CN214286990U - High-efficient filterable sieve that shakes soon - Google Patents

Abstract

The utility model relates to a sieve that shakes soon of high-efficient filteration belongs to ceramic manufacture's field, and it includes base, first bank of screens and shield, still includes the motor, the shield is opened and is equipped with the inlet pipe, the internally mounted of first bank of screens has the first sieve that shakes soon, discharging pipe, its characterized in that have been seted up to the lateral wall of first bank of screens: first sieve that shakes soon includes first screen cloth and second screen cloth, first screen cloth with second screen cloth fixed connection, the second screen cloth is connected with a plurality of first arc screen cloths, a plurality of first arc screen cloths use the axle center of first screen cloth as the interval distribution round of center. This application has the more abundant effect of messenger's mud filtration.

Description

High-efficient filterable sieve that shakes soon

Technical Field

The application relates to the field of ceramic production, in particular to a rotary vibration sieve for efficient filtration.

Background

The mud is formed by stirring materials such as clay and the like, is a main raw material for ceramic production, but the particle size of the qualified mud is standard, and in order to produce the qualified mud, mud blocks and large-particle objects in the mud need to be screened out by a rotary vibration screen.

Chinese patent publication No. CN201596617U discloses a novel double discharge pipe rotary vibrating screen. This novel two discharging pipe sieve that shakes soon includes the base, and the sieve that shakes soon is equipped with two discharging pipes. The materials entering the rotary vibration sieve can be respectively sent out from the two discharge pipes of the rotary vibration sieve, so that the rotary vibration sieve can discharge materials rapidly.

In view of the above-mentioned related technologies, the inventor believes that although the discharging speed is accelerated, the time for the rotary vibrating screen to filter the material is also shortened, so that the material is insufficiently filtered.

SUMMERY OF THE UTILITY MODEL

In order to make mud filter more abundant, this application provides a high-efficient filterable sieve that shakes soon.

The application provides a high-efficient filterable sieve that shakes soon adopts following technical scheme:

the utility model provides a sieve shakes soon of high-efficient filterable, includes base, first bank of screens and shield, still includes the motor, the shield is opened and is equipped with the inlet pipe, the internally mounted of first bank of screens has first sieve of shaking soon, the discharging pipe has been seted up to the lateral wall of first bank of screens, first sieve of shaking soon includes first screen cloth and second screen cloth, first screen cloth with second screen cloth fixed connection, the second screen cloth is connected with a plurality of first sieve screens, a plurality of first sieve screens use the axle center of first screen cloth as the interval distribution round of center.

Through adopting above-mentioned technical scheme, the in-process of filtering mud because the motor drives first sieve that shakes soon and rocks, and the mud that falls into first screen cloth scatters to the second screen cloth at the upper surface of first screen cloth gradually, and at the in-process that mud scatters, further filtration is carried out to mud to first arc screen cloth for filter to mud is more abundant.

Preferably, the first arc-shaped screen is detachably connected with the second screen through a pair of sliding grooves, the pair of sliding grooves is fixedly connected with the second screen, and the first arc-shaped screen is respectively spliced with the pair of sliding grooves.

Through adopting above-mentioned technical scheme, the first arc screen cloth of convenient to detach.

Preferably, the second screen cloth still is connected with a plurality of second arc screen cloth, a plurality of second arc screen cloth use the axle center of first screen cloth as the central interval distribution round, the second arc screen cloth is close to the inside wall of first bank of screens, first arc screen cloth is kept away from the inside wall of first bank of screens, every second arc screen cloth all is located between the adjacent first arc screen cloth.

By adopting the technical scheme, the second arc-shaped screen can further filter the slurry passing between the adjacent first arc-shaped screens.

Preferably, the arc length of the second arcuate screen is longer than the arc length of the first arcuate screen.

Through adopting above-mentioned technical scheme for the second sieve bend can filter more from the mud that passes through between the adjacent first sieve bend.

Preferably, a third arc-shaped screen is arranged on the second screen close to the discharge pipe.

Through adopting above-mentioned technical scheme, the third sieve bend filters once more to the mud that is close to the discharging pipe for filter the ground more thoroughly to mud.

Preferably, the inner side wall of the first screen frame is fixedly connected with a connecting ring, one end of the third arc-shaped screen close to the first screen frame is fixedly connected with a connecting rod, and the connecting rod is inserted into the connecting ring.

Through adopting above-mentioned technical scheme, the third arc screen cloth of being convenient for is dismantled.

Preferably, the inner side wall of the first screen frame is further fixedly connected with a limiting rod abutted against the third arc-shaped screen.

Through adopting above-mentioned technical scheme, the third arc screen cloth is further consolidated to the gag lever post.

