CN209736032U - Automatic material machine that connects who rejects of waste material - Google Patents

Abstract

The utility model discloses a material receiving machine for automatically removing waste materials, which comprises a screen separating box body, a dispersing partition plate is embedded at the upper part in the screen separating box body, a first filter screen plate is embedded below the dispersing partition plate, the outer part of a first screen separating chamber is connected with a first discharging pipe along the extension part of the lower end of the first filter screen plate, a second filter screen plate is embedded below the first filter screen plate in the screen separating box body, a second discharging pipe which is inclined downwards and communicated with a second screen separating chamber is arranged on one side of the first discharging pipe, a third filter screen plate is embedded in the second discharging pipe, a baffle which is inclined upwards is arranged below the third filter screen plate in the first discharging pipe, and the two ends of the second filter screen plate are connected with the inner walls at the upper and lower sides of a; the outer side of the third sieve-dividing chamber is connected with a third discharge pipe along the lower end of the bottom; the vibrating motor is installed in the screen box body, the output end of the vibrating motor is connected with the vibrating rod, and the contact positions of the vibrating rod and the bottoms of the second filter screen plate and the first filter screen plate are respectively provided with a limiting vibrating ball.

Description

Automatic material machine that connects who rejects of waste material

Technical Field

The utility model relates to a material is polished and is divided the sieve field, specifically is an automatic material machine that connects who rejects of waste material.

Background

the ball mill is the key equipment for crushing the materials after the materials are crushed. This type of mill is provided with a number of steel balls as grinding media in the barrel. It is widely used in the production industries of cement, silicate products, novel building materials, refractory materials, chemical fertilizers, black and non-ferrous metal ore dressing, glass ceramics and the like, and is used for dry or wet grinding of various ores and other grindable materials. The ball mill is suitable for grinding various ores and other materials, is widely used in the industries of mineral separation, building materials, chemical industry and the like, and can be divided into a dry type ore grinding mode and a wet type ore grinding mode. According to different ore discharge modes, the method can be divided into a lattice type and an overflow type.

At present, steel balls of a ball mill need to be replaced due to the fact that the steel balls are worn after being used for a period of time, waste materials need to be discharged, the waste materials contain the steel balls and clinker powder, the clinker powder can be recycled after being recycled, the steel balls can be sold as waste steel, cost is saved, the existing screening device is poor in screening effect, and a lot of clinker powder is mixed in the steel balls.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an automatic material machine that connects of rejecting of waste material to solve the problem that proposes in the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: a material receiving machine capable of automatically removing waste materials comprises a screening box body, wherein the bottom of the screening box body is supported and fixed by a support, a feeding port is formed in the top of the screening box body, a dispersing partition plate is embedded in the upper portion of the inside of the screening box body, a first filtering screen plate is embedded below the dispersing partition plate, the first filtering screen plate is of a downward inclined structure, a first screening chamber is formed between the dispersing partition plate and the first filtering screen plate, a first discharging pipe is connected to the outer portion of the first screening chamber along the extending position of the lower end of the first filtering screen plate, and the bottom of the first discharging pipe is communicated with a first material receiving box;

a second filter screen plate parallel to the dispersing partition plate is embedded below the first filter screen plate in the screening box body, a second screening chamber is formed between the first filter screen plate and the second filter screen plate, a second discharging pipe which is obliquely and downwards communicated with the second screening chamber is arranged on one side of the first discharging pipe, a third filter screen plate is embedded at the joint of the second discharging pipe and the first discharging pipe, and a baffle plate which is obliquely and upwards is arranged on the lower edge of the third filter screen plate in the first discharging pipe;

The inner walls of the two sides of the screening box body are respectively provided with a through groove corresponding to the positions of the two ends of the second filter screen plate, the two ends of the second filter screen plate penetrate through the through grooves, the intersections of the second filter screen plate and the inner and outer sides of the through grooves are respectively provided with a limiting plate, and the two ends of the second filter screen plate are connected with the inner walls of the upper and lower sides of the through grooves through vibrating springs; a third sieve chamber is arranged in the sieve box body below the second filter screen plate, the bottom of the third sieve chamber is of an inclined downward structure, a third discharge pipe is connected to the outer side of the third sieve chamber along the lower end of the bottom of the third sieve chamber, and the bottom of the third discharge pipe is communicated with the second material receiving box;

The vibrating motor is installed below the third sieve-dividing chamber in the sieve-dividing box body, the output end of the vibrating motor is upwards connected with the vibrating rod, the vibrating rod penetrates through the second filter screen plate and contacts with the bottom of the first filter screen plate, and the vibrating rod is provided with limiting vibrating balls at the contact positions of the second filter screen plate and the bottom of the first filter screen plate respectively.

