CN217866568U - Herringbone curve coal dropping pipe structure - Google Patents

Abstract

The utility model discloses a herringbone curve coal breakage pipe structure, which relates to the technical field of coal breakage pipes, and provides the following scheme, comprising a material distribution pipe and a material distribution mechanism arranged outside the material distribution pipe, wherein the material distribution mechanism comprises a swing assembly, a connecting assembly and a material distribution assembly; the swing assembly comprises a material distribution motor, a rotating plate, a swing plate and a swing guide groove, the material distribution motor is fixedly connected to the outer wall of the material distribution pipe, the rotating plate is mounted at the output end of the material distribution motor, the swing plate in rotary connection with the outer wall of the material distribution pipe is movably connected to one end of the rotating plate, and the swing guide groove is formed in the connection position of the swing plate and the rotating plate; the connecting assembly comprises a driving guide plate and a material distribution guide groove, and the rotating guide pillar rotates to drive the connecting plate and the material distribution pipe to move relatively through the connecting plate by arranging two groups of vibrating plates, so that the connecting plate moves to drive two groups of coal breakage pipe bodies to vibrate synchronously through the two groups of vibrating plates, and the vibration cleaning operation of coal attached to the inner walls of the two groups of coal breakage pipe bodies is realized.

Description

Herringbone curve coal dropping pipe structure

Technical Field

The utility model relates to a coal breakage pipe technical field especially relates to a chevron shape curve coal breakage tubular construction.

Background

The coal conveying device comprises a coal conveying device, a coal receiving belt, a coal conveying device and a coal conveying device, wherein the coal conveying device comprises a coal conveying device, a coal receiving belt and a coal receiving pipe, the coal receiving belt is arranged on the coal conveying device, the coal conveying device comprises a coal receiving belt, a coal receiving belt and a coal conveying pipe, the coal receiving belt is arranged on the coal conveying device, the coal conveying device comprises a coal receiving belt, a coal conveying pipe and a coal conveying pipe, the coal receiving belt is arranged on the coal conveying pipe, the coal conveying pipe is arranged on the coal receiving belt, and the coal conveying pipe is arranged below the coal receiving belt.

However, when the herringbone curved coal dropping pipe structure in the prior art is used, coal can be attached to the inner wall of the coal dropping pipe, so that the diameter of the coal dropping pipe is reduced, the coal dropping pipe is easy to block, the use requirement of people is not met, and the herringbone curved coal dropping pipe structure is needed.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a chevron shape curve coal breakage tubular construction has solved the problem that the coal that exists among the prior art can be attached to the coal breakage intraductal wall.

In order to achieve the above object, the utility model provides a following technical scheme: a herringbone curve coal breakage pipe structure comprises a material distribution pipe and a material distribution mechanism arranged outside the material distribution pipe, wherein the material distribution mechanism comprises a swinging assembly, a connecting assembly and a material distribution assembly;

the swing assembly comprises a material distribution motor, a rotating plate, a swing plate and a swing guide groove, the material distribution motor is fixedly connected to the outer wall of the material distribution pipe, the rotating plate is mounted at the output end of the material distribution motor, the swing plate in rotary connection with the outer wall of the material distribution pipe is movably connected to one end of the rotating plate, and the swing guide groove is formed in the connection position of the swing plate and the rotating plate;

the connecting assembly comprises a driving guide plate and a material distribution guide groove, the top end of the swinging plate is movably connected with the driving guide plate which is screwed with the outer wall of the material distribution pipe, and the material distribution guide groove is formed in the connecting part of the driving guide plate and the swinging plate;

the material distributing assembly comprises a rotating shaft, a material distributing plate and a material distributing hopper, wherein the rotating shaft is connected with the outer wall of the material distributing pipe in a rotating mode through one end of the driving guide plate, the material distributing plate is fixedly connected with the inner wall of the material distributing pipe through one end of the rotating shaft, and the material distributing hopper is fixedly connected with the bottom end of the material distributing pipe below the material distributing plate.

