CN219129949U - Raw material pellet storage equipment for haydite sand preparation - Google Patents

Abstract

The utility model belongs to the technical field of ceramic particle sand production, and particularly provides raw material pellet storage equipment for ceramic particle sand preparation. The utility model can remove and separate and store the dust on the surface of the raw material pellets through collision, friction and airflow, prevent the dust from contacting with the raw material pellets again, prevent the dust generated in the dust removing process from polluting the air, store the raw material pellets, facilitate the powder recovery and improve the production efficiency of the raw material pellets.

Description

Raw material pellet storage equipment for haydite sand preparation

Technical Field

The utility model relates to the technical field of ceramic particle sand production, in particular to raw material pellet storage equipment for preparing ceramic particle sand.

Background

The ceramsite has a plurality of fine particles smaller than 5 mm, and the fine particles are screened out by a screening machine in production, so that the ceramsite is called ceramsite sand, the density of the ceramsite sand is slightly high, and the chemical and thermal stability is good; the ceramic sand is mainly used for preparing light aggregate concrete, light mortar and heat-resistant concrete fine aggregate by replacing natural river sand or mountain sand, and is also used for soilless culture and industrial filtration.

The ceramic sand is different according to different raw materials, but has several key steps of homogenization, double-roll granulation, roasting and cooling, raw material pellets for completing granulation work are usually stored, the existing raw material pellet storage device stores powder on the surfaces of the raw material pellets together in the storage process, so that a large amount of powder residues are accumulated in the storage device, the raw material waste phenomenon is caused, the yield of the raw material pellets is reduced, excessive dust can also influence the subsequent calcination process, a device is provided in CN202221074988.2, dust on the surfaces of ceramsite sand is brushed off and collected through a brush, and the brushed dust and ceramsite sand fall down simultaneously, so that the problem of reattachment exists; in the prior art, a raw material pellet storage device for preparing the ceramsite sand, which can remove external dust of the ceramsite sand, timely separate the dust from raw material pellets to prevent the raw material pellets from contacting again and store the raw material pellets, is lacking.

Disclosure of Invention

In order to solve the existing problems, the utility model provides a raw material pellet storage device for preparing ceramsite sand, which can remove and separate and store dust on the surface of raw material pellets, prevent the dust from contacting with the raw material pellets again, store the raw material pellets and facilitate the recovery of the powder; in order to solve the problem of powder adhesion on the surface of the raw material pellets, the feeding pipeline mechanism provided by the utility model can separate the powder from the pellets by the natural falling impact force of the pellets and the friction and collision with the speed reducing mechanism; in order to solve the problem that the fallen powder is easy to contact with the pellets again and adhere to the pellets, the dust separating and collecting mechanism provided by the utility model can separate and collect the dust from the pellets, so that the pellets are prevented from contacting again and the powder is convenient to recover; in order to solve the problems that excessive dust affects subsequent calcination and reduces the yield of raw material pellets, the raw material pellet storage box mechanism provided by the utility model can be used for secondarily separating powder and storing the raw material pellets, so that the powder removing effect is further improved.

The technical scheme adopted by the utility model is as follows: the utility model provides a haydite sand preparation is with raw material pellet storage facilities, includes feeding pipeline mechanism, goes dust mechanism of blowing, dust separation collection mechanism and raw material pellet bin mechanism, goes the dust mechanism of blowing and link up and locate feeding pipeline mechanism upper roof, and the diapire is located down to the dust separation collection mechanism, and raw material pellet bin mechanism locates feeding pipeline mechanism lateral wall.

Further, the dust removing and blowing mechanism comprises a dust removing and blowing box body and a dust removing and blowing fan, wherein the dust removing and blowing box body is communicated with the upper top wall of the feeding pipeline mechanism, and the dust removing and blowing fan is arranged on the inner side wall of the dust removing and blowing box body.

Further, the upper top wall of the dust removing blow box body is provided with a dust removing fan mounting frame.

Further, the dust removing blowing fan comprises a dust removing fan driving motor and dust removing fan blades, the dust removing fan driving motor is arranged on the upper top wall of the dust removing fan mounting frame, the power output end of the dust removing fan driving motor is communicated with the upper top wall of the dust removing fan mounting frame, the dust removing fan blades are arranged on the power output end of the dust removing fan driving motor, the dust removing fan driving motor drives the dust removing fan blades to rotate, and external air is blown into the feeding pipe body through the dust removing blowing box body.

