CN219581077U - High-efficient feeding structure of sieve shakes soon - Google Patents

Abstract

The utility model relates to the technical field of feeding structures, and discloses a high-efficiency feeding structure of a rotary vibrating screen, which comprises two supporting rods and a material port, wherein the two supporting rods are distributed on two sides of the material port, bottom plates are welded and fixed on the bottoms of the supporting rods on two sides, sleeves are fixed on the surfaces of the two sides of the material port, the sleeves are slidably sleeved on the outer rings of the supporting rods, bolts are screwed on the side edges of the sleeves through screw grooves, the tail ends of the bolts penetrate into the sleeves and are abutted against the surfaces of the supporting rods, and hoppers communicated with the inside of the lower parts of the material port are integrally connected. According to the technical scheme, the two supporting rods are arranged on two sides of the material opening and the hopper, the material opening and the hopper are locked at fixed heights by utilizing the sleeve matched bolts, and the heights of the rotary vibrating screen can be easily adjusted when the heights of the rotary vibrating screen are changed, so that the bottom discharge pipe is close to and above the screen mesh on the uppermost layer, continuous feeding can be realized to the rotary vibrating screen, the discharge pipe is prevented from contacting with the rotary vibrating screen, and powder is conveniently added, so that the screening efficiency is improved.

Description

High-efficient feeding structure of sieve shakes soon

Technical Field

The utility model relates to the technical field of feeding structures, in particular to a high-efficiency feeding structure of a rotary vibrating screen.

Background

The rotary vibration sieve is a high-precision fine powder sieving machine, has low noise and high efficiency, takes 3-5 minutes for quick net replacement, has a fully-closed structure, is suitable for sieving and filtering materials such as grains, powder, mucus and the like, takes a vertical motor as a vibration source, is provided with eccentric weights at the upper end and the lower end of the motor, converts the rotary motion of the motor into horizontal, vertical and inclined three-dimensional motions, and transmits the motions to a sieving surface. The phase angles of the upper end and the lower end are adjusted, so that the movement track of the material on the screen surface can be changed.

The rotary vibration sieve can use a single-layer sieve or a multi-layer sieve when in use, can realize multi-stage sieving of materials, and manually enables powder to be sieved to be added into the uppermost sieve when in sieving.

When the technical scheme is realized, at least the following defects exist: because the powder is added by the manual work, and increase of the whole height of the device can be further caused when the multilayer screen cloth is added during screening, the powder is not convenient enough, and the screening efficiency is lower. Therefore, we propose a high-efficient feeding structure of rotary vibrating screen.

Disclosure of Invention

The utility model aims to provide a high-efficiency feeding structure of a rotary vibrating screen, which is characterized in that two supporting rods are arranged on two sides of a material opening and a hopper, the material opening and the hopper are locked at fixed heights by utilizing sleeve matched bolts, the heights of the rotary vibrating screen can be easily adjusted when the heights of the rotary vibrating screen are changed, a discharging pipe at the bottom of the rotary vibrating screen is close to and above an uppermost screen, continuous feeding into the rotary vibrating screen can be realized, the discharging pipe is prevented from contacting the rotary vibrating screen, powder is conveniently added, the screening efficiency is improved, and the problems in the background art are solved.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the high-efficiency feeding structure of the rotary vibrating screen comprises two supporting rods and a material port, wherein the two supporting rods are distributed on two sides of the material port, and bottom plates are welded and fixed at the bottoms of the supporting rods on two sides; the sleeve is fixedly arranged on the surfaces of two sides of the material opening, the sleeve is sleeved on the outer ring of the supporting rod in a sliding manner, the side edge of the sleeve is screwed with a bolt through a screw groove, and the tail end of the bolt penetrates into the sleeve and is abutted against the surface of the supporting rod; the lower integral of the material opening is connected with a hopper communicated with the inside of the material opening, and the bottom integral of the hopper is connected with a discharging pipe communicated with the inside of the material opening.

Through adopting above-mentioned technical scheme, utilize branch cooperation bottom plate to realize the support to feed inlet and hopper to in the in-process of using, can lock feed inlet and hopper on suitable height through sleeve cooperation bolt, and then the adaptation contains the sieve that shakes soon of different layer number screen cloth, make the bottom of discharging pipe be located the top of the upper screen cloth and be close to rather than as far as possible, make the material be added to in the sieve that shakes soon, improve the effect of screening.

