CN112722772A - Automatic ball separating machine for forging balls - Google Patents

Abstract

The invention provides an automatic ball separating machine for forged balls, and relates to the technical field of ball separating equipment for steel ball production. This automatic ball separating machine for forging balls, including the guide cylinder body, the first interior helical blade of inside wall fixedly connected with of guide cylinder body, a plurality of first discharge gates have evenly been seted up to the surface of guide cylinder body, the first transmission post of inboard fixedly connected with of guide cylinder body, and first transmission post is located the inboard center department of guide cylinder body, the both ends of first transmission post are rotated respectively and are connected with first support frame and support side cover. Through separately leading-in each ball distributing roller with the steel ball, in the steel ball that each ball distributing roller will collect at last is unified to be led into corresponding equipment to avoid the jam of steel ball in a certain fortune feed cylinder, also be favorable to promoting the efficiency of steel ball transportation feed simultaneously, also avoided like the high cost that a plurality of guide equipment combined use produced in addition.

Description

Automatic ball separating machine for forging balls

Technical Field

The invention relates to the technical field of ball separating equipment for steel ball production, in particular to an automatic ball separating machine for forged balls.

Background

The forged ball is a traditional steel ball production process, and is named in English: for rolled steel balls, although the rolled steel ball production process is internationally an obstacle to military projection, this conventional process is retained while the steel ball process is constantly being updated due to the advantages of the forged balls. And still is the pet of the grinding industries such as mines, power plants, cement plants and the like.

At present, the guide equipment that current forging ball was used does not all have the effect of automatic ball separation, consequently leads to when exporting the steel ball at every turn, all can only export a small amount of steel balls to lead to the efficiency of transportation guide to obtain promoting difficultly, in addition, the guide equipment that current forging ball was used is if want to improve guide efficiency, mostly carries out the guide transportation through the mutual combination of a plurality of guide equipment, but such method fortune material cost is too high.

Disclosure of Invention

Technical problem to be solved

Aiming at the defects of the prior art, the invention provides an automatic ball separating machine for forging balls, which solves the problems that the existing material guiding equipment for forging balls has no automatic ball separating effect, so that only a small amount of steel balls can be output each time the steel balls are led out, the material conveying and guiding efficiency is difficult to improve, and the transportation and guiding cost of the existing material guiding equipment for efficient forging balls is high.

(II) technical scheme

In order to achieve the purpose, the invention is realized by the following technical scheme: an automatic ball separating machine for forging balls comprises a guide cylinder body, wherein the inner side wall of the guide cylinder body is fixedly connected with first inner spiral blades, the outer surface of the guide cylinder body is uniformly provided with a plurality of first discharge ports, the inner side of the guide cylinder body is fixedly connected with a first transmission column, the first transmission column is positioned at the center of the inner side of the guide cylinder body, two ends of the first transmission column are respectively and rotatably connected with a first support frame and a support side cover, the position, corresponding to the first transmission column, of the inner top side of the support side cover is provided with a first transmission belt pulley, the first transmission belt pulley is fixedly connected with the first transmission column, the inner bottom side of the support side cover is provided with a first driving motor, the output shaft of the first driving motor is fixedly connected with a second transmission belt pulley, and the surfaces of the second transmission belt pulley and the first transmission belt pulley are jointly connected with a first transmission belt, a first material guide frame is fixedly connected to one side of the supporting side cover close to the material guide cylinder body discharge port, a plurality of second material guide frames are uniformly arranged on one side of the first material guide frame away from the supporting side cover, the plurality of second material guide frames are respectively aligned with the plurality of first discharge ports, ball distributing rollers are respectively arranged on one sides of the first material guide frames and the plurality of second material guide frames away from the material guide cylinder body, a second discharge port is respectively arranged on one side of the plurality of ball distributing rollers away from the material guide cylinder body, second inner helical blades are respectively fixedly connected to the inner side walls of the plurality of ball distributing rollers, second transmission columns are respectively fixedly connected to the inner sides of the plurality of ball distributing rollers, the second transmission columns are positioned at the centers of the inner sides of the ball distributing rollers, third transmission belt pulleys are respectively fixedly connected to one side of the plurality of second transmission columns away from the material guide cylinder body, and second transmission belts are jointly connected to the outer surfaces of the plurality of third transmission belt pulleys, and one end of each second transmission column, which is far away from the guide cylinder body, is connected with a second support frame in a rotating mode, one end of each second support frame, which is far away from the ball distributing roller, is fixedly connected with a second driving motor, and the output end of each second driving motor is fixedly connected with the adjacent second transmission column.