Further, the dust separation and collection mechanism comprises a dust collection shell, a dust collection push-pull box body and a dust suction and exhaust mechanism, wherein the dust collection shell is arranged on the lower bottom wall of the feeding pipeline mechanism, the dust collection push-pull box body is slidably arranged on the inner bottom wall of the dust collection shell, and the dust suction and exhaust mechanism is communicated with the side wall of the dust collection shell.

Further, the dust suction exhaust mechanism comprises a dust exhaust box body, a dust collection exhaust fan and a dust filter plate, the dust exhaust box body is communicated with the side wall of the dust collection shell, the dust collection exhaust fan is rotationally arranged on the inner side wall of the dust exhaust box body, the dust filter plate is arranged on the inner side wall of the dust exhaust box body, the dust collection exhaust fan is rotationally arranged, air in the dust collection shell and in the feeding pipeline mechanism is filtered by the dust filter plate and then is discharged through the dust suction exhaust mechanism, most dust in the dust separation collection mechanism can fall into the dust collection push-pull box body, and a small amount of dust is adsorbed by the dust filter plate and finally falls into the dust collection push-pull box body.

Further, the feeding pipeline mechanism comprises a feeding pipe body and a pipeline dust filter screen, the upper top wall of the feeding pipe body is provided with a feeding hole, the pipeline dust filter screen is communicated with the lower bottom wall of the feeding pipe body, the lower bottom wall of the pipeline dust filter screen is fixedly connected with the upper top wall of the dust collecting shell, and the lower bottom wall of the dust removing blow box body is communicated with the upper top wall of the feeding pipe body.

Further, the upper top wall of the pipeline dust filter net is provided with a plurality of groups of pellet speed reducing columns, raw material pellets with dust enter the feeding pipeline mechanism from the feeding inlet, the raw material pellets fall on the pipeline dust filter net, the powder on the surface of the raw material pellets is separated from the pellets by impact, the raw material pellets move downwards along the feeding pipeline body, and the pellet speed reducing columns on the surface of the pipeline dust filter net can be in contact with the raw material pellets to reduce the falling speed of the pellets and further remove the dust by collision and friction.

Further, the raw material pellet storage box mechanism comprises a raw material pellet storage box body, a raw material pellet box door and a storage box body dust collection box, wherein the raw material pellet storage box body is communicated with the side wall of the feed pipe body, the raw material pellet box door is rotationally arranged on the outer side wall of the raw material pellet storage box body, and the storage box body dust collection box is slidably arranged on the inner bottom wall of the raw material pellet storage box body.

Further, the inner side wall of the raw material pellet storage box body is provided with a dust secondary filter screen, raw material pellets with surface powder removed enter the raw material pellet storage box mechanism through a feed pipe body, the pellets entering the raw material pellet storage box body fall to the dust secondary filter screen, redundant dust falls into a dust collection box of the storage box body through a dust secondary filter screen hole gap, raw material pellets are stored in the raw material pellet storage box body, and when the raw material pellet storage box is used, a raw material pellet box door is opened to take out the stored raw material pellets.

The beneficial effects obtained by the utility model by adopting the structure are as follows:

(1) The raw material pellet storage equipment for preparing the haydite sand can remove dust on the surface of the raw material pellet, separate and store the dust, prevent the dust from contacting with the raw material pellet again, store the raw material pellet and simultaneously facilitate powder recovery;

(2) The dust removing and blowing mechanism provided by the utility model can remove powder on the surface of the raw material pellets through air flow, and simultaneously blow off the fallen powder, so that the raw material pellets from which the powder is removed are prevented from contacting with the powder again;

(3) The dust separating and collecting mechanism provided by the utility model can suck the air with dust and discharge the air after filtering, the dust removing efficiency is enhanced by improving the airflow velocity, meanwhile, the dust can be prevented from flying, the air pollution in the powder removing process is prevented, in addition, the dust is separated and stored intensively, the raw material pellets are prevented from contacting the dust again, the powder can be conveniently recycled, and the production efficiency of the ceramic sand is improved;

(4) The raw material pellet storage box mechanism provided by the utility model can separate and collect a small amount of residual powder falling off from raw material pellets while storing the raw material pellets, prevent the powder from contacting the raw material pellets again, and improve the recycling rate of the powder;

(5) The pipeline dust filter screen provided by the utility model can enable air flow to pass through so as to improve the powder removal efficiency of the surface of the raw material pellets, the pellet speed reduction column on the surface of the pipeline dust filter screen can slow down the falling speed of the pellets, the dust removal time of the raw material pellets in the air flow is prolonged, and the powder removal efficiency can be further improved through collision and friction.

