CN211521029U - Glass raw material dust removal system - Google Patents

Abstract

The utility model discloses the application belongs to the technical field that the raw materials removed dust, specifically discloses a glass raw materials dust pelletizing system, including a reaction section of thick bamboo and a collecting vessel, the inside cavity of collecting vessel, the coaxial fixedly connected with magazine of collecting vessel, the magazine with the reaction section of thick bamboo intercommunication, a plurality of first suction holes have been seted up on the top of collecting vessel, the collecting vessel intercommunication has the air exhauster. The utility model discloses can avoid the dust to fly upward and be thrown the material workman and absorb when throwing the material.

Description

Glass raw material dust removal system

Technical Field

The utility model discloses the application belongs to the technical field that the raw materials removed dust, specifically discloses a glass raw materials dust pelletizing system.

Background

In the production and manufacturing process of glass, raw materials for manufacturing glass need to be fed into a reaction cylinder (such as a smelting furnace) through a feeding hopper, so that the raw materials generate a series of reactions in the reaction cylinder, however, powder materials are often mixed in the fed raw materials, so that the powder materials in the raw materials will scatter and fly around the feeding hopper during feeding, the flying of dust will pollute the processing environment, and workers are liable to suck the dust during feeding, thus harming their health.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a glass raw materials dust pelletizing system aims at can avoiding the dust to be thrown the absorption of material workman when throwing the material.

In order to achieve the above object, the basic scheme of the utility model is:

glass raw materials dust pelletizing system, including reaction cylinder and collecting vessel, the inside cavity of collecting vessel, the coaxial fixedly connected with feeding hopper of collecting vessel, feeding hopper with the reaction cylinder intercommunication, a plurality of first suction holes have been seted up on the top of collecting vessel, the collecting vessel intercommunication has the air exhauster.

The working principle and the beneficial effects of the basic scheme are as follows:

1) through set up the collecting vessel on the reaction cylinder among this technical scheme, and set up feeding hopper on the collecting vessel, such setting can avoid directly producing the dust when throwing the material to the reaction cylinder and fly upward, in this technical scheme when throwing the material, can directly throw into the reaction cylinder through feeding hopper on the collecting vessel in and with the raw materials, then will make the dust that flies upward collect in can being inhaled the collecting vessel through starting the air exhauster, avoid the dust to fly upward everywhere, pollute the processing environment, and then avoid the dust to be inhaled by the workman and harm workman's healthy.

2) A plurality of suction holes are formed in the bottom of the collecting cylinder in the technical scheme, so that the dust absorption effect can be improved, and the dust absorption efficiency is improved.

Further, the feeding hopper is funnel-shaped.

So set up the area that can increase the input raw materials, and can promote the speed of raw materials whereabouts, make the entering reaction section of thick bamboo that the raw materials can be quick.

Furthermore, the collecting cylinder is cylindrical, a discharge hole is formed in the bottom end of the collecting cylinder, the feeding hopper is located in the discharge hole, and a gap is formed between the feeding hopper and the side wall of the discharge hole.

The gap has between discharge opening and the magazine, and such setting can make the dust that inhales in the collecting vessel drop to the reaction tube in react, makes the dust of collecting can carry out recycle.

Further, a plurality of the first suction holes are uniformly distributed along the circumferential direction of the collecting cylinder.

So set up, can make the dust absorption more even, and can enlarge the absorption scope to the dust, improved dust collection efficiency.

Furthermore, a protective cover is arranged on the collecting cylinder, the feeding hopper is positioned in the protective cover, and the top end of the feeding hopper is positioned at the lower part of the protective cover.

The setting of protection casing among this technical scheme can further improve the absorption effect to the dust, makes the workman when throwing the material, has the space of relative confined, can reduce the flow space of dust to the negative pressure that makes the air exhauster produce is stronger, and is better to the absorption effect of dust.

Further, the outer side of the collecting cylinder is coaxially connected with a mounting ring, a circle of sliding groove is coaxially formed in the mounting ring, and the protective cover is inserted into the sliding groove. So set up, make things convenient for the installation of protective housing.

Further, the inside cavity of protection casing, a plurality of second suction holes have been seted up to the inside wall of protection casing, the bottom of protection casing with the surge drum communicates each other.

The second suction hole has been seted up through the inside wall at the protection casing among this technical scheme, can improve the absorption effect to the dust, has effectively reduced the scope that the dust flies upward, and owing to at the in-process of input raw materials, the dust is usually to diffusion all around, and the protection casing is owing to be located the outside of magazine, therefore the protection casing can play more effectual absorption to the dust of diffusion all around.

Furthermore, the side wall of the protective cover is provided with a notch.

The setting up of breach conveniently throws the material workman and will be equipped with the container of raw materials and place in breach department to throw the material to throwing hopper, the height of throwing in the raw materials has been avoided having increased because of the setting of protection casing to the setting of breach, thereby makes to throw the material workman and can be more smooth, the more light throw in the raw materials to the reaction cylinder.