Preferably, the top end of the material distributing pipe is fixedly connected with a connecting pipe, the top end of the connecting pipe is fixedly connected with a feed inlet, the bottom end of the material distributing funnel is fixedly connected with a coal dropping pipe body, the bottom end of the material distributing funnel is located on one side of the coal dropping pipe body and is fixedly connected with a vibration motor, a rotary disc is installed at the output end of the vibration motor, the bottom end edge of the rotary disc is fixedly connected with a rotary guide pillar, the outer wall of the rotary guide pillar is screwed with a connecting plate, one end of the connecting plate is screwed with a connecting plate, and one end of the connecting plate is fixedly connected with a vibration plate fixedly connected with the outer wall of the coal dropping pipe body.

Preferably, the swing plate forms a swing structure with the material distributing pipe through the rotating plate and the swing guide groove, and the swing center of the swing plate and the rotation center of the rotating plate are located on the same vertical plane.

Preferably, the driving guide plate forms a swing structure with the material distributing pipe through the swing plate and the material distributing guide groove, and the swing angle of the driving guide plate is equal to the included angle of the bottom end of the material distributing pipe.

Preferably, the distribution hoppers are arranged in two groups, and the position relation of the two groups of distribution hoppers is symmetrical about the distribution pipe.

Preferably, the connecting plate forms a telescopic structure with the material distributing pipe through the rotating guide pillar and the connecting plate, and the vibrating plates are provided with two groups.

Preferably, the vibration plate is tightly attached to the outer wall of the coal dropping pipe body, and the vibration plate is connected with the coal dropping pipe body through a connecting plate to form a vibration structure.

Compared with the prior art, the beneficial effects of the utility model are that:

through setting up two sets of vibration boards, rotatory guide pillar rotates and drives through the connecting plate and connect even board and branch material pipe relative motion to make and connect even board motion and drive two sets of coal breakage body synchronous oscillation through two sets of vibration boards, realize the vibration cleaning operation to the attached coal of two sets of coal breakage body inner walls.

Drawings

Fig. 1 is a schematic view of the overall structure of a herringbone curved coal chute structure provided by the present invention;

fig. 2 is a schematic view of a material distributing pipe connection structure of a herringbone curve coal dropping pipe structure provided by the utility model;

fig. 3 is a schematic view of a connection structure of a distributing plate of a herringbone curved coal chute structure provided by the utility model;

fig. 4 is a schematic view of a connection connecting plate of a herringbone curved coal chute structure provided by the present invention.

In the figure: 1-distributing pipe; 2-a material distributing motor; 3-rotating the plate; 4-a swing plate; 5-swinging the guide groove; 6-active guide plate; 7-a material distributing guide groove; 8-a rotating shaft; 9-material distributing plate; 10-a material separating funnel; 11-a connecting tube; 12-a feed inlet; 13-a coal dropping pipe body; 14-a vibration motor; 15-a turntable; 16-rotating the guide post; 17-a connecting plate; 18-connecting the connecting plate; 19-vibrating plate.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Example 1

As shown in fig. 1 to 3, the illustrated herringbone curved coal dropping pipe structure includes a material distributing pipe 1 and a material distributing mechanism disposed outside the material distributing pipe 1, where the material distributing mechanism includes a swing assembly, a connecting assembly, and a material distributing assembly;

the swinging assembly comprises a material distributing motor 2, a rotating plate 3, a swinging plate 4 and a swinging guide groove 5, the material distributing motor 2 is fixedly connected to the outer wall of the material distributing pipe 1, the rotating plate 3 is installed at the output end of the material distributing motor 2, the swinging plate 4 which is in screwed connection with the outer wall of the material distributing pipe 1 is movably connected to one end of the rotating plate 3, and the swinging guide groove 5 is formed in the connecting part of the swinging plate 4 and the rotating plate 3;

the connecting assembly comprises a driving guide plate 6 and a material distribution guide groove 7, the top end of the swinging plate 4 is movably connected with the driving guide plate 6 which is screwed with the outer wall of the material distribution pipe 1, and the material distribution guide groove 7 is arranged at the connecting part of the driving guide plate 6 and the swinging plate 4;

divide the material subassembly to include pivot 8, divide flitch 9 and divide material funnel 10, the pivot 8 that the one end fixedly connected with of initiative baffle 6 connect soon with the material pipe 1 outer wall that divides, the one end of pivot 8 extends to the inner wall fixedly connected with that divides material pipe 1 and divides the flitch 9, divides the bottom fixedly connected with that the flitch 9 is located the material pipe 1 that divides below to divide material funnel 10.

