CN216779436U - Sorbitol particulate material screening and feeding device - Google Patents

Abstract

The utility model provides a screening and feeding device for sorbitol granular materials, belongs to the technical field of solid sorbitol granular material screening, and effectively solves the problems that sorbitol granular materials are not screened thoroughly and the utilization rate of screening equipment is low. The technical scheme includes that the material homogenizing device comprises a pulse feeding mechanism, a feeding port of the pulse feeding mechanism is communicated with an output end of an air feeding material pipeline, an output end of the pulse feeding mechanism is communicated with an input end of a homogenizing part, a switch valve is arranged at a joint of the output end of the pulse feeding mechanism and the input end of an electric vibrating screen, and an output end of the homogenizing part is communicated with an input end of the electric vibrating screen. The beneficial effects of the utility model are as follows: the utility model provides a simple structure, convenient to use can effectively improve the sorbitol granule material screening loading attachment of screen cloth utilization ratio and screening effect.

Description

Sorbitol particulate material screening and feeding device

Technical Field

The utility model relates to the technical field of solid sorbitol particle material screening, in particular to sorbitol particles

The granular material screening and feeding device.

Background

In the production process of solid sorbitol, in order to obtain better screening effect, the enterprise uses square vibration screening equipment, the screen cloth of the screening equipment inclines at a certain angle, sorbitol material enters from the upper opening of the screen cloth and flows to the discharge from the surface of the screen cloth to the bottom of the screen cloth, in the flowing process, the screen cloth continuously vibrates to screen the material, the ubiquitous material in the screening process is concentrated in the middle of the screen cloth, because the length of the screen cloth is limited, a large amount of material passes through the middle of the screen cloth, the problem of incomplete screening of the material can be caused, the feeding amount has to be reduced in order to ensure the screening effect, and the material is left unused in about half of the area of the whole screen cloth through the middle of the screen cloth, the utilization rate of the equipment is low, and the improvement of the capacity of the equipment is influenced.

Therefore, how to solve the above technical problems becomes the subject of the present invention.

SUMMERY OF THE UTILITY MODEL

In order to solve the defects of the prior art, the utility model provides the sorbitol granular material screening and feeding device which is simple in structure and convenient to use and can effectively improve the screen utilization rate and the screening effect.

The technical scheme adopted by the utility model for solving the technical problem is as follows: the utility model provides a sorbitol particulate material screening and feeding device which comprises a pulse feeding mechanism, wherein a feeding port of the pulse feeding mechanism is communicated with an output end of an air feeding material pipeline;

the output end of the pulse feeding mechanism is communicated with the input end of the refining component, a switch valve is arranged at the joint of the output end of the refining component and the input end of the electric vibrating screen.

The material homogenizing part comprises a horizontally arranged circular ring-shaped material inlet, and the material inlet is connected and matched with a circular opening at the output end of the pulse feeding mechanism;

an upper homogenizing bin is fixedly connected to the periphery of the bottom of the feeding port, the periphery of the bottom edge of the upper homogenizing bin is overlapped with and fixedly connected with the upper edge of the top of a rectangular horizontally arranged lower homogenizing bin, and the bottom outlet of the lower homogenizing bin is the same as and is connected and matched with the rectangular inlet of the electric vibrating screen;

and a plurality of upper homogenizing plates and a plurality of lower homogenizing plates are uniformly arranged in the upper homogenizing bin and the lower homogenizing bin respectively.

The upper material homogenizing plate comprises first upper material homogenizing plates, each first upper material homogenizing plate comprises vertical plates which are vertically arranged, two sides of the top of each vertical plate are fixedly connected to two sides of the inner wall of the material inlet, and the vertical plates are parallel to each other and have the same interval;

the lower material homogenizing plates with the same number are arranged in the lower material homogenizing bin corresponding to each vertical plate, the lower material homogenizing plates are parallel to each other and have the same distance, and the lower material homogenizing plates are parallel to the vertical plates;

two ends of each lower material homogenizing plate are respectively attached to and fixedly connected with the inner walls of two long edges of the lower material homogenizing bin, and the lower material homogenizing plates are perpendicular to the long edges of the lower material homogenizing bin;

the length and the width of the lower material homogenizing bin are both larger than the diameter of the feeding port;

and an inclined plate is fixedly connected between each vertical plate and the corresponding lower refining plate.

The upper material homogenizing plate comprises a second upper material homogenizing plate, and a plurality of right-angle trapezoidal second upper material homogenizing plates are uniformly arranged in the upper material homogenizing bin in the circumferential direction of the material inlet;

every on the second uniform plate the right-angle side all with the central axis coincidence of pan feeding mouth, every on the second the hypotenuse summit of uniform plate all with fixed connection, every are followed outward to pan feeding mouth bottom uniform plate hypotenuse all presses close to go up the inner wall in refining storehouse, every on the second uniform plate bottom all with the laminating of lower uniform plate top and crisscross distribution.