Preferably, the screen frame further comprises a second screen frame, a second rotary vibration screen is mounted inside the second screen frame, and the mesh number of the second rotary vibration screen is larger than that of the first rotary vibration screen.

Through adopting above-mentioned technical scheme, the second is revolved and is shaken the sieve and carry out further filtration to mud for the filtration to mud is more thorough.

In summary, the present application includes at least one of the following beneficial technical effects:

1. in the process of filtering the slurry, the motor drives the first rotary vibration sieve to shake, the slurry falling into the first screen mesh is gradually dispersed towards the second screen mesh on the upper surface of the first screen mesh, and the first arc-shaped screen mesh further filters the slurry in the slurry dispersing process, so that the slurry is more fully filtered;

2. the second arcuate screen may further filter the slurry passing between adjacent first arcuate screens;

3. the third arch-shaped screen re-filters the slurry near the discharge pipe, so that the slurry is filtered more thoroughly.

Drawings

Fig. 1 is a schematic structural view of a high efficiency filtration rotary vibrating screen according to an embodiment of the present application.

FIG. 2 is a cross-sectional view of a high efficiency filtration rotary shaker screen according to an embodiment of the present application.

FIG. 3 is a schematic diagram of a structure embodying a first arcuate screen, a second arcuate screen, and a third arcuate screen in accordance with an embodiment of the present application.

Description of reference numerals: 1. a base; 2. a first screen frame; 21. a discharge pipe; 22. a first rotary vibration screen; 221. a first screen; 222. a second screen; 3. a second screen frame; 31. a second rotary vibration screen; 4. a third screen frame; 41. a chassis; 5. a dust cover; 51. a feed pipe; 6. a motor; 7. a first arcuate screen; 8. a second arcuate screen; 9. a third arcuate screen; 10. a chute; 11. a connecting ring; 12. a connecting rod; 13. a limiting rod.

Detailed Description

The present application is described in further detail below with reference to figures 1-3.

The embodiment of the application discloses high-efficient filterable sieve that shakes soon. Referring to fig. 1 and 2, a high-efficiency filtering rotary vibration sieve comprises a base 1, a first sieve frame 2, a second sieve frame 3, a third sieve frame 4 and a dustproof cover 5, wherein the dustproof cover 5, the first sieve frame 2, the second sieve frame 3, the third sieve frame 4 and the base 1 are sequentially arranged from top to bottom, a feeding pipe 51 is arranged in the middle of the dustproof cover 5, a hole (not shown) is formed in the upper surface of the base 1, a motor 6 is further arranged, an output shaft of the motor 6 extends out of the hole of the base 1 and is fixedly connected with the lower surface of the third sieve frame 4, discharging pipes 21 are respectively arranged on the side walls of the first sieve frame 2, the second sieve frame 3 and the third sieve frame 4, a first rotary vibration sieve 22 is arranged in the first sieve frame 2, the first rotary vibration sieve 22 is parallel to the ground, a second rotary vibration sieve 31 is arranged in the second sieve frame 3, the second rotary vibration sieve 31 is parallel to the ground, and the mesh number of the second rotary vibration sieve 31 is larger than that of the first rotary vibration sieve 22, the third frame 4 is fitted with a chassis 41, the chassis 41 being parallel to the ground.

Starting the motor 6, driving the first sieve frame 2 to rock by the motor 6, in the process of filtering mud, firstly, the mud enters the first sieve frame 2 from the feeding pipe 51, then the mud falls on the central position of the upper surface of the first rotary vibration sieve 22, and as the motor 6 drives the first sieve frame 2 to rock, the mud is gradually dispersed from the center of the first rotary vibration sieve 22, meanwhile, the first rotary vibration sieve 22 filters the mud, mud blocks in the mud are sieved by the first rotary vibration sieve 22, and the sieved mud blocks are discharged from the discharging pipe 21 of the first sieve frame 2; the mud filtered by the first rotary vibration sieve 22 falls on the upper surface of the second rotary vibration sieve 31, the second rotary vibration sieve 31 further filters the mud, large granular objects (the implementation refers to unqualified mud with smaller particles than mud blocks) in the mud are sieved out, and the sieved large granular objects are discharged from the discharge pipe 21 of the second sieve frame 3; the mud filtered by the first rotary vibration sieve 22 and the second rotary vibration sieve 31 falls on the upper surface of the chassis 41 in the third sieve frame 4 and is discharged from the discharge pipe 21 of the third sieve frame 4, and the mud discharged this time is qualified mud.