Optionally, the terminal of bolt is fixed with the rubber piece that is used for anti-skidding conflict, and the bolt is contradicted at the surface of branch through the rubber piece.

Through adopting above-mentioned technical scheme, when the bolt is screwed up, contradict at the surface of branch through its terminal rubber piece, can obtain more stable skid-proof conflict supporting effect.

Optionally, one side of the rubber block is integrally connected with a clamping block, and the rubber block is connected with the bolt in a mode that the clamping block is embedded into the bolt.

Through adopting above-mentioned technical scheme, through the inside mode of fixture block embedding to the rubber piece, realize the firm connection of rubber piece and bolt.

Optionally, an annular groove is formed around the outer ring of the discharging pipe, and the annular groove is provided with two circles.

Through adopting above-mentioned technical scheme, when needs make discharging pipe outer lane cover go up the cloth cover, can make the rope encircle behind the cloth cover outer lane block put in the annular, realize the locking to the cloth cover.

Optionally, the sleeve is fixed on the side surface of the material opening in a welding mode, and the sleeve is symmetrically arranged on two sides of the material opening.

Through adopting above-mentioned technical scheme, realize the firm fixed to the sleeve through welded mode.

Compared with the prior art, the technical scheme of the utility model has the following beneficial effects:

1. according to the technical scheme, the two supporting rods are arranged on two sides of the material opening and the hopper, the material opening and the hopper are locked at fixed heights by utilizing the sleeve matched bolts, and the heights of the rotary vibrating screen can be easily adjusted when the heights of the rotary vibrating screen are changed, so that the bottom discharge pipe is close to and above the screen mesh on the uppermost layer, continuous feeding can be realized to the rotary vibrating screen, the discharge pipe is prevented from contacting with the rotary vibrating screen, and powder is conveniently added, so that the screening efficiency is improved.

2. According to the technical scheme, the rubber block is fixed at the tail end of the bolt, the bolt is abutted against the surface of the supporting rod through the rubber block, and the anti-skid and anti-collision effects of the bolt and the supporting rod are improved.

Drawings

Other features, objects and advantages of the present utility model will become more apparent upon reading of the detailed description of non-limiting embodiments, given with reference to the accompanying drawings in which:

FIG. 1 is a schematic diagram of the overall structure of the high-efficiency feed structure of the rotary vibrating screen of the present utility model;

fig. 2 is a schematic diagram of a bolting configuration of the high efficiency feed structure of the rotary vibrating screen of the present utility model.

In the figure: 1. a support rod; 11. a bottom plate; 2. a material port; 21. a hopper; 22. a discharge pipe; 23. a ring groove; 3. a sleeve; 31. a bolt; 311. a rubber block; 312. a clamping block; 32. a screw groove.

Detailed Description

Referring to fig. 1-2, the present utility model provides a technical solution: the utility model provides a high-efficient feeding structure of rotary vibrating screen, includes branch 1 and material mouth 2, and branch 1 is provided with two and the bottom of two branches 1 is welded fastening has bottom plate 11, and branch 1 hangs down the surface of placing bottom plate 11 in, and two branches 1 distribute in the both sides of material mouth 2;

referring to fig. 1 and 2, a sleeve 3 is slidably sleeved on the outer ring above the struts 1 at two sides, the sleeve 3 can be lifted or lowered to different heights on the outer ring of the struts 1, two side edges of the sleeve 3 are provided with through screw grooves 32, the side edges of the sleeve 3 are screwed with bolts 31 through the screw grooves 32, one end of each bolt 31 penetrates into the sleeve 3, a clamping block 312 is fixedly embedded in the interior of each bolt 31, a rubber block 311 is integrally connected to the outer side of each clamping block 312, each rubber block 311 penetrates to the outer side of each bolt 31, the rubber blocks 311 are abutted against the surface of the struts 1, after the sleeve 3 is adjusted to a proper height, the rubber blocks 311 at the tail ends of the bolts 31 can be abutted against the surface of the struts 1 to lock the struts, the other end of each bolt 31 is positioned outside the sleeve 3, a material port 2 is arranged between the sleeves 3 at two sides and abutted against the sleeve 3, and the side edges of the sleeve 3 and the material port 2 are welded and fixed together, and after the height of the sleeve 3 is adjusted and locked, the height adjustment and locking of the material port 2 are simultaneously realized;