Further, the protection casing and the spout sliding fit.

So set up, can be through rotating the protection casing, the direction of adjustment breach to make and throw the material workman and can throw the material in the position of difference, throw the material convenient more, nimble.

Further, the bottom end of the notch is higher than the top end of the feeding hopper.

So set up can be when throwing the material, the bottom of breach can play the supporting role to the container that is equipped with the raw materials, and more convenient operation when empting the raw materials.

Drawings

FIG. 1 is a perspective view of a first embodiment of the glass raw material dust removing system of the present invention;

FIG. 2 is a top view of a first embodiment of the glass feedstock dedusting system of the present invention;

FIG. 3 is a cross-sectional view taken along line A-A of FIG. 2;

FIG. 4 is a perspective view of a second embodiment of the glass raw material dust removing system of the present invention;

FIG. 5 is a top view of a second embodiment of the glass feedstock dedusting system of the present invention;

FIG. 6 is a cross-sectional view taken along line B-B of FIG. 5;

fig. 7 is a partial enlarged view at C in fig. 6.

Detailed Description

The following is further detailed by way of specific embodiments:

reference numerals in the drawings of the specification include: reaction cylinder 1, feed port 2, collecting cylinder 3, hopper 4, collar 5, first suction opening 6, protection casing 7, breach 8, air exhauster 9, play tuber pipe 10, discharge opening 11, cavity 12, second suction opening 13, connecting pipe 14.

Example one

The embodiment is basically as shown in the attached figure 1: glass raw materials dust pelletizing system, including reaction cylinder 1 and collecting cylinder 3, collecting cylinder 3 is located reaction cylinder 1's top, and collecting cylinder 3 passes through bolt fixed connection with reaction cylinder 1. As shown in fig. 2 and fig. 3, the collecting cylinder 3 is hollow, the collecting cylinder 3 is a cylindrical structure, a discharge hole 11 is formed at the bottom end of the collecting cylinder 3 and located at the center thereof, a feed hole 2 is formed at the top end of the reaction cylinder 1 and located at the center thereof, and the discharge hole 11 at the bottom end of the collecting cylinder 3 is communicated with the feed hole 2 at the top end of the reaction cylinder 1.

Collecting cylinder 3 is fixed with feeding hopper 4 with coaxial welding, and feeding hopper 4 in this embodiment is hourglass hopper-shaped, and the bottom of feeding hopper 4 is located the feed port 2 of reaction cylinder 1, and feeding hopper 4 bottom is uncovered to make feeding hopper 4 and reaction cylinder 1 communicate, have the gap between the lateral wall of discharge opening 11 and feeding hopper 4, such setting can make the dust that gets into in collecting cylinder 3 fall into in reaction cylinder 1.

As shown in fig. 2, a plurality of first suction holes 6 are formed at the top end of the collecting cylinder 3, and the plurality of first suction holes 6 are uniformly distributed along the circumferential direction of the collecting cylinder 3. Combine shown in fig. 3, the right side intercommunication of surge drum 3 has a tuber pipe 10, and bolt fixedly connected with air exhauster 9 is passed through on the right side of surge drum 3, and the one end that goes out tuber pipe 10 is located surge drum 3, and the other end that goes out tuber pipe 10 communicates with air exhauster 9, and the one end of keeping away from air exhauster 9 at play tuber pipe 10 is passed through screw fixedly connected with and is filtered the piece, if the dust removal sack, filter and can avoid inspiratory dust to be inhaled inside air exhauster 9.

Referring to fig. 1, in the embodiment, a protective cover 7 is arranged outside the collecting cylinder 3, the feeding hopper 4 is positioned in the protective cover 7, and the top end of the feeding hopper 4 is positioned at the lower part of the protective cover 7. 3 outside coaxial weld of surge drum is fixed with collar 5, and collar 5 is located the upper portion of surge drum 3, the coaxial round of having seted up in collar 5 is annular spout, protection casing 7 is cylindricly, and the upper end and the lower extreme of protection casing 7 are the opening end, protection casing 7 inserts in the spout, the thickness of protection casing 7 is less than the width of spout in this embodiment, thereby make the gap between protection casing 7 and the spout, make protection casing 7 and spout sliding fit, protection casing 7 can be along the circumferential direction of spout promptly.

The side wall of the protective cover 7 is provided with a notch 8, and the width of the notch 8 is set according to a container adopted by a manufacturer when loading glass raw materials, so that the container loading the glass raw materials can be placed at the notch 8. In this embodiment, the bottom end of the notch 8 is higher than the top end of the feeding hopper 4, so that the container loaded with the glass raw materials can be placed at the bottom end of the notch 8 and then the glass raw materials in the container can be poured backwards, and the labor is saved.