Drawings

FIG. 1 is a schematic perspective view of a raw material pellet storage device for preparing ceramsite sand according to the present utility model;

FIG. 2 is a schematic perspective view of a feed conduit mechanism according to the present utility model;

FIG. 3 is a partial view A of FIG. 2;

FIG. 4 is a perspective view of a dust blower hook according to the present utility model;

fig. 5 is a front cross-sectional view of a dust removing blower hook according to the present utility model;

FIG. 6 is a schematic perspective view of a dust separating and collecting mechanism according to the present utility model;

FIG. 7 is a front cross-sectional view of the dust suction and exhaust mechanism of the present utility model;

FIG. 8 is a schematic perspective view of a raw meal pellet bin mechanism according to the present utility model;

fig. 9 is a schematic perspective view of a raw pellet storage bin according to the present utility model.

Wherein, 1, feeding pipeline mechanism, 11, inlet pipe body, 111, feed inlet, 12, pipeline dust filter screen, 121, pellet deceleration column, 2, go dust blowing mechanism, 21, go dust blowing box, 211, go dust fan mounting bracket, 22, go dust blowing fan, 221, go dust fan driving motor, 222, go dust fan flabellum, 3, dust separation collection mechanism, 31, dust collection shell, 32, dust collection push-pull box, 33, dust suction exhaust mechanism, 331, dust exhaust box, 332, dust collection exhaust fan, 333, dust filter plate, 4, raw material pellet bin mechanism, 41, raw material pellet bin body, 411, dust secondary filter net, 42, raw material pellet bin door, 43, bin body dust collection box.

The accompanying drawings are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate the utility model and together with the embodiments of the utility model, serve to explain the utility model.

Detailed Description

The utility model will be described in further detail with reference to the accompanying drawings: as shown in fig. 1, the raw material pellet storage device for preparing the ceramsite sand comprises a feeding pipeline mechanism 1, a dust removing and blowing mechanism 2, a dust separating and collecting mechanism 3 and a raw material pellet storage box mechanism 4, wherein the dust removing and blowing mechanism 2 is communicated with the upper top wall of the feeding pipeline mechanism 1, the dust separating and collecting mechanism 3 is arranged on the lower bottom wall of the feeding pipeline mechanism 1, and the raw material pellet storage box mechanism 4 is arranged on the outer side wall of the feeding pipeline mechanism 1.

As shown in fig. 1 to 4, the dust blower mechanism 2 includes a dust blower box 21 and a dust blower fan 22, the dust blower box 21 is provided through the upper top wall of the feed pipe mechanism 1, and the dust blower fan 22 is provided on the inner side wall of the dust blower box 21.

As shown in fig. 1 to 5, a dust removing fan mounting frame 211 is provided on the upper top wall of the dust removing blow box body 21.

As shown in fig. 1 to 5, the dust blower fan 22 includes a dust blower fan driving motor 221 and dust blower fan blades 222, the dust blower fan driving motor 221 is disposed on the upper top wall of the dust blower fan mounting frame 211, the power output end of the dust blower fan driving motor 221 is disposed on the upper top wall of the dust blower fan mounting frame 211 in a penetrating manner, and the dust blower fan blades 222 are disposed on the power output end of the dust blower fan driving motor 221.

As shown in fig. 1 to 6, the dust separating and collecting mechanism 3 includes a dust collecting housing 31, a dust collecting push-pull box 32, and a dust suction and exhaust mechanism 33, the dust collecting housing 31 is provided on the lower bottom wall of the feed pipe mechanism 1, the dust collecting push-pull box 32 is slidably provided on the inner bottom wall of the dust collecting housing 31, and the dust suction and exhaust mechanism 33 is provided through the side wall of the dust collecting housing 31.