Referring to fig. 2 and 3, since the motor 6 drives the first and second rotary vibrating screens 22 and 31 to shake, the residence time of the sludge on the first and second rotary vibrating screens 22 and 31 is limited, so that the sludge is not sufficiently filtered. In order to solve the problem, the first rotary vibration sieve 22 includes a first sieve 221 and a second sieve 222, the second rotary vibration sieve 31 also includes the first sieve 221 and the second sieve 222, an outer side wall of the first sieve 221 is fixedly connected with an inner side wall of the second sieve 222, the upper surface of the second sieve 222 is connected with a plurality of first arch-shaped sieves 7, the plurality of first arch-shaped sieves 7 are distributed in a circle at intervals by taking an axis of the first sieve 221 as a center, the axis of the first arch-shaped sieve 7 is close to the axis of the first sieve 221, the number of the first arch-shaped sieves 7 on the upper surface of the first rotary vibration sieve 22 shown in the embodiment is four, and the number of the first arch-shaped sieves 7 on the upper surface of the second rotary vibration sieve 31 is also four.

During the dropping process of the slurry, the slurry firstly falls into the upper surface of the first screen cloth 221, and then is scattered on the upper surface of the first screen cloth 221, and during the scattering process of the slurry, the first arc-shaped screen cloth 7 further filters the slurry, so that the slurry is more fully filtered.

Part of the slurry will pass through between the adjacent first arc-shaped screens 7 and will not be filtered by the first arc-shaped screens 7, so the upper surface of the second screen 222 is further connected with a plurality of second arc-shaped screens 8, the arc length of the second arc-shaped screens 8 is longer than that of the first arc-shaped screens 7, the plurality of second arc-shaped screens 8 are distributed in a circle at intervals by taking the axis of the first screen 221 as the center, each second arc-shaped screen 8 is located between the adjacent first arc-shaped screens 7, the axis of the second arc-shaped screens 8 is close to the axis of the first screen 221, the number of the second arc-shaped screens 8 on the upper surface of the first rotary vibrating screen 22 shown in the embodiment is four, and the number of the second arc-shaped screens 8 on the upper surface of the second rotary vibrating screen 31 is also four. The second arch screens 8 may further filter the slurry passing between adjacent first arch screens 7.

Since the first arch-shaped screen 7 is closer to the axis of the first screen 221, and the second arch-shaped screen 8 is farther from the axis of the first screen 221, the slurry passing between the adjacent first arch-shaped screens 7 can be diffused, so that the arc length of the second arch-shaped screen 8 is longer than that of the first arch-shaped screen 7, and the second arch-shaped screen 8 can filter more slurry.

The second screen 222 is provided with a third arcuate screen 9 adjacent the discharge pipe 21, the third arcuate screen 9 re-filtering the slurry before the slurry is discharged from the discharge pipe 21, so that the slurry is filtered more thoroughly.

After the rotary vibration sieve is used, a first arc-shaped screen 7, a second arc-shaped screen 8 and a third arc-shaped screen 9 need to be cleaned, in order to conveniently clean the first arc-shaped screen 7, the second arc-shaped screen 8 and the third arc-shaped screen 9, each first arc-shaped screen 7 is detachably connected with the second screen 222 through a pair of chutes 10, each second arc-shaped screen 8 is also detachably connected with the second screen 222 through a pair of chutes 10, the lower end of each chute 10 is fixedly connected with the upper surface of the second screen 222, the first arc-shaped screen 7 is positioned between the corresponding pair of chutes 10 and is respectively inserted into the corresponding pair of chutes 10, and the second arc-shaped screen 8 is also positioned between the corresponding pair of chutes 10 and is respectively inserted into the corresponding pair of chutes 10; first bank 2 and second bank 3 are close to the equal fixedly connected with go-between 11 of inside wall of discharging pipe 21, the one end fixedly connected with connecting rod 12 in the axle center of first screen cloth 221 is kept away from to third sieve bend 9, connecting rod 12 pegs graft with the go-between 11 that corresponds, for further consolidating third sieve bend 9, the gag lever post 13 that the inside wall of first bank 2 still fixedly connected with and the third sieve bend 9 that corresponds were contradicted, the gag lever post 13 that the inside wall of second bank 3 also fixedly connected with and the third sieve bend 9 that corresponds were contradicted.

When the first arc-shaped screen 7 needs to be cleaned, the first arc-shaped screen 7 is taken down from the corresponding pair of sliding grooves 10 and cleaned; when the second arc-shaped screen 8 needs to be cleaned, the second arc-shaped screen 8 is taken down from the corresponding pair of sliding grooves 10 and cleaned; when the third arc-shaped screen 9 needs to be cleaned, the connecting rods 12 of the third arc-shaped screen 9 are taken down from the corresponding connecting rings 11, and the third arc-shaped screen 9 is cleaned.

The implementation principle of the rotary vibration sieve for efficient filtration is as follows:

when the mud needs to be filtered, the first arc-shaped screen 7 is inserted into the corresponding pair of sliding chutes 10; inserting the second arc-shaped screen 8 into a corresponding pair of chutes 10; and connecting rods 12 of the third arc-shaped screen 9 are inserted into the corresponding connecting rings 11.