The upper material homogenizing plate and the lower material homogenizing plate are both made of stainless steel.

When the utility model is actually used: the material is sent the pipeline by the wind and is carried to pulse feeding mechanism in, pulse feeding mechanism sends the material into even feed bin at first, disperses the material through the effect of last refining plate, and the material after the dispersion gets into even feed bin down again, and even entry screen cloth that enters into the electric vibration sieve after carrying out the secondary refining to the material through the effect of even feed bin down sieves.

The utility model has the beneficial effects that: carry out effectual reposition of redundant personnel to the material through the refining part, improved the utilization ratio of screen cloth, promoted the screening effect, thereby the productivity of production efficiency and equipment has been promoted to the improvement feed volume that can the certain degree.

Drawings

Fig. 1 is a front view of the present invention.

Fig. 2 is a schematic perspective view of the refining element according to the present invention.

FIG. 3 is a front view of the inside of a refining member in example 1 of the present invention.

FIG. 4 is a schematic perspective view of the internal structure of a refining member in example 1 of the present invention.

FIG. 5 is a front view of the inside of a refining member in example 2 of the present invention.

FIG. 6 is a schematic perspective view of the internal structure of a refining member in example 2 of the present invention.

Wherein the reference numerals are: 1. a pulse feeding mechanism; 2. an air-fed material pipeline; 3. a refining component; 301. a feeding port; 302. feeding a material homogenizing bin; 303. discharging a material homogenizing bin; 304. a first upper refining plate; 3041. a vertical plate; 3042. a sloping plate; 305. a material homogenizing plate is arranged; 306. a second upper homogenizing plate; 4. an on-off valve; 5. and (5) electrically vibrating and screening.

Detailed Description

In order to clearly illustrate the technical features of the present solution, the present solution is explained below by way of specific embodiments.

Example 1

Referring to fig. 1 to 4, the utility model discloses a sorbitol particulate material screening and feeding device, which comprises a pulse feeding mechanism 1, wherein a feeding port of the pulse feeding mechanism 1 is communicated with an output end of an air feeding material pipeline 2, an output end of the pulse feeding mechanism 1 is communicated with an input end of a refining part 3, a connection part of the output end of the pulse feeding mechanism 1 is provided with a switch valve 4, and an output end of the refining part 3 is communicated with an input end of an electric vibrating screen 5.

The refining part 3 comprises a circular ring-shaped feeding port 301 which is horizontally arranged, the feeding port 301 is connected and matched with an annular port at the output end of the pulse feeding mechanism 1, an upper refining bin 302 is fixedly connected to the periphery of the bottom of the feeding port 301, the bottom of the upper refining bin 302 is overlapped and fixedly connected with the top of a lower refining bin 303 which is horizontally arranged in a rectangular shape along the periphery, the bottom outlet of the lower refining bin 303 is the same as the rectangular inlet of the electric vibrating screen 5 in size and is connected and matched with the rectangular inlet of the electric vibrating screen 5, and a plurality of upper refining plates and a plurality of lower refining plates 305 are respectively and uniformly arranged in the upper refining bin 302 and the lower refining bin 303. The upper material homogenizing plate and the lower material homogenizing plate 305 are both made of stainless steel.

The upper homogenizing plate comprises first upper homogenizing plates 304, each first upper homogenizing plate 304 comprises vertical plates 3041 which are vertically arranged, two sides of the top of each vertical plate 3041 are fixedly connected to two sides of the inner wall of the feeding port 301, each vertical plate 3041 is parallel to each other and has the same interval, lower homogenizing plates 305 which are the same in number are arranged in the lower homogenizing silo 303 corresponding to each vertical plate 3041, each lower homogenizing plate 305 is parallel to each other and has the same interval, each lower homogenizing plate 305 is parallel to the vertical plate 3041, two ends of each lower homogenizing plate 305 are respectively attached to and fixedly connected with the inner walls of two long edges of the lower homogenizing silo 303, the long edges of the lower homogenizing plates 305 and the long edges of the lower homogenizing silo 303 are perpendicular to each other, the length and the width of the lower homogenizing silo 303 are both greater than the diameter of the feeding port 301, and a homogenizing plate 3042 is fixedly connected between each vertical plate 3041 and the corresponding lower homogenizing plate 305.

During the actual use, the material is sent to pulse feeding mechanism 1 in by wind send pipeline 2, and pulse feeding mechanism 1 sends the material into in the refining bin 302 at first, disperses the material through the effect of the first refining board 304 of horizontal evenly distributed, and the material after the dispersion gets into refining bin 303 down again, and even entering into the entry screen cloth of electric vibrating screen 5 after carrying out the secondary refining to the material through the effect of refining board 305 down sieves. The blanking channel between every two first upper refining plates 304 completely corresponds to the blanking channel between two lower refining plates 305, so that the materials entering the screen are more dispersed.