Preferably, the guide cylinder body and one side of the first transmission column, which is close to the feeding port of the guide cylinder body, are jointly and rotatably connected with a feeding cover, and the feeding cover is fixedly connected with the first support frame.

Preferably, the first support frame and the bottom end of the support side cover are fixedly connected with a first base together, and the first driving motor, the first material guide frame and the second material guide frame are fixedly connected with the first base.

Preferably, the guide cylinder body is obliquely arranged, and the discharge port of the guide cylinder body is positioned obliquely above the feeding port.

Preferably, the ball distributing rollers are all obliquely arranged, and the second discharge port of each ball distributing roller is positioned obliquely above the feeding port.

Preferably, the bottom sides of the ball distributing rollers and the second support frame are fixedly connected with a second base together.

The working principle is as follows: when the guide cylinder is used, the first driving motor on the first base drives the second driving belt pulley to rotate, the second driving belt pulley correspondingly drives the first driving belt pulley and the first driving column to rotate through the first driving belt in the supporting side cover, so that the guide cylinder body rotates between the first supporting frame and the supporting side cover, meanwhile, the first inner spiral blades on the inner side of the guide cylinder body drive the steel balls in the feeding cover to be led into the guide cylinder body, the steel balls in the guide cylinder body are discharged from each first discharge port and the discharge port of the guide cylinder body through the rotating first inner spiral blades, so that the steel balls respectively fall into the first guide frame and the second guide frames, meanwhile, the second driving motor on the second supporting frame drives the second driving column on the adjacent side to rotate, and the third driving belt pulley on the second driving column correspondingly drives the rest third driving belt pulley and the second driving column to finish rotating through the second driving belt pulley and the second driving column Therefore, each ball distributing roller rotates simultaneously, the second inner spiral blades on the inner side of the ball distributing rollers drive the steel balls in the material guide frame to be guided into the ball distributing rollers when the ball distributing rollers rotate, the steel balls in the ball distributing rollers are guided out from the second discharge hole through the rotating second inner spiral blades, and accordingly the conveying and feeding of the steel balls are achieved.

(III) advantageous effects

The invention provides an automatic ball separating machine for a forging ball. The method has the following beneficial effects:

1. this automatic ball separator for forging ball through in separately leading-in each ball cylinder with the steel ball, in the steel ball that at last each ball cylinder of rethread will be collected unified leading-in corresponding equipment to avoided the jam of steel ball in a certain fortune feed cylinder, also be favorable to promoting the efficiency of steel ball transportation feed simultaneously, also avoided like the high cost that a plurality of guide equipment combination use and produced in addition.

Drawings

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

FIG. 2 is a schematic structural view of a material guide cylinder body according to the present invention;

fig. 3 is a schematic structural view of a first material guiding frame and a second material guiding frame of the present invention;

fig. 4 is a schematic structural view of the ball distributing roller of the present invention.

Wherein, 1, a guide cylinder body; 2. a first inner helical blade; 3. a first discharge port; 4. a first drive column; 5. a first support frame; 6. feeding a material cover; 7. supporting the side cover; 8. a first drive pulley; 9. a first drive belt; 10. a first drive motor; 11. a second drive pulley; 12. a first base; 13. a first material guide frame; 14. a second material guide frame; 15. a ball distributing roller; 16. a second drive post; 17. a second inner helical blade; 18. a second discharge port; 19. a second support frame; 20. a second drive motor; 21. a third drive pulley; 22. a second drive belt; 23. a second base.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example (b):