Preferably, the charging opening is of a funnel-shaped structure with an upward opening.

preferably, the dispersing partition is internally provided with a plurality of dispersing meshes formed by criss-cross dividing strips, and the dividing strips are made of metal materials.

Preferably, the pore diameters of the first filter screen plate, the second filter screen plate and the third filter screen plate are equal.

preferably, the baffle is connected with the inner wall of the first discharge pipe through a hinge, and a compression spring is connected between one side of the baffle, which is far away from the third filter screen plate, and the inner wall of the first discharge pipe.

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

1. the utility model discloses a set up dispersion baffle, bump with the steel ball when the waste material is led in, on the one hand will wrap up and vibrate at the grog powder on steel ball surface and get off, and on the other hand separates the steel ball one by one, the subsequent screening of being convenient for.

2. A pipeline for secondary screening is arranged on one side of a discharge pipe for guiding out the steel balls, the clinker powder which is not completely separated is further collected, the clinker powder is limited by a baffle plate arranged on the pipeline for secondary screening, the clinker powder can conveniently enter a second screening chamber, the steel balls are collided with the baffle plate in the guiding-out process, and the clinker powder is prevented from being accumulated at the bottom of the baffle plate.

3. Through at the internal installation vibrating motor of branch sieve box to through vibrating arm and spacing vibration ball and first filter screen board and the contact of second filter screen board, and second filter screen board and branch sieve box inner wall elastic connection, the vibration effect is good, is favorable to the separation of grog powder and steel ball and the derivation of grog powder, and the separation effect is good.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention;

Fig. 2 is a schematic structural diagram of the dispersion partition plate of the present invention;

FIG. 3 is an enlarged view of the structure A in FIG. one of the present invention;

Fig. 4 is a schematic view of the connection structure of the second filter screen plate and the sieving box of the present invention.

In the figure: 1. screening the box body; 2. a support; 3. a feed inlet; 4. a dispersion baffle; 5. cutting the strips; 6. dispersing the meshes; 7. a first filter screen plate; 8. a first classifying chamber; 9. a first discharge pipe; 10. a first material receiving box; 11. a second filter screen plate; 12. a second sieve chamber; 13. a second discharge pipe; 14. a third filter screen plate; 15. a baffle plate; 16. a compression spring; 17. a through groove; 18. a limiting plate; 19. a vibration spring; 20. a third sieve-dividing chamber; 21. a third discharge pipe; 22. a second material receiving box; 23. a vibration motor; 24. a vibrating rod; 25. limiting vibration ball.

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.

in the description of the present invention, it should be noted that the terms "vertical", "upper", "lower", "horizontal", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the present invention.

In the description of the present invention, it should also be noted that, unless otherwise explicitly specified or limited, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

Referring to fig. 1-4, the present invention provides a technical solution: a receiving machine for automatically removing waste materials comprises a screening box body 1, wherein the bottom of the screening box body 1 is supported and fixed by a support 2, a feeding port 3 is formed in the top of the screening box body 1, a dispersing partition plate 4 is embedded in the upper portion of the inside of the screening box body 1, a first filtering screen plate 7 is embedded below the dispersing partition plate 4, the first filtering screen plate 7 is of a downward inclined structure, a first screening chamber 8 is formed between the dispersing partition plate 4 and the first filtering screen plate 7, a first discharging pipe 9 is connected to the outer portion of the first screening chamber 8 along the extending portion of the lower end of the first filtering screen plate 7, and the bottom of the first discharging pipe 9 is communicated with a first receiving box 10;