As shown in fig. 3, the swing plate 4 forms a swing structure with the material distribution pipe 1 through the rotating plate 3 and the swing guide groove 5, and the swing center of the swing plate 4 and the rotation center of the rotating plate 3 are located on the same vertical plane, which is beneficial to the rotation of the rotating plate 3 and the swing of the swing plate 4 driven by the swing guide groove 5, so as to realize the swing control operation of the swing plate 4.

As shown in fig. 3, the driving guide plate 6 forms a swing structure with the material distributing pipe 1 through the swing plate 4 and the material distributing guide groove 7, and a swing angle of the driving guide plate 6 is equal to an included angle of the bottom end of the material distributing pipe 1, so that the swing plate 4 can swing to drive the driving guide plate 6 to rotate through the material distributing guide groove 7, and the rotation of the driving guide plate 6 can be controlled.

As shown in fig. 1, two sets of distribution hoppers 10 are provided, the two sets of distribution hoppers 10 are symmetrical with respect to the distribution pipe 1, and the two sets of distribution hoppers 10 are provided, so that the control operation of coal classification and blanking is facilitated.

Example 2

As shown in fig. 1 and fig. 4, in this embodiment, further describing example 1, a connecting pipe 11 is fixedly connected to a top end of the distributing pipe 1, a feeding port 12 is fixedly connected to a top end of the connecting pipe 11, a coal dropping pipe body 13 is fixedly connected to a bottom end of the distributing hopper 10, a vibration motor 14 is fixedly connected to one side of the coal dropping pipe body 13 at the bottom end of the distributing hopper 10, a rotary table 15 is installed at an output end of the vibration motor 14, a rotary guide pillar 16 is fixedly connected to a bottom end edge of the rotary table 15, a connecting plate 17 is screwed to an outer wall of the rotary guide pillar 16, one end of the connecting plate 17 is screwed to a connecting plate 18, a vibration plate 19 fixedly connected to an outer wall of the coal dropping pipe body 13 is fixedly connected to one end of the connecting plate 18, which facilitates the vibration motor 14 to drive the rotary guide pillar 16 to rotate through the rotary table 15, the rotary guide pillar 16 rotates to drive the connecting plate 18 to move relative to the distributing pipe 1 through the connecting plate 17, so that the connecting plate 18 moves to drive two groups of coal dropping pipe bodies 13 to vibrate synchronously through the two groups of vibration plates 19, and thus realizing vibration cleaning operation of coal adhered to the inner walls of the two groups of coal dropping pipe bodies 13.

As shown in fig. 3, the connecting plate 18 and the distributing pipe 1 form a telescopic structure through the rotating guide post 16 and the connecting plate 17, and two groups of vibrating plates 19 are arranged, so that the rotating guide post 16 rotates to drive the connecting plate 18 and the distributing pipe 1 to move relatively through the connecting plate 17, and the vibration of the connecting plate 18 is controlled.

As shown in fig. 3, the vibrating plate 19 is closely attached to the outer wall of the coal dropping pipe 13, and the vibrating plate 19 forms a vibrating structure with the coal dropping pipe 13 by connecting the connecting plate 18, so that the connecting plate 18 is favorable to move to drive the two groups of coal dropping pipe 13 to synchronously vibrate through the two groups of vibrating plates 19, and the control operation of the synchronous vibration of the two groups of coal dropping pipe 13 is realized.

When in use: firstly, an operator sends coal into a feeding hole 12, the coal in the feeding hole 12 enters a material distributing pipe 1 through a connecting pipe 11 to carry out material distributing operation, a material distributing motor 2 works to drive a rotating plate 3 to rotate, the rotating plate 3 rotates to drive an oscillating plate 4 to oscillate through an oscillating guide groove 5, so that the oscillating plate 4 oscillates to drive a driving guide plate 6 to rotate through a material distributing guide groove 7, the driving guide plate 6 rotates to rotate and drive a material distributing plate 9 to synchronously rotate through a rotating shaft 8, and the material distributing operation on the coal is realized by changing the oscillating angle of the material distributing plate 9.