As shown in fig. 1 to 7, the dust suction and exhaust mechanism 33 includes a dust exhaust box 331, a dust collection exhaust fan 332, and a dust filter plate 333, the dust exhaust box 331 is disposed through the side wall of the dust collection housing 31, the dust collection exhaust fan 332 is rotatably disposed on the inner side wall of the dust exhaust box 331, and the dust filter plate 333 is disposed on the inner side wall of the dust exhaust box 331.

As shown in fig. 1 to 7, the feeding pipeline mechanism 1 comprises a feeding pipe body 11 and a pipeline dust filter screen 12, wherein a feeding inlet 111 is formed in the upper top wall of the feeding pipe body 11, the pipeline dust filter screen 12 is communicated with the lower bottom wall of the feeding pipe body 11, the lower bottom wall of the pipeline dust filter screen 12 is fixedly connected with the upper top wall of the dust collection shell 31, and the lower bottom wall of the dust removal blow box body 21 is communicated with the upper top wall of the feeding pipe body 11.

As shown in fig. 1 to 3, the upper top wall of the duct dust filter screen 12 is provided with a plurality of groups of pellet deceleration columns 121.

As shown in fig. 1 to 8, the raw material pellet storage tank mechanism 4 includes a raw material pellet storage tank 41, a raw material pellet tank door 42 and a storage tank dust collection box 43, the raw material pellet storage tank 41 is provided through the side wall of the feed pipe body 11, the raw material pellet tank door 42 is provided rotatably on the outer side wall of the raw material pellet storage tank 41, and the storage tank dust collection box 43 is provided slidably on the inner bottom wall of the raw material pellet storage tank 41.

As shown in fig. 1 to 9, the inside wall of the raw pellet storage box 41 is provided with a dust secondary filter 411.

In specific use, raw material pellets with dust enter the feeding pipeline mechanism 1 from the feeding port 111, the raw material pellets freely fall in the feeding pipeline body 11 and fall on the pipeline dust filter screen 12, the powder on the surface of the raw material pellets is separated from the pellets by impact, the raw material pellets move downwards along the feeding pipeline body 11, the pellet speed reduction column 121 on the surface of the pipeline dust filter screen 12 can be in contact with the raw material pellets, the falling speed of the pellets is slowed down by impact and friction, and meanwhile, the dust is further removed.

When the raw material pellets enter the feed inlet 111, the dust removing blower 2 and the dust separating and collecting mechanism 3 start to work, the dust removing fan driving motor 221 drives the dust removing fan blade 222 to rotate, external air is blown into the feed pipe body 11 through the dust removing blower body 21, the dust removing blower 2 blows powder falling off from the surface of the raw material pellets in the feed pipe body 11 into the dust separating and collecting mechanism 3 through the holes of the pipeline dust filter screen 12, the dust collecting exhaust fan 332 rotates, air in the dust collecting shell 31 and in the feed pipe body 11 is filtered by the dust filter plate 333 and then is discharged through the dust sucking and exhausting mechanism 33, most dust in the dust separating and collecting mechanism 3 falls into the dust collecting push-pull box 32, and a small number of dust is adsorbed by the dust filter plate 333 and finally falls into the dust collecting push-pull box 32.

Raw material pellets with surface powder removed enter the raw material pellet storage box mechanism 4 through the feed pipe body 11, the pellets entering the raw material pellet storage box body 41 fall to the dust secondary filter screen 411, redundant dust falls into the storage box body dust collection box 43 through the holes of the dust secondary filter screen 411, raw material pellets are stored in the raw material pellet storage box body 41, and when in use, the raw material pellet box door 42 is opened to take out the stored raw material pellets.

When the dust is collected to a certain amount, the dust collection push-pull box 32 and the storage box dust collection box 43 are pulled out to clean the dust inside and reload.

The present utility model and its embodiments have been described above with no limitation, and the embodiments of the present utility model are shown in the drawings, and the actual structure is not limited thereto, so that those skilled in the art who have the ordinary skill in the art who have the benefit of the present utility model will not creatively design similar structures and examples to those of the present utility model without departing from the gist of the present utility model.

