filter cylinder to stably rotate and a second stabilizing seat for supporting the outer screen filter cylinder to stably rotate are connected between the two groups of side supporting seats, a rack is arranged at a discharge hole of the first stabilizing seat, and a driving mechanism for driving the inner screen filter cylinder to rotate is arranged on the rack; according to the utility model, the inner screen filter cylinder and the outer screen filter cylinder are matched, the inner screen filter cylinder and the outer screen filter cylinder can rotate, so that the materials can be effectively screened and filtered, and meanwhile, the sieve plate can be used for further screening and filtering, so that the materials are subjected to multi-stage screening and filtering, the particle screening effect is improved, and the preparation of vitamin particle finished products is facilitated.

Description

Hierarchical formula granule screening preparation structure

Technical Field

The utility model relates to the technical field of vitamin processing, in particular to a hierarchical particle screening preparation structure.

Background

After the vitamin raw material is processed into particles, the particles are required to be screened and filtered, the particles are classified, fine impurities are removed, and corresponding screening equipment and the like are required to be used.

Among the screening grading plant is used in production of current patent publication No. CN212397244U, including the box, the feeder hopper, dust absorption mechanism and shale shaker filter mechanism, the feeder hopper is installed in the penetration on the roof of box, dust absorption mechanism is installed to the outer wall of a curb plate of box, install the shale shaker in the box and strain the mechanism, it has first discharge gate and second discharge gate to open respectively on two curb plates that the box corresponds each other, all install vibrating motor on first screen plate and the second screen plate, its vibration intensity is high, guaranteed the effect of straining, and the ejection of compact direction of first screen plate and second screen plate is opposite, the going on of the ejection of compact after straining has been made things convenient for the screen greatly.

Among the above-mentioned screening grading plant, can carry out the screening of classifying through first screen plate and second screen plate, but when using, the material is direct to drop through first screen plate and second screen plate, and the pay-off is more when, is difficult for carrying out effectual screening, needs to improve. Aiming at the problems, a hierarchical particle screening preparation structure is provided.

Disclosure of Invention

The utility model aims to provide a hierarchical particle screening preparation structure so as to solve the problems in the background art.

In order to achieve the above purpose, the present utility model provides the following technical solutions:

a hierarchical granule screening preparation structure comprises an inner screening filter cylinder, an outer screening filter cylinder and two groups of side supporting seats;

the outer screen filter cylinder is sleeved on the outer side of the inner screen filter cylinder, the inner screen filter cylinder is connected with a connecting frame for fixing the outer screen filter cylinder, a first stabilizing seat for supporting the inner screen filter cylinder to stably rotate and a second stabilizing seat for supporting the outer screen filter cylinder to stably rotate are connected between the two groups of side supporting seats, a rack is arranged at a discharge hole of the first stabilizing seat, and a driving mechanism for driving the inner screen filter cylinder to rotate is arranged on the rack;

the bottom of the outer screen filter cylinder is provided with a screen plate which is inclined towards the feeding port of the inner screen filter cylinder.

In one alternative: the driving mechanism comprises driving equipment arranged on the frame, a fixing frame is arranged at the discharge port of the inner screen filter cylinder, the power output end of the driving equipment is connected with an output shaft, and one end, far away from the driving equipment, of the output shaft is connected with the shaft end of the fixing frame.

In one alternative: the axes of the inner screen filter cylinder and the outer screen filter cylinder are coincident, and the inner screen filter cylinder and the outer screen filter cylinder are inclined to one side close to the frame.

In one alternative: the length of the outer screening filter cylinder is smaller than that of the inner screening filter cylinder, a guide plate arranged on the frame is arranged at the discharge hole of the inner screening filter cylinder, a first receiving box is arranged at the discharge end of the guide plate, the inner wall of the guide plate is in sliding fit with the outer wall of the end part of the inner screening filter cylinder, and a second receiving box is arranged at the discharge end of the outer screening filter cylinder.

In one alternative: and a third material receiving box is arranged at the bottom of the sieve plate.

In one alternative: the top of the first stabilizing seat is provided with a first arc-shaped groove, and the first arc-shaped groove is in running fit with the outer wall of one end of the inner screen filter cylinder.

In one alternative: the top of the second stabilizing seat is provided with a second arc-shaped groove, the second arc-shaped groove is in running fit with the outer wall of one end of the outer screen filter cylinder, and the first stabilizing seat and the second stabilizing seat are arranged in parallel.

In one alternative: the inner sieve filter cylinder comprises a first arc-shaped groove, a second arc-shaped groove and a second arc-shaped groove, wherein a first limit groove is arranged in the first arc-shaped groove, a first limit ring matched with the first limit groove is connected to the outer wall of the end part of the inner sieve filter cylinder, and a second limit ring matched with the second limit groove is connected to the outer wall of the end part of the outer sieve filter cylinder.

