CN219817033U - High-efficient screening subassembly is used to prilling tower - Google Patents

Abstract

The utility model provides a high-efficiency screening component for a granulating tower, wherein two supporting seats are arranged at the lower part of a tower body of the granulating tower, the two screening components are symmetrically arranged on the outer side wall of the vertical part of the tower body, vertical guide components are respectively arranged on the inner side walls of the vertical parts of the two supporting seats, a horizontal moving platform is arranged on the inner side of each vertical guide component, and the screening component is arranged between the two horizontal moving platforms. According to the utility model, the movement and vibration of the screening assembly can be realized through the vertical guide assembly and the horizontal moving platform, and the cleaning of large particles accumulated on the screen can be realized without stopping, so that the screening efficiency of the particles is greatly improved.

Description

High-efficient screening subassembly is used to prilling tower

Technical Field

The utility model relates to the technical field of screening devices, in particular to a high-efficiency screening component for a prilling tower.

Background

The granulating tower is in a chimney shape, has the same diameter, and has the structure that the height of a reinforced concrete cylinder body is 50-100 meters, and the working principle is that liquid materials are pushed to the top through a pipeline and then are sprayed out, and in the falling process, the materials are automatically solidified into solid small particles through air cooling. When current prilling tower carries the finished product granule of its bottom, can set up the screen cloth in the bottom of prilling tower and screen the granule generally, when the accumulational macroparticle is more on the screen cloth, can lead to the screen cloth screening inefficacy, at this moment, need shut down to clear up accumulational macroparticle on the screen cloth, just can continue to carry out screening work, greatly reduced the screening efficiency of screen cloth.

Disclosure of Invention

In view of the above, the utility model provides the efficient screening component for the prilling tower, the movement and vibration of the screening component can be realized through the vertical guide component and the horizontal moving platform, the cleaning of large particles accumulated on the screen can be realized without stopping, and the screening efficiency of the particles is greatly improved.

In order to solve the technical problems, the utility model provides a high-efficiency screening assembly for a prilling tower, wherein a supporting seat is arranged at the lower part of a tower body of the prilling tower, the supporting seat is used for supporting and fixing the tower body of the prilling tower, screening assemblies are arranged below the tower body and are used for screening particles produced by the prilling tower, two supporting seats are symmetrically arranged on the outer side wall of the vertical part of the tower body, vertical guide assemblies are respectively arranged on the inner side walls of the vertical parts of the two supporting seats and are used for guiding the vertical positions of the screening assemblies, vertical movement of the screening assemblies is realized through up-and-down movement, further high-efficiency screening is realized, the inner side of each vertical guide assembly is provided with a horizontal moving platform, the horizontal moving platform is used for moving the horizontal position of the screening assembly, rapid cleaning and collecting of residual particles on the screening assembly are conveniently realized, and the screening assembly is arranged between the two horizontal moving platforms.

The vertical guide assembly comprises guide rails respectively arranged on the inner side walls of the vertical parts of the supporting seats, guide blocks are respectively arranged in the guide rails in a sliding mode, telescopic sleeve rods are respectively arranged on the inner sides of the horizontal parts of the bottoms of the guide rails, the end parts of the telescopic ends of the telescopic sleeve rods are connected with the bottoms of the horizontal parts of the guide blocks, and the telescopic sleeve rods are used for carrying out upper and lower elastic support on the guide blocks and the screening assembly and are convenient for enhancing the screening efficiency of the screening assembly.

Be provided with horizontal migration platform on the vertical portion inside wall of two guide blocks respectively, horizontal migration platform is sharp slip table, is provided with screening subassembly between the slider of two sharp slip tables, and screening subassembly is including setting up flourishing the frame that connects between the slider of two sharp slip tables, and flourishing bottom that connects the frame is provided with the screen cloth, and the screen cloth is used for sieving the granule of different diameter sizes, is convenient for follow-up granule's recovery and classification.

The telescopic loop bar comprises a fixed end, a telescopic end and a compression spring which is arranged inside the fixed end and used for supporting the telescopic end, the telescopic end of the telescopic loop bar can enter the fixed end under the action of external force to further compress the compression spring inside the fixed end, after the external force is removed, the screening assembly is driven to vibrate up and down under the action of self-restoring elastic force of the compression spring, and then efficient screening of particles is achieved, the screening effect is better, and the efficiency is higher.

The supporting seat is Z-shaped, and the upper horizontal part of the supporting seat is welded on the outer side wall of the tower body and is fastened on the ground through expansion bolts.

The screening components are two, the two screening components are fixedly arranged on the sliding block of the linear sliding table, and the gap between the containing frames of the two screening components is smaller than the minimum diameter of the minimum particles. Therefore, particles on the screening component can be rapidly collected under the action of the linear sliding table under the condition of no shutdown.

