CN209866267U - Improved glass crushing structure - Google Patents

Abstract

The utility model relates to an improved glass crushing structure, which comprises a crushing cavity, wherein two opposite sides of the upper part of the crushing cavity are provided with feed inlets, and one side of the crushing cavity is provided with a cutting structure; a first crushing structure and a second crushing structure are sequentially arranged in the crushing cavity from top to bottom; a discharge hole is formed in the bottom of the crushing cavity; the first crushing structure comprises a plurality of crushing rollers A which are arranged in a crushing cavity side by side, a plurality of convex cones are arrayed on the outer surface of each crushing roller A along the length direction of the outer surface of each crushing roller A, and the convex cones of the adjacent crushing rollers A are arranged in a staggered manner; the second crushing structure comprises a plurality of crushing rollers B which are arranged in the crushing cavity side by side, and the distance between every two adjacent crushing rollers B is smaller than the distance between every two adjacent crushing rollers A. The utility model has the advantages that: the efficiency of feeding is promoted to two feed inlet structures, and kibbling quality is promoted to two crushing structure.

Description

Improved glass crushing structure

Technical Field

The utility model relates to a glass processing technology field especially relates to an improvement type glass crushing structure.

Background

In the process of processing glass, defective products or damaged products are difficult to avoid, and the products are wasted if directly discarded, so that enterprises generally want to recycle the products. It is conventional practice to crush these glasses and then reuse them. Glass rubbing crusher among the prior art, generally kibbling efficiency is lower, and kibbling effect is also not ideal enough moreover, smashes the back on crushing apparatus usually, because kibbling degree is not enough, still must carry out secondary operation, increases work load on the one hand, and on the other hand has also increased operating time, the urgent need to improve.

SUMMERY OF THE UTILITY MODEL

Based on this, the utility model aims to provide an improvement type glass crushing structure, two feed inlet structures promote the efficiency of feeding, and two crushing structures promote kibbling quality.

The utility model provides an improved glass crushing structure, which comprises a crushing cavity, wherein two opposite sides of the upper part of the crushing cavity are provided with feed inlets, and one side of the crushing cavity is provided with a cutting structure; a first crushing structure and a second crushing structure are sequentially arranged in the crushing cavity from top to bottom; and a discharge hole is formed in the bottom of the crushing cavity.

First crushing structure includes a plurality of crushing roller A of installing in crushing intracavity side by side, crushing roller A's surface is provided with a plurality of protruding cones along its length direction array, and is adjacent crushing roller A's protruding cone dislocation set.

The second crushing structure comprises a plurality of crushing rollers B which are arranged in the crushing cavity side by side, and the distance between every two adjacent crushing rollers B is smaller than the distance between every two adjacent crushing rollers A.

The cutting structure comprises a conveying structure, a support A fixed above the conveying structure, a cutting driving motor fixed on the support A, and a glass cutting knife connected with the power output end of the cutting driving motor.

Preferably, the discharge port is funnel-shaped.

Preferably, the conveying structure comprises a support B, a conveying roller arranged on the support B, and a driving motor for driving the conveying roller.

Preferably, the bracket B is provided with a dust cover.

As a preferred scheme, the bottom of the discharge port is correspondingly provided with a material conveying vehicle.

Preferably, the conveying direction of the conveying roller corresponds to the position of the feed opening.

The utility model has the advantages that: the two opposite sides of the upper part of the crushing cavity are provided with the feed inlets, and during processing, the materials are fed from the two feed inlets simultaneously, so that the feeding efficiency is improved; a cutting structure is arranged on one side of the crushing cavity, a feed inlet on one side of the crushing cavity is matched with the cutting structure, for some glass with larger volume, the glass is firstly cut through the cutting structure and then enters the crushing cavity through the feed inlet to be crushed, and the crushing quality is improved; smash intracavity portion and set gradually first crushing structure and second crushing structure, carry out coarse crushing through first crushing structure, then rethread second crushing structure carries out fine crushing to further promote kibbling quality.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

The reference signs are: support B10, driving conveying roller 11, glass 12, support A13, feed inlet 14, crushing cavity 15, feed inlet 16, crushing roller A17, crushing roller B18, feed delivery vehicle 19, support C20, glass cutter 21, convex cone 22, discharge port 23, cutting driving motor 24 and dust cover 25.

Detailed Description

For further understanding of the features and technical means of the present invention, as well as the specific objects and functions attained by the present invention, the present invention will be described in further detail with reference to the accompanying drawings and detailed description.