Finally, coal in the distributing pipe 1 enters the coal breakage pipe body 13 through the distributing hopper 10 to achieve guiding operation of the coal in the coal breakage pipe body 13, vibration cleaning operation is conducted on the coal attached to the inner wall of the coal breakage pipe body 13, the vibration motor 14 works to drive the rotary guide pillar 16 to rotate through the rotary disc 15, the rotary guide pillar 16 rotates to drive the connecting plate 18 and the distributing pipe 1 to move relatively through the connecting plate 17, so that the connecting plate 18 moves to drive two groups of coal breakage pipe bodies 13 to vibrate synchronously through the two groups of vibration plates 19, and vibration cleaning operation of the coal attached to the inner wall of the two groups of coal breakage pipe bodies 13 is achieved.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides a chevron shape curve coal breakage tubular structure, includes branch material pipe (1) and sets up the feed mechanism in branch material pipe (1) outside, its characterized in that: the material distribution mechanism comprises a swing assembly, a connecting assembly and a material distribution assembly;

the swing assembly comprises a material distribution motor (2), a rotating plate (3), a swing plate (4) and a swing guide groove (5), the material distribution motor (2) is fixedly connected to the outer wall of the material distribution pipe (1), the rotating plate (3) is installed at the output end of the material distribution motor (2), the swing plate (4) which is in screwed connection with the outer wall of the material distribution pipe (1) is movably connected to one end of the rotating plate (3), and the swing guide groove (5) is formed in the connecting portion of the swing plate (4) and the rotating plate (3);

the connecting assembly comprises a driving guide plate (6) and a material distribution guide groove (7), the top end of the swinging plate (4) is movably connected with the driving guide plate (6) which is in screwed connection with the outer wall of the material distribution pipe (1), and the material distribution guide groove (7) is formed in the connecting part of the driving guide plate (6) and the swinging plate (4);

divide the material subassembly to include pivot (8), divide flitch (9) and divide hopper (10), the one end fixedly connected with of initiative baffle (6) and the pivot (8) that divide material pipe (1) outer wall to connect soon, the one end of pivot (8) extends to the inner wall fixedly connected with that divides material pipe (1) divides flitch (9), the below of dividing flitch (9) is located the bottom fixedly connected with that divides material pipe (1) and divides hopper (10).

2. A herringbone curvilinear coal chute structure as claimed in claim 1, wherein: the coal feeding device is characterized in that a connecting pipe (11) is fixedly connected to the top end of the material distributing pipe (1), a feeding hole (12) is fixedly connected to the top end of the connecting pipe (11), a coal dropping pipe body (13) is fixedly connected to the bottom end of the material distributing hopper (10), a vibrating motor (14) is fixedly connected to one side of the coal dropping pipe body (13) at the bottom end of the material distributing hopper (10), a rotary table (15) is installed at the output end of the vibrating motor (14), a rotary guide pillar (16) is fixedly connected to the edge of the bottom end of the rotary table (15), a connecting plate (17) is connected to the outer wall of the rotary guide pillar (16) in a rotating mode, one end of the connecting plate (17) is connected to a connecting plate (18) in a rotating mode, and a vibrating plate (19) fixedly connected to the outer wall of the connecting plate (18) is connected to the outer wall of the coal dropping pipe body (13).

3. A chevron curve coal chute structure as claimed in claim 1 wherein: the swing plate (4) and the material distributing pipe (1) form a swing structure through the rotating plate (3) and the swing guide groove (5), and the swing center of the swing plate (4) and the rotating center of the rotating plate (3) are located on the same vertical plane.

4. A chevron curve coal chute structure as claimed in claim 1 wherein: the driving guide plate (6) forms a swing structure with the material distributing pipe (1) through the swing plate (4) and the material distributing guide groove (7), and the swing angle of the driving guide plate (6) is equal to the included angle of the bottom end of the material distributing pipe (1).

5. A chevron curve coal chute structure as claimed in claim 1 wherein: the material distribution hopper (10) is provided with two groups, and the position relation of the two groups of material distribution hoppers (10) is symmetrical about the material distribution pipe (1).

6. A chevron curve coal chute structure as claimed in claim 2 wherein: the connecting plates (18) form a telescopic structure with the material distributing pipe (1) through the rotating guide posts (16) and the connecting plates (17), and two groups of vibrating plates (19) are arranged.

7. A chevron curve coal chute structure as claimed in claim 2 wherein: the vibrating plate (19) is tightly attached to the outer wall of the coal dropping pipe body (13), and the vibrating plate (19) is connected with the coal dropping pipe body (13) through a connecting plate (18) to form a vibrating structure.

Images