as shown in fig. 1 to 4, an embodiment of the present invention provides an automatic ball separating machine for forging balls, which includes a material guiding cylinder body 1, wherein a first inner helical blade 2 is fixedly connected to an inner side wall of the material guiding cylinder body 1, a plurality of first discharge ports 3 are uniformly formed in an outer surface of the material guiding cylinder body 1, a first transmission column 4 is fixedly connected to an inner side of the material guiding cylinder body 1, the first transmission column 4 is located at an inner center of the material guiding cylinder body 1, two ends of the first transmission column 4 are respectively and rotatably connected to a first supporting frame 5 and a supporting side cover 7, a first transmission belt pulley 8 is disposed at a position, corresponding to the first transmission column 4, on an inner top side of the supporting side cover 7, a first driving motor 10 is disposed on an inner bottom side of the supporting side cover 7, a second transmission belt pulley 11 is fixedly connected to an output shaft of the first driving motor 10, and a first transmission belt pulley 11 is disposed on a surface of the second transmission belt pulley 11 and a surface of the first transmission belt 8 9, a first material guide frame 13 is fixedly connected to one side of the supporting side cover 7 close to the material guide cylinder body 1, a plurality of second material guide frames 14 are uniformly arranged on one side of the first material guide frame 13 far away from the supporting side cover 7, the plurality of second material guide frames 14 are respectively aligned with the plurality of first material outlets 3, ball distributing rollers 15 are respectively arranged on one sides of the first material guide frame 13 and the plurality of second material guide frames 14 far away from the material guide cylinder body 1, second material outlets 18 are respectively arranged on one sides of the plurality of ball distributing rollers 15 far away from the material guide cylinder body 1, second inner spiral blades 17 are respectively fixedly connected to the inner side walls of the plurality of ball distributing rollers 15, second transmission columns 16 are respectively fixedly connected to the inner sides of the plurality of ball distributing rollers 15, the second transmission columns 16 are positioned at the centers of the inner sides of the plurality of second transmission columns 16 far away from the material guide cylinder body 1, and third transmission belt pulleys 21 are respectively fixedly connected to one sides of the plurality of, the outer surfaces of the third transmission belt pulleys 21 are connected with a second transmission belt 22, one ends, far away from the guide cylinder body 1, of the second transmission columns 16 are connected with a second support frame 19 in a rotating mode, one ends, far away from the ball distributing roller 15, of the second support frame 19 are fixedly connected with a second driving motor 20, and the output end of the second driving motor 20 is fixedly connected with the adjacent second transmission columns 16.

The guide cylinder body 1 and one side, close to a feeding port of the guide cylinder body 1, of the first transmission column 4 are jointly connected with a feeding cover 6 in a rotating mode, the feeding cover 6 is fixedly connected with a first support frame 5, and steel balls to be transported are placed in the feeding cover 6, so that the first inner spiral blades 2 on the inner side of the guide cylinder body 1 can guide the steel balls in the feeding cover 6 into the inner side of the guide cylinder body 1 when the guide cylinder body 1 rotates; the first support frame 5 and the bottom end of the support side cover 7 are fixedly connected with a first base 12, a first driving motor 10, a first material guide frame 13 and a second material guide frame 14 are fixedly connected with the first base 12, and the support stability of each part on the top side of the material guide cylinder body 1 is improved by arranging the first base 12; the guide cylinder body 1 is obliquely arranged, and the discharge port of the guide cylinder body 1 is positioned obliquely above the feed port, so that the first inner spiral blades 2 on the inner side of the guide cylinder body 1 drive the steel balls in the feed cover 6 to be led into the guide cylinder body 1 when the guide cylinder body 1 rotates, and the steel balls in the guide cylinder body 1 are led out from each first discharge port 3 through the rotating first inner spiral blades 2; the ball distributing rollers 15 are all obliquely arranged, and the second discharge port 18 of the ball distributing rollers 15 is positioned obliquely above the feeding port, so that the second inner spiral blades 17 on the inner side of the ball distributing rollers 15 drive the steel balls in the material guide frame to be guided into the ball distributing rollers 15 when the ball distributing rollers 15 rotate, and the steel balls in the ball distributing rollers 15 are guided out from the second discharge port 18 through the rotating second inner spiral blades 17; the bottom sides of the ball distributing rollers 15 and the second support frame 19 are fixedly connected with a second base 23, and the second base 23 is arranged to be favorable for improving the support stability of each component on the second base 23.