Claims (10)

1. Raw material pellet storage equipment for haydite sand preparation, including feeding pipeline mechanism (1), its characterized in that: the device is characterized by further comprising a dust removing and blowing mechanism (2), a dust separating and collecting mechanism (3) and a raw material pellet storage box mechanism (4), wherein the dust removing and blowing mechanism (2) is communicated with the upper top wall of the feeding pipeline mechanism (1), the dust separating and collecting mechanism (3) is arranged on the lower bottom wall of the feeding pipeline mechanism (1), and the raw material pellet storage box mechanism (4) is arranged on the outer side wall of the feeding pipeline mechanism (1).

2. The raw material pellet storage apparatus for ceramic sand production according to claim 1, wherein: the dust removing and blowing mechanism (2) comprises a dust removing and blowing box body (21) and a dust removing and blowing fan (22), the dust removing and blowing box body (21) is communicated with the upper top wall of the feeding pipeline mechanism (1), and the dust removing and blowing fan (22) is arranged on the inner side wall of the dust removing and blowing box body (21).

3. A raw material pellet storage apparatus for ceramic sand production as claimed in claim 2, wherein: the upper top wall of the dust removing blow box body (21) is provided with a dust removing fan mounting frame (211).

4. A raw material pellet storage apparatus for ceramic sand production as claimed in claim 3, wherein: the dust removing blowing fan (22) comprises a dust removing fan driving motor (221) and dust removing fan blades (222), the dust removing fan driving motor (221) is arranged on the upper top wall of the dust removing fan mounting frame (211), the power output end of the dust removing fan driving motor (221) is communicated with the upper top wall of the dust removing fan mounting frame (211), and the dust removing fan blades (222) are arranged at the power output end of the dust removing fan driving motor (221).

5. The raw material pellet storage equipment for preparing ceramsite sand according to claim 4, wherein: the dust separation and collection mechanism (3) comprises a dust collection shell (31), a dust collection push-pull box body (32) and a dust suction and exhaust mechanism (33), wherein the dust collection shell (31) is arranged on the lower bottom wall of the feeding pipeline mechanism (1), the dust collection push-pull box body (32) is slidably arranged on the inner bottom wall of the dust collection shell (31), and the dust suction and exhaust mechanism (33) is communicated with the side wall of the dust collection shell (31).

6. The raw material pellet storage equipment for preparing ceramsite sand according to claim 5, wherein: the dust suction exhaust mechanism (33) comprises a dust exhaust box body (331), a dust collection exhaust fan (332) and a dust filter plate (333), the dust exhaust box body (331) is communicated with the side wall of the dust collection shell (31), the dust collection exhaust fan (332) is rotationally arranged on the inner side wall of the dust exhaust box body (331), and the dust filter plate (333) is arranged on the inner side wall of the dust exhaust box body (331).

7. The raw material pellet storage apparatus for ceramic sand production as claimed in claim 6, wherein: the feeding pipeline mechanism (1) comprises a feeding pipe body (11) and a pipeline dust filter screen (12), a feeding inlet (111) is formed in the upper top wall of the feeding pipe body (11), the pipeline dust filter screen (12) is communicated with the lower bottom wall of the feeding pipe body (11), the lower bottom wall of the pipeline dust filter screen (12) is fixedly connected with the upper top wall of a dust collecting shell (31), and the lower bottom wall of the dust removing blow box body (21) is communicated with the upper top wall of the feeding pipe body (11) in a fixed connection mode.

8. The raw material pellet storage apparatus for ceramic sand production as claimed in claim 7, wherein: the upper top wall of the pipeline dust filter screen (12) is provided with a plurality of groups of pellet retarding columns (121).

9. The raw material pellet storage apparatus for ceramic sand production as claimed in claim 8, wherein: the raw material pellet storage box mechanism (4) comprises a raw material pellet storage box body (41), a raw material pellet box door (42) and a storage box body dust collection box (43), wherein the raw material pellet storage box body (41) is communicated with the side wall of the feeding pipe body (11), the raw material pellet box door (42) is rotationally arranged on the outer side wall of the raw material pellet storage box body (41), and the storage box body dust collection box (43) is slidably arranged on the inner bottom wall of the raw material pellet storage box body (41).

10. The raw material pellet storage apparatus for ceramic sand production as claimed in claim 9, wherein: the inner side wall of the raw material pellet storage box body (41) is provided with a dust secondary filter screen (411).

Images