Referring to fig. 1, an improved glass pulverizing structure includes a pulverizing chamber 15, the pulverizing chamber 15 is fixed on a support C20, two opposite sides of the upper portion of the pulverizing chamber 15 are provided with a feeding port 14 and a feeding port 16, and one side of the pulverizing chamber 15 is provided with a cutting structure; a first crushing structure and a second crushing structure are sequentially arranged in the crushing cavity 15 from top to bottom; the bottom of crushing chamber 15 is provided with discharge gate 23, and discharge gate 23 sets up to leak hopper-shaped. The bottom of the discharge port 23 is correspondingly provided with a movable material conveying vehicle 19.

The first crushing structure comprises a plurality of crushing rollers A17 which are arranged in the crushing cavity 15 side by side, a plurality of convex cones 22 are arranged on the outer surface of the crushing roller A17 along the length direction in an array mode, and the convex cones 22 of the adjacent crushing rollers A17 are arranged in a staggered mode; the grinding roller a17 is driven by a motor, and when the power supply is started, the grinding roller a17 starts to rotate, and the glass falling between the adjacent grinding rollers a17 is ground.

The second crushing structure comprises a plurality of crushing rollers B18 which are arranged in the crushing cavity 15 side by side, and the distance between two adjacent crushing rollers B18 is smaller than the distance between two adjacent crushing rollers A17; the grinding roller B18 is driven by a motor, and when the power supply is turned on, the grinding roller B18 starts to rotate, and the glass falling between the adjacent grinding rollers B18 is ground.

The cutting structure comprises a conveying structure, a support A13 fixed above the conveying structure, a cutting driving motor 24 fixed on the support A13, and a glass cutting knife 21 connected with the power output end of the cutting driving motor 24. The conveying structure comprises a support B10, a conveying roller 11 arranged on a support B10 and a driving motor for driving the conveying roller 11. The dust cover 25 is arranged on the bracket B10, and glass scraps are prevented from splashing in the cutting process through the dust cover 25. The conveying direction of the conveying roller 11 corresponds to the position where the feed opening 14 is located.

In practice, the feed ports 14 and 16 may be fed simultaneously. The glass 12 fed through the feed opening 14 is cut by the cutting structure. To the bigger glass of volume ratio, place on transfer roller 11 earlier, thereby driving motor drive transfer roller 11 rotates and drives glass and remove to the position of glass cutting knife 21 place, cuts glass through glass cutting knife 21 back, and feed inlet 14 is carried to the glass after rethread transfer roller 11 will cut to get into and smash in the chamber 15.

Enter into the glass in crushing chamber 15 through feed inlet 14 and feed inlet 16, carry out coarse crushing by crushing roller A17 of first crushing structure earlier, crushing roller A17 is last protruding awl 22 to roll glass after, and the glass is smashed and is fallen into the second crushing structure, smashes once more through crushing roller B18 to grind into the finer glass mince of volume, the rethread discharge gate 23 falls into defeated skip 19.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (6)

1. The utility model provides an improvement type glass crushing structure which characterized in that: the automatic feeding device comprises a crushing cavity (15), wherein feeding holes (14, 16) are formed in two opposite sides of the upper part of the crushing cavity (15), and a cutting structure is arranged on one side of the crushing cavity (15); a first crushing structure and a second crushing structure are sequentially arranged in the crushing cavity (15) from top to bottom; a discharge hole (23) is formed in the bottom of the crushing cavity (15);

the first crushing structure comprises a plurality of crushing rollers A (17) which are arranged in a crushing cavity (15) side by side, a plurality of convex cones (22) are arranged on the outer surface of each crushing roller A (17) in an array mode along the length direction of the outer surface, and the convex cones (22) of the adjacent crushing rollers A (17) are arranged in a staggered mode;

the second crushing structure comprises a plurality of crushing rollers B (18) which are arranged in a crushing cavity (15) side by side, and the distance between two adjacent crushing rollers B (18) is smaller than the distance between two adjacent crushing rollers A (17);

the cutting structure comprises a conveying structure, a support A (13) fixed above the conveying structure, a cutting driving motor (24) fixed on the support A (13), and a glass cutting knife (21) connected with the power output end of the cutting driving motor (24).

2. An improved glass pulverizing structure as defined in claim 1, characterized in that: the discharge hole (23) is arranged in a funnel shape.

3. An improved glass pulverizing structure as defined in claim 1, characterized in that: the conveying structure comprises a support B (10), a conveying roller (11) arranged on the support B (10), and a driving motor for driving the conveying roller (11).

4. An improved glass pulverizing structure as defined in claim 3, characterized in that: and a dust cover (25) is arranged on the bracket B (10).

5. An improved glass pulverizing structure as defined in any one of claims 1-4, characterized in that: the bottom of the discharge hole (23) is correspondingly provided with a material conveying vehicle (19).

6. An improved glass pulverizing structure as defined in claim 3, characterized in that: the conveying direction of the conveying roller (11) corresponds to the position of the feed inlet.