When the glass material feeding device is used, a feeding worker firstly starts the exhaust fan 9 when needing to feed materials, then the feeding worker places a container filled with glass materials in the notch 8, and then the container is aligned to the feeding hopper 4 to dump the materials in the container, so that the materials fall into the reaction cylinder 1 from the feeding hopper 4 to carry out chemical reaction.

In the in-process of input raw materials, because it has the dust to press from both sides the sediment in the raw materials, consequently in-process to input hopper 4 input raw materials, the dust will fly upward the diffusion all around, however under the effect of protection casing 7, can play certain effect of sheltering from to the dust, the negative pressure that air exhauster 9 produced will absorb the dust that flies upward simultaneously to make in the dust is collected the collecting vessel 3, avoid the dust to fly upward and cause environmental pollution, avoid simultaneously throwing the material workman and inhale a large amount of dust and harm healthy.

Example two

As shown in fig. 4, 5 and 6, the glass raw material dust removing system is different from the first embodiment in that: the collar 5 is located the top of surge drum 3 and passes through bolt fixed connection with surge drum 3 in this embodiment, the diameter of surge drum 3 is greater than the diameter of collar 5 in this embodiment, and collar 5 is located the central authorities of surge drum 3, the inside cavity 12 of having seted up of protection casing 7, and the inside wall of protection casing 7 has seted up a plurality of seconds and has inhaled hole 13, hole 13 is inhaled to the second communicates with each other with cavity 12 of protection casing 7, hole 13 is inhaled to the second in this embodiment is equipped with two-layerly, hole 13 is inhaled to every layer second all is equipped with a plurality ofly, hole 13 is inhaled all along the circumference evenly distributed of protection casing 7 to a plurality of seconds of every layer.

The bottom of the protective cover 7 is communicated with the collecting cylinder 3. Combine shown in fig. 7, there are a plurality of connecting pipes 14 at the top intercommunication of surge drum 3, and a plurality of through-holes have been seted up to the bottom of protection casing 7 along the circumference evenly distributed of surge drum 3 to a plurality of connecting pipes 14, the one end and the surge drum 3 intercommunication of connecting pipe 14, the other end of connecting pipe 14 stretch into in the through-hole with the bottom of protection casing 7 communicate each other to make the effect that protection casing 7 and surge drum 3 realized the intercommunication.

In this embodiment, after the exhaust fan 9 is started, the negative pressure generated by the exhaust fan 9 can absorb dust from the first suction hole 6 and can absorb dust from the second suction hole 13 on the inner side of the protection cover 7, so that the dust absorption area is enlarged, and the dust absorption effect is effectively improved.

The above description is only an example of the present invention, and the common general knowledge of the known specific structures and characteristics of the embodiments is not described herein. It should be noted that, for those skilled in the art, without departing from the structure of the present invention, several modifications and improvements can be made, which should also be regarded as the protection scope of the present invention, and these will not affect the effect of the implementation of the present invention and the practicability of the patent.

Claims (10)

1. The glass raw material dust removal system is characterized by comprising a reaction cylinder and a collecting cylinder, wherein the collecting cylinder is hollow, a feeding hopper is fixedly connected with the collecting cylinder in a coaxial mode and communicated with the reaction cylinder, a plurality of first suction holes are formed in the top end of the collecting cylinder, and an exhaust fan is communicated with the collecting cylinder.

2. The glass feedstock dusting system of claim 1 wherein the hopper is funnel shaped.

3. The glass raw material dust removal system according to claim 1, wherein the collection barrel is cylindrical, a discharge hole is formed in the bottom end of the collection barrel, the feeding hopper is located in the discharge hole, and a gap is formed between the feeding hopper and the side wall of the discharge hole.

4. The glass feedstock dusting system of claim 3 wherein a plurality of the first suction holes are evenly distributed along a circumference of the collection canister.

5. The glass raw material dedusting system of claim 1, wherein a protective cover is disposed on the collection cylinder, the feeding hopper is disposed in the protective cover, and a top end of the feeding hopper is disposed at a lower portion of the protective cover.

6. The glass raw material dedusting system of claim 5, wherein a mounting ring is coaxially connected to the outer side of the collecting cylinder, a circle of sliding groove is coaxially formed in the mounting ring, and the protective cover is inserted into the sliding groove.

7. The glass raw material dedusting system of claim 6, wherein the inside of the protective cover is hollow, a plurality of second suction holes are formed in the inner side wall of the protective cover, and the bottom of the protective cover is communicated with the collecting barrel.

8. The glass feedstock dedusting system of claim 6 or 7, wherein the side wall of the shield is notched.

9. A glass feedstock dusting system according to claim 8 wherein the protective cover is in sliding engagement with the chute.

10. The glass feedstock dusting system of claim 8 wherein a bottom end of the notch is higher than a top end of the hopper.

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