Compared with the prior art, the utility model has the beneficial effects that:

according to the utility model, the inner screen filter cylinder and the outer screen filter cylinder are matched, the inner screen filter cylinder and the outer screen filter cylinder can rotate, so that the materials can be effectively screened and filtered, and meanwhile, the sieve plate can be used for further screening and filtering, so that the materials are subjected to multi-stage screening and filtering, the particle screening effect is improved, and the preparation of vitamin particle finished products is facilitated;

according to the utility model, one end of the inner screen filter cylinder is convenient for feeding, and the discharge ports of the inner screen filter cylinder and the outer screen filter cylinder are convenient for receiving materials, so that the particle collection of different size grades is facilitated.

Drawings

Fig. 1 is a schematic structural view of the present utility model.

Fig. 2 is a schematic structural view of a rack according to the present utility model.

Fig. 3 is a schematic view of the structure of the inner and outer screen cartridges of the present utility model.

Fig. 4 is a schematic cross-sectional view of the present utility model.

In the figure: 11. a side support base; 12. a first stabilizing seat; 13. an inner screen filter cartridge; 14. an outer screen cartridge; 15. a sieve plate; 16. a third receiving box; 17. a second stabilizing seat; 18. a driving device; 19. a frame; 20. a first receiving box; 21. a material guide plate; 22. a second receiving box; 23. a connecting frame; 24. and a fixing frame.

Detailed Description

Examples

Referring to fig. 1-4, in an embodiment of the present utility model, a hierarchical particle screening preparation structure includes an inner screening cartridge 13, an outer screening cartridge 14, and two sets of side support seats 11;

the outer screen filter cylinder 14 is sleeved on the outer side of the inner screen filter cylinder 13, the inner screen filter cylinder 13 is connected with a connecting frame 23 for fixing the outer screen filter cylinder 14, a first stabilizing seat 12 for supporting the inner screen filter cylinder 13 to stably rotate and a second stabilizing seat 17 for supporting the outer screen filter cylinder 14 to stably rotate are connected between the two groups of side supporting seats 11, a rack 19 is arranged at a discharge hole of the first stabilizing seat 12, and a driving mechanism for driving the inner screen filter cylinder 13 to rotate is arranged on the rack 19;

the inner screen filter cylinder 13 and the outer screen filter cylinder 14 can synchronously rotate, and the materials filtered by the inner screen filter cylinder 13 enter the outer screen filter cylinder 14 for filtration;

the bottom of the outer screen filter cylinder 14 is provided with a screen plate 15 which is inclined towards the feed inlet of the inner screen filter cylinder 13; the material filtered by the outer screen cartridge 14 enters the screen plate 15 for filtration.

The driving mechanism comprises a driving device 18 arranged on a frame 19, wherein the driving device 18 can be the matching of the existing gear motor and a coupling; a fixed frame 24 is arranged at the discharge port of the inner screen filter cylinder 13, the power output end of the driving equipment 18 is connected with an output shaft, and one end of the output shaft far away from the driving equipment 18 is connected with the shaft end of the fixed frame 24; the driving device 18 can drive the output shaft to rotate, so that the fixing frame 24 drives the inner screen filter cylinder 13 to rotate, and the inner screen filter cylinder 13 drives the outer screen filter cylinder 14 to rotate.

The axes of the inner screen filter cylinder 13 and the outer screen filter cylinder 14 are coincident, and the inner screen filter cylinder 13 and the outer screen filter cylinder 14 are inclined to one side close to the frame 19; the materials in the inner screen cartridge 13 and the outer screen cartridge 14 are output to a side close to the frame 19.

The length of the outer screening filter cylinder 14 is smaller than that of the inner screening filter cylinder 13, a material guide plate 21 mounted on a frame 19 is arranged at the discharge port of the inner screening filter cylinder 13, a first material receiving box 20 is arranged at the discharge end of the material guide plate 21, and the first material receiving box 20 is used for collecting materials in the inner screening filter cylinder 13; the inner wall of the guide plate 21 is in sliding fit with the outer wall of the end part of the inner screen filter cylinder 13, a second material receiving box 22 is arranged at the discharge end of the outer screen filter cylinder 14, and the second material receiving box 22 is used for collecting materials in the outer screen filter cylinder 14.

The third material receiving box 16 is arranged at the bottom of the screen plate 15, the third material receiving box 16 collects materials leaked from the bottom of the screen plate 15, and the corresponding material receiving box can be arranged at the discharge end of the screen plate 15.

The top of the first stabilizing seat 12 is provided with a first arc-shaped groove, the first arc-shaped groove is in running fit with the outer wall of one end of the inner screen filter cylinder 13, and the first stabilizing seat 12 supports the inner screen filter cylinder 13 to stably rotate.

The top of the second stabilizing seat 17 is provided with a second arc-shaped groove, the second arc-shaped groove is in running fit with the outer wall of one end of the outer screen filter cylinder 14, and the first stabilizing seat 12 and the second stabilizing seat 17 are arranged in parallel; the second stabilizing seat 17 supports the outer screen cartridge 14 for stable rotation.