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 (6)

1. The utility model provides a forge ball and use automatic ball separator, includes guide cylinder body (1), its characterized in that: the inner side wall of the guide cylinder body (1) is fixedly connected with a first inner spiral blade (2), the outer surface of the guide cylinder body (1) is uniformly provided with a plurality of first discharge holes (3), the inner side of the guide cylinder body (1) is fixedly connected with a first transmission column (4), the first transmission column (4) is positioned at the center of the inner side of the guide cylinder body (1), two ends of the first transmission column (4) are respectively and rotatably connected with a first support frame (5) and a support side cover (7), the inner top side of the support side cover (7) is provided with a first transmission belt pulley (8) corresponding to the position of the first transmission column (4), the first transmission belt pulley (8) is fixedly connected with the first transmission column (4), the inner bottom side of the support side cover (7) is provided with a first driving motor (10), the output shaft of the first driving motor (10) is fixedly connected with a second transmission belt pulley (11), the second transmission belt pulley (11) and the surface of the first transmission belt pulley (8) are jointly connected and provided with a first transmission belt (9), one side of the support side cover (7) close to the discharge hole of the guide cylinder body (1) is fixedly connected with a first guide frame (13), one side of the first guide frame (13) far away from the support side cover (7) is uniformly provided with a plurality of second guide frames (14), the plurality of second guide frames (14) are respectively aligned with the plurality of first discharge holes (3), one sides of the first guide frame (13) and the plurality of second guide frames (14) far away from the guide cylinder body (1) are respectively provided with a ball distributing roller (15), one sides of the plurality of ball distributing rollers (15) far away from the guide cylinder body (1) are respectively provided with a second discharge hole (18), the inner side walls of the plurality of ball distributing rollers (15) are respectively fixedly connected with a second inner spiral blade (17), a plurality of the inboard equal fixedly connected with second transmission post (16) of minute ball cylinder (15), and second transmission post (16) are located the inboard center department of minute ball cylinder (15), and it is a plurality of the equal fixedly connected with third drive pulley (21) of one side of keeping away from guide cylinder body (1) of second transmission post (16), it is a plurality of the surface of third drive pulley (21) is connected jointly and is provided with second drive belt (22), and is a plurality of the one end that guide cylinder body (1) was kept away from in second transmission post (16) rotates jointly and is connected with second support frame (19), the one end fixedly connected with second driving motor (20) of minute ball cylinder (15) is kept away from in second support frame (19), and fixed connection between the output of second driving motor (20) and adjacent second transmission post (16).

2. The automatic ball separating machine for the forged balls according to claim 1, characterized in that: the feeding cover (6) is connected with one side, close to a feeding port of the feeding cylinder body (1), of the feeding cylinder body (1) and the first transmission column (4) in a rotating mode, and the feeding cover (6) is fixedly connected with the first support frame (5).

3. The automatic ball separating machine for the forged balls according to claim 1, characterized in that: the bottom end of the first support frame (5) and the bottom end of the support side cover (7) are fixedly connected with a first base (12) together, and the first driving motor (10), the first material guide frame (13), the second material guide frame (14) and the first base (12) are fixedly connected.

4. The automatic ball separating machine for the forged balls according to claim 1, characterized in that: the guide cylinder body (1) is obliquely arranged, and a discharge port of the guide cylinder body (1) is positioned obliquely above a feeding port.

5. The automatic ball separating machine for the forged balls according to claim 1, characterized in that: a plurality of the ball distributing rollers (15) are all obliquely arranged, and a second discharge hole (18) of each ball distributing roller (15) is positioned obliquely above the feeding port.

6. The automatic ball separating machine for the forged balls according to claim 1, characterized in that: the bottom sides of the ball distributing rollers (15) and the second support frame (19) are fixedly connected with a second base (23) together.

Images