In summary, compared with the prior art, the utility model has at least one of the following beneficial technical effects:

1. according to the utility model, the movement and vibration of the screening assembly can be realized through the vertical guide assembly and the horizontal moving platform, and the cleaning of large particles accumulated on the screen can be realized without stopping, so that the screening efficiency of the particles is greatly improved.

2. The vertical guide component is used for enabling the screening component to vibrate in the vertical direction when particles produced by the granulating tower fall and strike the screen of the screening component, so that an effect similar to a vibrating screen is produced, and screening efficiency of the screen is improved.

3. The horizontal moving platform is used for moving the horizontal position of the screen cloth, so that the screen cloth filled with particles is conveniently moved to the lower part of the granulating tower while a new screen cloth is conveniently moved to the lower part of the granulating tower, residual particles on the screen cloth are conveniently absorbed and collected by the absorbing material, the screen cloth cleaning work of the granulating tower can be performed without stopping the machine, and the device is more efficient and convenient.

4. The screening component is to setting up the purpose in succession in order to be convenient for realize the high-efficient screening to the granule that the prilling tower produced under the state of not shutting down, it is more convenient.

Drawings

FIG. 1 is a schematic view of a high efficiency screen assembly for a prilling tower of the present utility model;

FIG. 2 is an elevation view of a high efficiency screen assembly for a prilling tower of the present utility model;

FIG. 3 is a top view of the high efficiency screen assembly for a prilling tower of the present utility model;

fig. 4 is a rear view of the high efficiency screen assembly for a prilling tower of the present utility model.

Reference numerals illustrate: 100. a tower body; 200. a support base; 300. a screen assembly; 301. a holding frame; 302. a screen; 400. a vertical guide assembly; 401. a guide rail; 402. a guide block; 403. a telescopic loop bar; 500. and (5) horizontally moving the platform.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present utility model more clear, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to fig. 1 to 4 of the embodiments of the present utility model. It will be apparent that the described embodiments are some, but not all, embodiments of the utility model. All other embodiments, which are obtained by a person skilled in the art based on the described embodiments of the utility model, fall within the scope of protection of the utility model.

As shown in fig. 1: the embodiment provides a high-efficient screening subassembly is used to prilling tower, tower body 100 lower part of prilling tower is provided with supporting seat 200, supporting seat 200 is the Z type, the upper portion horizontal part welding of supporting seat 200 sets up on the lateral wall of tower body 100, supporting seat 200 passes through expansion bolts fastening subaerial, supporting seat 200 is used for supporting and fixing the tower body 100 of prilling tower, the below of tower body 100 is provided with screening subassembly 300, screening subassembly 300 is used for sieving the granule that prilling tower produced, supporting seat 200 has two, and the symmetry sets up on the vertical portion lateral wall of tower body 100, be provided with vertical direction subassembly 400 on the vertical portion inside wall of two supporting seats 200 respectively, vertical direction subassembly 400 is used for guiding the vertical position of screening subassembly 300, be used for realizing the up-and-down motion of screening subassembly 300 through the up-and-down motion, and then realized high-efficient screening, the inboard of every vertical direction subassembly 400 all is provided with horizontal movement platform 500, horizontal movement platform 500 is used for moving the horizontal position of screening subassembly 300, be convenient for realizing the quick clearance of remaining granule on the screening subassembly 300, two horizontal movement platform 500 are provided with between two horizontal movement 300.

According to one embodiment of the present utility model, as shown in fig. 1 and 4, the vertical guide assembly 400 includes guide rails 401 respectively disposed on inner side walls of the vertical portion of the supporting base 200, each guide rail 401 has a guide block 402 sliding inside, a telescopic rod 403 is disposed inside a horizontal portion of a bottom of each guide rail 401, and an end portion of a telescopic end of the telescopic rod 403 is connected to a bottom of the horizontal portion of the guide block 402, and the telescopic rod 403 is used for elastically supporting the guide block 402 and the screening assembly 300 up and down, so as to enhance screening efficiency of the screening assembly 300.

According to another embodiment of the present utility model, as shown in fig. 1 and 3, the inner side walls of the vertical portions of the two guide blocks 402 are respectively provided with a horizontal moving platform 500, the horizontal moving platform 500 is a linear sliding table, a screening assembly 300 is arranged between the sliding blocks of the two linear sliding tables, the screening assembly 300 comprises a containing frame 301 arranged between the sliding blocks of the two linear sliding tables, the bottom of the containing frame 301 is provided with a screen 302, and the screen 302 is used for screening particles with different diameters, so that the subsequent particles can be recovered and classified conveniently.