The motor 6 is started, the mud enters the first sieve frame 2 from the feeding pipe 51 and falls into the upper surface of the first sieve net 221, the first sieve net 221 filters the mud for the first time, then the upper surface of the first sieve net 221 is scattered to the upper surface of the second sieve net 222, the first sieve bend 7 filters the mud again, the mud is filtered more fully, then the second sieve bend 8 can further filter the mud passing through the mud between the adjacent first sieve bend 7, when the mud is close to the discharging pipe 21, the third sieve bend 9 filters the mud again, the mud is filtered more thoroughly, and the mud blocks filtered by the first rotary vibration sieve 22 are discharged from the discharging pipe 21 of the first sieve frame 2.

The mud filtered by the first rotary vibration sieve 22 falls into the upper surface of the second rotary vibration sieve 31, the second rotary vibration sieve 31 is used for further filtering, the second rotary vibration sieve 31 sieves out large-particle objects in the mud, and the sieved large-particle objects are discharged from the discharge pipe 21 of the second sieve frame 3.

The mud filtered by the first rotary vibration sieve 22 and the second rotary vibration sieve 31 falls on the upper surface of the base plate 41 and is discharged from the discharge pipe 21 of the third sieve frame 4, and the mud discharged at this time is qualified mud.

When the first arc-shaped screen 7 needs to be cleaned, the first arc-shaped screen 7 is taken down from the corresponding pair of sliding grooves 10 and cleaned; when the second arc-shaped screen 8 needs to be cleaned, the second arc-shaped screen 8 is taken down from the corresponding pair of sliding grooves 10 and cleaned; when the third arc-shaped screen 9 needs to be cleaned, the connecting rods 12 of the third arc-shaped screen 9 are taken down from the corresponding connecting rings 11, and the third arc-shaped screen 9 is cleaned.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. The utility model provides a sieve that shakes soon of high efficiency filtration, includes base (1), first bank of screens (2) and shield (5), still includes motor (6), inlet pipe (51) have been seted up in shield (5), the internally mounted of first bank of screens (2) has first sieve (22) that shakes soon, discharging pipe (21), its characterized in that have been seted up to the lateral wall of first bank of screens (2): the first rotary vibration sieve (22) comprises a first sieve mesh (221) and a second sieve mesh (222), the first sieve mesh (221) and the second sieve mesh (222) are fixedly connected, the second sieve mesh (222) is connected with a plurality of first arc-shaped sieve meshes (7), and the first arc-shaped sieve meshes (7) are distributed for one circle at intervals by taking the axis of the first sieve mesh (221) as the center.

2. The high efficiency filtration rotary vibrating screen of claim 1, wherein: the first arc-shaped screen (7) is detachably connected with the second screen (222) through a pair of chutes (10), the pair of chutes (10) is fixedly connected with the second screen (222), and the first arc-shaped screen (7) is respectively spliced with the pair of chutes (10).

3. The high efficiency filtration rotary vibrating screen of claim 1, wherein: the second screen cloth (222) is further connected with a plurality of second arc-shaped screen cloths (8), the second arc-shaped screen cloths (8) are distributed in a circle at intervals by taking the axis of the first screen cloth (221) as the center, the second arc-shaped screen cloths (8) are close to the inner side wall of the first screen frame (2), the inner side wall of the first screen frame (2) is far away from the first arc-shaped screen cloth (7), and each second arc-shaped screen cloth (8) is located between the adjacent first arc-shaped screen cloths (7).

4. A high efficiency filtration rotary vibrating screen according to claim 3, wherein: the arc length of the second arc-shaped screen (8) is longer than that of the first arc-shaped screen (7).

5. The high efficiency filtration rotary vibrating screen of claim 1, wherein: and a third arc-shaped screen (9) is arranged at the position, close to the discharge pipe (21), of the second screen (222).

6. The high efficiency filtration rotary vibrating screen of claim 5, wherein: the inside wall fixedly connected with go-between (11) of first bank of screens (2), third arc screen cloth (9) are close to the one end fixedly connected with connecting rod (12) of first bank of screens (2), connecting rod (12) with go-between (11) are pegged graft.

7. The high efficiency filtration rotary vibrating screen of claim 6, wherein: the inner side wall of the first screen frame (2) is also fixedly connected with a limiting rod (13) which is abutted against the third arc-shaped screen (9).

8. The high efficiency filtration rotary vibrating screen of claim 1, wherein: still include second bank of screens (3), the internally mounted of second bank of screens (3) has second sieve (31) that shakes soon, the mesh number of second sieve (31) that shakes soon is greater than the mesh number of first sieve (22) that shakes soon.

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