referring to fig. 1, a hopper 21 is integrally connected to the lower part of a material port 2, a discharge pipe 22 is integrally connected to the lower part of the hopper 21, the hopper 21 is communicated with the inside of the material port 2, the discharge pipe 22 is communicated with the hopper 21 and is communicated with the material port 2, powder enters the hopper 21 after being added through the material port 2, then enters the discharge pipe 22 and is discharged to the outside, and enters a rotary vibration sieve, and as the discharge pipe 22 is not contacted with a screen mesh on the uppermost layer, the vibration of the rotary vibration sieve can be prevented from affecting the feeding;

referring to fig. 1, an annular groove 23 is formed around the outer ring of the discharging pipe 22, and the annular groove 23 is provided with two rings, so as to avoid the phenomenon of spreading when powder falls, a cloth sleeve can be sleeved on the outer ring of the discharging pipe 22, and a rope is wound around the outer ring of the cloth sleeve and then is bundled into the annular groove 23, so that the cloth sleeve is locked, and the dust spreading can be reduced during discharging.

During the use, make branch 1 by vertical steady rest through bottom plate 11, and make branch 1 of both sides supported in the both sides of sieve that shakes soon, then adjust the height of feed inlet 2 and hopper 21 according to the height of sieve that shakes soon, unscrew the bolt 31 that is located on sleeve 3 of both sides earlier in the time of the adjustment, and make its end no longer conflict in the surface of branch 1, and then can drive feed inlet 2 and hopper 21 to rise or descend the height, afterwards screw down bolt 31 makes the rubber piece 311 at its end support tightly in the surface of branch 1 once more, and then lock sleeve 3, feed inlet 2 and hopper 21's height, and at every time increase or reduce the number of layers of screen cloth, all adjust feed inlet 2 and hopper 21's height, make bottom discharging pipe 22 be close to on the screen cloth of top as far as possible, in order to reduce the powder to add in the sieve that shakes soon, can use the cloth cover in the outer lane of discharging pipe 22, and make the rope bind in the outer lane of cloth cover place it below the screen cloth pipe 22 in the top of the same time, then make the powder conveying pipeline of its end place in the top of screen cloth cover simultaneously, then make the powder conveying pipeline of its end place in the top of screen cloth pipe 2 in order to continue shaking, and mix in the sieve to shake in the sieve, the powder layer in the sieve that the sieve is added continuously after the sieve is continued, and the sieve is added to the sieve in the sieve is passed through the sieve to the sieve in the sieve layer of the sieve that the sieve is added into the layer after the layer.

Claims (5)

1. The utility model provides a high-efficient feeding structure of sieve shakes soon, includes branch and feed opening, its characterized in that: the two support rods are arranged and distributed on two sides of the material opening, and bottom plates are welded and fixed at the bottoms of the support rods on two sides;

the sleeve is fixedly arranged on the surfaces of two sides of the material opening, the sleeve is sleeved on the outer ring of the supporting rod in a sliding manner, the side edge of the sleeve is screwed with a bolt through a screw groove, and the tail end of the bolt penetrates into the sleeve and is abutted against the surface of the supporting rod;

the lower integral of the material opening is connected with a hopper communicated with the inside of the material opening, and the bottom integral of the hopper is connected with a discharging pipe communicated with the inside of the material opening.

2. The high-efficiency feeding structure of a rotary vibrating screen according to claim 1, wherein: the tail end of the bolt is fixed with a rubber block for preventing sliding and abutting, and the bolt abuts against the outer surface of the supporting rod through the rubber block.

3. The high-efficiency feeding structure of a rotary vibrating screen according to claim 2, wherein: one side of the rubber block is integrally connected with a clamping block, and the rubber block is connected with the bolt in a mode that the clamping block is embedded into the bolt.

4. The high-efficiency feeding structure of a rotary vibrating screen according to claim 1, wherein: an annular groove is formed in the outer ring of the discharging pipe in a surrounding mode, and two rings are arranged in the annular groove.

5. The high-efficiency feeding structure of a rotary vibrating screen according to claim 1, wherein: the sleeve is fixed on the side surface of the material opening in a welding mode, and the sleeve is symmetrically arranged on two sides of the material opening.