According to another embodiment of the present utility model, as shown in fig. 2 and 4, the telescopic rod 403 includes a fixed end, a telescopic end and a compression spring disposed inside the fixed end for supporting the telescopic end, where the telescopic end of the telescopic rod 403 can enter the fixed end under the action of external force to further compress the compression spring inside the fixed end, and after the external force is removed, the screen assembly 300 is driven to vibrate up and down under the action of self-restoring elastic force of the compression spring, so as to realize efficient screening of particles, and the screening effect is better and the efficiency is higher.

According to another embodiment of the present utility model, as shown in fig. 3, there are two screen assemblies 300, two screen assemblies 300 are fixedly arranged on the slide block of the linear sliding table, and the gap between the receiving frames 301 of two screen assemblies 300 is smaller than the minimum diameter of the minimum particles. This allows for rapid collection of particles on screen assemblies 300 without downtime under the action of a linear slipway.

The application method of the utility model comprises the following steps:

firstly, it should be clear that, the screen 302 of the high-efficiency screening assembly 300 designed by the utility model is opposite to and is closely adjacent to the horizontal moving platform 500, when the prilling tower is used for production, the produced large and small particles fall onto the screen 302 downwards, downward pressure is generated on the screen 302, the screen 302 drives the horizontal moving platform 500 to press the guide block 402 downwards along the guide rail 401 to compress the telescopic end of the telescopic sleeve rod 403, the telescopic end of the telescopic sleeve rod 403 can enter the fixed end under the action of the pressure to further compress the compression spring in the fixed end, the compressed compression spring can drive the screening assembly 300 to vibrate up and down under the self-restoring elastic force, so that the high-efficiency screening of the particles is realized, when the large particles on the screen 302 are accumulated to a certain extent, the horizontal moving platform 500 is started to drive the screening assembly 300 to move forwards until the new screen 302 is placed under the granulator, then the large particles on the screen 302 far away from the granulator are collected through the absorber, the absorber can further collect the large particles on the screen 302 through the absorber, and the large particles can be lifted up and down through the guide rail 500 in the prior art, and the large-efficiency of the screen assembly is not required to be cleaned up by the large-size screening assembly 500.

While the foregoing is directed to the preferred embodiments of the present utility model, it will be appreciated by those skilled in the art that various modifications and adaptations can be made without departing from the principles of the present utility model, and such modifications and adaptations are intended to be comprehended within the scope of the present utility model.

Claims (7)

1. High-efficient screening subassembly is used to prilling tower, and tower body (100) lower part of prilling tower is provided with supporting seat (200), the below of tower body (100) is provided with screening subassembly (300), its characterized in that: the two supporting seats (200) are symmetrically arranged on the outer side wall of the vertical part of the tower body (100), vertical guide assemblies (400) are respectively arranged on the inner side walls of the vertical parts of the two supporting seats (200), each vertical guide assembly (400) is provided with a horizontal moving platform (500) on the inner side, and screening assemblies (300) are arranged between the two horizontal moving platforms (500).

2. The high efficiency screen assembly for a prilling tower of claim 1, wherein: the vertical guide assembly (400) comprises guide rails (401) which are respectively arranged on the inner side walls of the vertical parts of the supporting seat (200), guide blocks (402) are respectively arranged in the guide rails (401) in a sliding mode, telescopic sleeve rods (403) are respectively arranged on the inner sides of the horizontal parts of the bottoms of the guide rails (401), and the end portions of the telescopic ends of the telescopic sleeve rods (403) are connected with the bottoms of the horizontal parts of the guide blocks (402).

3. The high efficiency screen assembly for a prilling tower of claim 2, wherein: horizontal moving platforms (500) are respectively arranged on the inner side walls of the vertical parts of the two guide blocks (402), and the horizontal moving platforms (500) are linear sliding tables.

4. A high efficiency screen assembly for a prilling tower according to claim 3, wherein: a screening assembly (300) is arranged between the sliding blocks of the two linear sliding tables, the screening assembly (300) comprises a containing frame (301) arranged between the sliding blocks of the two linear sliding tables, and a screen (302) is arranged at the bottom of the containing frame (301).

5. The high efficiency screen assembly for a prilling tower of claim 2, wherein: the telescopic loop bar (403) comprises a fixed end, a telescopic end and a compression spring which is arranged inside the fixed end and used for supporting the telescopic end.

6. The high efficiency screen assembly for a prilling tower of claim 1, wherein: the support base (200) is Z-shaped, and the upper horizontal part of the support base (200) is welded on the outer side wall of the tower body (100).

7. The high efficiency screen assembly for a prilling tower of claim 4, wherein: the two screening assemblies (300) are fixedly arranged on the sliding blocks of the linear sliding table, and the gap between the containing frames (301) of the two screening assemblies (300) is smaller than the minimum diameter of the minimum particles.