In this embodiment, the feeding hole of the inner screen filter cylinder 13 can be used for feeding materials, the driving device 18 can drive the output shaft to rotate, so that the fixing frame 24 drives the inner screen filter cylinder 13 to rotate, the inner screen filter cylinder 13 drives the outer screen filter cylinder 14 to rotate, materials filtered by the inner screen filter cylinder 13 enter the outer screen filter cylinder 14 to be filtered, the first material receiving box 20 collects materials in the inner screen filter cylinder 13, the second material receiving box 22 collects materials in the outer screen filter cylinder 14, materials filtered by the outer screen filter cylinder 14 enter the screen plate 15 to be filtered, the third material receiving box 16 collects materials leaked from the bottom of the screen plate 15, corresponding material receiving boxes can be distributed at the discharge end of the screen plate 15, and the materials are subjected to multi-stage screening and filtering, so that particle collection with different size grades is facilitated.

Examples

Different from the embodiment 1, a first limit groove is arranged in the first arc-shaped groove, a first limit ring matched with the first limit groove is connected to the outer wall of the end part of the inner screen filter cylinder 13, a second limit groove is arranged in the second arc-shaped groove, and a second limit ring matched with the second limit groove is connected to the outer wall of the end part of the outer screen filter cylinder 14;

in this embodiment, the first and second stop rings may act as stops to reduce axial displacement of the inner and outer screen cartridges 13, 14.

Claims (8)

1. A hierarchical particle screening preparation structure comprises an inner screening filter cylinder (13), an outer screening filter cylinder (14) and two groups of side supporting seats (11);

the method is characterized in that: the outer screen filter cylinder (14) is sleeved on the outer side of the inner screen filter cylinder (13), the inner screen filter cylinder (13) is connected with a connecting frame (23) for fixing the outer screen filter cylinder (14), a first stabilizing seat (12) for supporting the inner screen filter cylinder (13) to stably rotate and a second stabilizing seat (17) for supporting the outer screen filter cylinder (14) to stably rotate are connected between the two groups of side supporting seats (11), a rack (19) is arranged at a discharge hole of the first stabilizing seat (12), and a driving mechanism for driving the inner screen filter cylinder (13) to rotate is arranged on the rack (19);

the bottom of the outer screen filter cylinder (14) is provided with a screen plate (15) inclined towards the feed inlet of the inner screen filter cylinder (13).

2. A hierarchical particle screening preparation structure according to claim 1, characterized in that: the driving mechanism comprises driving equipment (18) arranged on a frame (19), a fixing frame (24) is arranged at the discharge hole of the inner screen filter cylinder (13), the power output end of the driving equipment (18) is connected with an output shaft, and one end, far away from the driving equipment (18), of the output shaft is connected with the shaft end of the fixing frame (24).

3. A hierarchical particle screening preparation structure according to claim 1, characterized in that: the axes of the inner screen filter cylinder (13) and the outer screen filter cylinder (14) are coincident, and the inner screen filter cylinder (13) and the outer screen filter cylinder (14) are inclined to one side close to the frame (19).

4. A hierarchical particle screening preparation structure according to claim 1, characterized in that: the length of the outer screening filter cylinder (14) is smaller than that of the inner screening filter cylinder (13), a material guide plate (21) mounted on a frame (19) is arranged at the discharge hole of the inner screening filter cylinder (13), a first material receiving box (20) is arranged at the discharge end of the material guide plate (21), the inner wall of the material guide plate (21) is in sliding fit with the outer wall of the end part of the inner screening filter cylinder (13), and a second material receiving box (22) is arranged at the discharge end of the outer screening filter cylinder (14).

5. A hierarchical particle screening preparation structure according to claim 1, characterized in that: the bottom of the sieve plate (15) is provided with a third material receiving box (16).

6. A hierarchical particle screening preparation structure according to claim 1, characterized in that: the top of the first stabilizing seat (12) is provided with a first arc-shaped groove, and the first arc-shaped groove is in running fit with the outer wall of one end of the inner screen filter cylinder (13).

7. The hierarchical structure for preparing particle screening according to claim 6, wherein: the top of the second stabilizing seat (17) is provided with a second arc-shaped groove, the second arc-shaped groove is in running fit with the outer wall of one end of the outer screen filter cylinder (14), and the first stabilizing seat (12) and the second stabilizing seat (17) are arranged in parallel.

8. The hierarchical structure for preparing particle screening according to claim 7, wherein: the inner sieve filter is characterized in that a first limit groove is formed in the first arc groove, a first limit ring matched with the first limit groove is connected to the outer wall of the end part of the inner sieve filter cylinder (13), a second limit groove is formed in the second arc groove, and a second limit ring matched with the second limit groove is connected to the outer wall of the end part of the outer sieve filter cylinder (14).