A second filter screen plate 11 parallel to the dispersing partition plate 4 is embedded below the first filter screen plate 7 in the screening box body 1, a second screening chamber 12 is formed between the first filter screen plate 7 and the second filter screen plate 11, a second discharge pipe 13 which is obliquely and downwardly communicated with the second screening chamber 12 is arranged on one side of the first discharge pipe 9, a third filter screen plate 14 is embedded at the joint of the second discharge pipe 13 and the first discharge pipe 9, and an obliquely and upwardly inclined baffle plate 15 is installed on the lower edge of the third filter screen plate 14 in the first discharge pipe 9;

through grooves 17 are respectively formed in the positions, corresponding to the two ends of the second filter screen plate 11, of the inner walls of the two sides of the screening box body 1, two ends of the second filter screen plate 11 penetrate through the through grooves 17, limiting plates 18 are respectively arranged at the intersection positions of the second filter screen plate 11 and the inner and outer sides of the through grooves 17, and two ends of the second filter screen plate 11 are connected with the inner walls of the upper and lower sides of the through grooves 17 through vibrating springs 19; a third sieving chamber 20 is arranged below the second filter screen plate 11 in the sieving box body 1, the bottom of the third sieving chamber 20 is of an inclined downward structure, a third discharging pipe 21 is connected to the outer side of the third sieving chamber 20 along the lower end of the bottom, and the bottom of the third discharging pipe 21 is communicated with a second material receiving box 22;

Install vibrating motor 23 in the third minute sieve room 20 below in the branch sieve box 1, vibrating motor 23's output upwards is connected with vibrating arm 24, and vibrating arm 24 passes second filter screen board 11 and the contact of first filter screen board 7 bottom, and the contact department is provided with spacing vibration ball 25 respectively with second filter screen board 11, the first filter screen board 7 bottom on the vibrating arm 24.

preferably, the charging opening 3 is of a funnel-shaped structure with an upward opening.

Preferably, a plurality of dispersing meshes 6 are formed in the dispersing partition plate 4 by criss-cross dividing strips 5, and the dividing strips 5 are made of metal materials, so that the steel balls can collide with the dividing strips 5 conveniently, and the separation of the steel balls and the clinker powder is accelerated.

Preferably, the pore sizes of the first filter screen plate 7, the second filter screen plate 11 and the third filter screen plate 14 are equal.

Preferably, the baffle 15 is connected to the inner wall of the first outlet pipe 9 by a hinge, and a compression spring 16 is connected between the side of the baffle 15 remote from the third screen plate 14 and the inner wall of the first outlet pipe 9.

The working principle is as follows: during screening, a small amount of waste materials are poured into the material inlet 3 uniformly and continuously, the waste materials fall on the dispersing partition plate 4 firstly, the partition strips 5 of the dispersing partition plate 4 collide with the steel balls, and the dispersing mesh openings 6 separate the steel balls one by one, so that subsequent screening is facilitated. The separated steel balls and clinker powder enter a first screening chamber 8, and as the clinker powder and the steel balls are fully separated, the clinker powder continuously enters a second screening chamber 12 downwards through a first filter screen plate 7, then enters a third screening chamber 20 through a third filter screen plate 14, and then is guided into a second material receiving box 22 through a third discharge pipe 21; the steel balls are blocked by the first filter screen plate 7, enter the first discharge pipe 9 along with the first filter screen plate 7 with an inclined structure under the action of gravity, and finally fall into the first material receiving box 10; a second discharging pipe 13 which is obliquely and downwards communicated with the second sieving chamber 12 is arranged on one side of the first discharging pipe 9, the second discharging pipe 13 further collects the clinker powder which is not completely separated, a baffle plate 15 which is obliquely and upwards is arranged on the lower edge of the third filtering screen plate 14 in the first discharging pipe 9, the baffle plate 15 is connected with the inner wall of the first discharging pipe 9 through a hinge, a compression spring 16 is connected between one side of the baffle plate 15, which is far away from the third filtering screen plate 14, and the inner wall of the first discharging pipe 9, so that the baffle plate 15 is in an elastic connection state, the clinker powder is limited by the baffle plate 15, the steel ball collides with the baffle plate 15 in the process of being led out, the clinker powder is prevented from being accumulated at the bottom of the baffle plate 15, the clinker powder can conveniently enter the second sieving chamber 12, and the clinker powder subjected to secondary sieving falls into the third sieving chamber 20 from the second sieving chamber 12 and then is. Install vibrating motor 23 in the branch sieve box 1, vibrating arm 24 passes second filter screen plate 11 and the contact of first filter screen plate 7 bottom, vibrating arm 24 is last to be provided with spacing vibration ball 25 with second filter screen plate 11, the contact department of first filter screen plate 7 bottom respectively, start vibrating motor 23 before sieving, to first filter screen plate 7, second filter screen plate 11 vibrates, second filter screen plate 11 is connected through vibrating spring 19 with the inner wall of branch sieve box 1 both sides, the vibration effect is good, be favorable to the separation of grog powder and steel ball and the derivation of grog powder, it is effectual to separate.