Example 2

Referring to fig. 5 to 6, the rest of the embodiment 1 is the same as that of embodiment 1, except that: go up the refining plate and include refining plate 306 on the second, refining plate 306 is gone up to even being provided with a plurality of right angle trapezoidal form second with the circumferencial direction of pan feeding mouth 301 in the refining bin 302, refining plate 306 is all coincided with the central axis of pan feeding mouth 301 on the right-angle side of refining plate 306 on every second, the hypotenuse summit of refining plate 306 all with pan feeding mouth 301 bottom outer edge fixed connection on every second, refining plate 306 hypotenuse all presses close to the inner wall of refining bin 302 on every second, refining plate 306 bottom all laminates and crisscross distribution with refining plate 305 top down on every second. The second material homogenizing plates 306 distributed in the circumferential direction can completely equally divide the feeding port 301, so that the blanking is more uniformly dispersed.

The technical features of the present invention which are not described in the above embodiments may be implemented by or using the prior art, and are not described herein again, of course, the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and variations, modifications, additions or substitutions which may be made by those skilled in the art within the spirit and scope of the present invention should also fall within the protection scope of the present invention.

Claims (4)

1. The sorbitol particulate material screening and feeding device is characterized by comprising a pulse feeding mechanism (1), wherein a feeding port of the pulse feeding mechanism (1) is communicated with an output end of an air feeding material pipeline (2);

the output end of the pulse feeding mechanism (1) is communicated with the input end of a refining component (3), a switch valve (4) is arranged at the joint, and the output end of the refining component (3) is communicated with the input end of an electric vibrating screen (5);

the material homogenizing part (3) comprises a horizontally arranged circular ring-shaped material inlet (301), and the material inlet (301) is connected and matched with a circular opening at the output end of the pulse feeding mechanism (1);

an upper material homogenizing bin (302) is fixedly connected to the periphery of the bottom of the feeding port (301), the periphery of the bottom edge of the upper material homogenizing bin (302) is overlapped with and fixedly connected with the upper edge of the top of a rectangular horizontally arranged lower material homogenizing bin (303), and the size of the bottom outlet of the lower material homogenizing bin (303) is the same as that of the rectangular inlet of the electric vibrating screen (5) and the bottom outlet of the lower material homogenizing bin is connected and matched with the rectangular inlet of the electric vibrating screen;

a plurality of upper homogenizing plates and a plurality of lower homogenizing plates (305) are respectively and uniformly arranged in the upper homogenizing bin (302) and the lower homogenizing bin (303).

2. The sorbitol granular material screening and feeding device as claimed in claim 1, wherein the upper refining plate comprises first upper refining plates (304), each first upper refining plate (304) comprises vertical plates (3041) which are vertically arranged, two sides of the top of each vertical plate (3041) are fixedly connected to two sides of the inner wall of the feeding port (301), and the vertical plates (3041) are parallel to each other and have the same interval;

the lower material homogenizing plates (305) with the same number are arranged in the lower material homogenizing bin (303) corresponding to each vertical plate (3041), the lower material homogenizing plates (305) are parallel to each other and have the same distance, and each lower material homogenizing plate (305) is parallel to the vertical plate (3041);

two ends of each lower homogenizing plate (305) are respectively attached to and fixedly connected with the inner walls of two long edges of the lower homogenizing cabin (303), and the long edges of the lower homogenizing plates (305) and the lower homogenizing cabin (303) are perpendicular to each other;

the length and the width of the lower material homogenizing bin (303) are both larger than the diameter of the feeding port (301);

an inclined plate (3042) is fixedly connected between each vertical plate (3041) and the corresponding lower material homogenizing plate (305).

3. The sorbitol particulate material screening and feeding device as claimed in claim 1, wherein the upper homogenizing plate comprises a second upper homogenizing plate (306), and a plurality of right-angled trapezoid-shaped second upper homogenizing plates (306) are uniformly arranged in the upper homogenizing chamber (302) in the circumferential direction of the feeding port (301);

every on the second uniform plate (306) the right-angle side all with the central axis coincidence of pan feeding mouth (301), every on the second the hypotenuse summit of uniform plate (306) all with pan feeding mouth (301) bottom is outer along fixed connection, every on the second uniform plate (306) hypotenuse all presses close to go up the inner wall of uniform material storehouse (302), every on the second uniform plate (306) bottom all with uniform plate (305) top laminating and crisscross distribution down.

4. The sorbitol particulate material screening and feeding device as claimed in claim 1, wherein said upper homogenizing plate and said lower homogenizing plate (305) are both made of stainless steel.

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