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 (5)

1. the material receiving machine capable of automatically removing the waste materials is characterized by comprising a screening box body (1), wherein the bottom of the screening box body (1) is supported and fixed by a support (2), a feeding port (3) is formed in the top of the screening box body (1), a dispersing partition plate (4) is embedded in the upper portion of the screening box body (1), a first filtering screen plate (7) is embedded below the dispersing partition plate (4), the first filtering screen plate (7) is of a downward inclined structure, a first screening chamber (8) is formed between the dispersing partition plate (4) and the first filtering screen plate (7), a first discharging pipe (9) is connected to the outer portion of the first screening chamber (8) along the extension position of the lower end of the first filtering screen plate (7), and the bottom of the first discharging pipe (9) is communicated with a first material receiving box (10);

A second filter screen plate (11) parallel to the dispersing partition plate (4) is embedded below the first filter screen plate (7) in the screening box body (1), a second screening chamber (12) is formed between the first filter screen plate (7) and the second filter screen plate (11), a second discharge pipe (13) which is obliquely downward and communicated with the second screening chamber (12) is arranged on one side of the first discharge pipe (9), a third filter screen plate (14) is embedded at the joint of the second discharge pipe (13) and the first discharge pipe (9), and an oblique upward baffle plate (15) is installed on the lower edge of the third filter screen plate (14) in the first discharge pipe (9);

through grooves (17) are respectively formed in positions, corresponding to the two ends of the second filter screen plate (11), of the inner walls of the two sides of the screening box body (1), two ends of the second filter screen plate (11) penetrate through the through grooves (17), a limiting plate (18) is respectively arranged at the intersection of the second filter screen plate (11) and the inner side and the outer side of the through grooves (17), and the two ends of the second filter screen plate (11) are connected with the inner walls of the upper side and the lower side of the through grooves (17) through vibrating springs (19); a third sieve chamber (20) is arranged below the second filter screen plate (11) in the sieve box body (1), the bottom of the third sieve chamber (20) is of an inclined downward structure, a third discharge pipe (21) is connected to the outer side of the third sieve chamber (20) along the lower end of the bottom, and the bottom of the third discharge pipe (21) is communicated with a second material receiving box (22);

Install vibrating motor (23) in third minute sieve room (20) below in branch sieve box (1), the output of vibrating motor (23) upwards is connected with vibrating arm (24), vibrating arm (24) pass second filter screen board (11) and first filter screen board (7) bottom contact, filter screen board (11), first filter screen board (7) bottom contact department on vibrating arm (24) and be provided with spacing vibration ball (25) respectively.

2. The automatic waste material removing and receiving machine as claimed in claim 1, wherein: the feed inlet (3) is of a funnel-shaped structure with an upward opening.

3. The automatic waste material removing and receiving machine as claimed in claim 1, wherein: the interior of the dispersing partition board (4) is formed with a plurality of dispersing meshes (6) by criss-cross dividing strips (5), and the dividing strips (5) are made of metal materials.

4. The automatic waste material removing and receiving machine as claimed in claim 1, wherein: the aperture of the first filter screen plate (7), the second filter screen plate (11) and the third filter screen plate (14) are equal.

5. the automatic waste material removing and receiving machine as claimed in claim 1, wherein: the baffle (15) is connected with the inner wall of the first discharging pipe (9) through a hinge, and a compression spring (16) is connected between one side of the baffle (15) far away from the third filter screen plate (14) and the inner wall of the first discharging pipe (9).