CN116715000A

CN116715000A - Feeding device for disc feeder

Info

Publication number: CN116715000A
Application number: CN202311001138.9A
Authority: CN
Inventors: 张连军; 张仲林
Original assignee: Yantai Xinte Machinery Equipment Co ltd
Current assignee: Yantai Xinte Machinery Equipment Co ltd
Priority date: 2023-08-10
Filing date: 2023-08-10
Publication date: 2023-09-08
Anticipated expiration: 2043-08-10
Also published as: CN116715000B

Abstract

The invention relates to the technical field of disc feeders, in particular to a feeding device for a disc feeder, which comprises a machine body, wherein the machine body is internally provided with: the disc is arranged on the machine body, the rotating shaft is rotatably arranged on the machine body, the baffle is fixedly sleeved on the rotating shaft, and the baffle is used for scraping and conveying materials; the device comprises a driving block, a leak hole and a moving block, wherein the driving block is arranged in a baffle, the leak hole is arranged in the baffle, the leak hole is used for releasing a conveying material in the baffle, the moving block is arranged on the baffle, and the moving block is used for cleaning a gap between the baffle and a disc; the driving mechanism is arranged in the baffle plate and is used for driving the moving block. When the conveyed material impacts the driving block, the moving magnet drives the moving block to move together, the moving block slides rightwards in the second guide groove, and the moving block cleans the conveyed material between the disc and the baffle plate so as to prevent the baffle plate from being blocked by the conveyed material and influence the position adjustment of the baffle plate.

Description

Feeding device for disc feeder

Technical Field

The invention relates to the technical field of disc feeders, in particular to a feeding device for a disc feeder.

Background

The Chinese patent publication No. CN104192508B discloses a disk feeder, which comprises a shell, a motor, an adjusting handle, a lifting screw rod, a connecting scraper, a rotating tray, a connecting flange frame, an adjusting hand wheel, a lifting nut frame, a feeding pipe, a lifting pipe, a discharging pipe, an adjusting mechanism fixing frame, a scraper adjusting screw rod, a pull plate, a movable scraper, a scraper shaft and a scraper support, wherein the motor is fixed at the bottom of the shell, a motor rotating shaft is connected with the bottom of the rotating tray, the lifting pipe is arranged in the shell, the lifting pipe is fixed in the shell through the lifting nut frame, the upper end of the lifting screw rod is provided with the adjusting hand wheel, one side of the lifting pipe is provided with the feeding pipe, the movable scraper is arranged between the lifting pipe and the discharging pipe, and the inner wall of the shell is provided with the adjusting mechanism fixing frame, and the movable scraper is connected with the connecting scraper. This batcher has a plurality of unloading to be adjusted and ejection of compact adjustment mechanism, can adjust the powder as required to can improve aerated concrete brick piece quality greatly, but still lead to there is the problem in the use because the structure is limited among the above-mentioned technique:

when using the disc feeder, rotatory disc drives material and scraper blade and offsets to scrape down the material from the disc, and current disc feeder is in order to conveniently adjust the position of scraper blade, so set up to leave the space between scraper blade and the disc, but when carrying the material, the very easy clearance department that stays between scraper blade and the disc of material is owing to this space is less, is unfavorable to clear up this space, and does not have the clean structure to this space in the above-mentioned technique, fills this space easily, makes the scraper blade block, extremely difficult position of adjusting the scraper blade.

Disclosure of Invention

The invention aims to solve the problems in the prior art and provides a feeding device for a disc feeder.

In order to achieve the above purpose, the present invention adopts the following technical scheme:

the utility model provides a feeding device that disc batcher was used, includes the organism, be provided with in the organism:

the rotary disc is arranged on the machine body, the rotary disc is used for conveying materials, the rotary shaft is rotatably arranged on the machine body, the baffle is fixedly sleeved on the rotary shaft, and the baffle is used for scraping the conveyed materials;

the device comprises a driving block, a leak hole and a moving block, wherein the driving block is arranged in a baffle, the driving block is impacted by conveyed materials, the leak hole is arranged in the baffle and used for releasing the conveyed materials in the baffle, the moving block is arranged on the baffle, and the moving block is used for cleaning a gap between the baffle and a disc;

the driving mechanism is arranged in the baffle plate and is used for driving the moving block.

Preferably, the body is further provided with:

the motor and the reversing box are fixedly arranged on the machine body, and the reversing box is positioned below the disc;

the output shaft and the input shaft are both rotatably arranged in the reversing box, the disc is fixedly connected with the output shaft, and the output end of the motor is in transmission connection with the input shaft.

Preferably, the motor output end and the input shaft are fixedly provided with driving wheels, and the motor output end and the input shaft are provided with driving belts in a matched manner through the driving wheels.

Preferably, the driving mechanism includes:

the device comprises an inclined cavity, a device cavity and a spring, wherein the inclined cavity and the device cavity are both arranged in a baffle, the inclined cavity is communicated with the outer end of the baffle, the spring is welded in the inclined cavity, the driving block is sleeved in the inclined cavity in a sliding manner, and the driving block is fixedly connected with the free end of the spring;

the guide pipe is fixedly arranged in the inclined cavity, the input end of the guide pipe is sleeved in the through hole in a sliding mode, the through hole and the guide pipe are matched and applied to conveying materials of the drainage impact driving block, the cover plate is rotatably arranged on the driving block and used for opening and closing the through hole, a torsion spring is fixedly arranged on the cover plate, and the cover plate is movably abutted to the guide pipe;

the device comprises a driving block, a first sliding groove, a first magnet, a second sliding groove and a second magnet, wherein the first sliding groove and the second sliding groove are respectively arranged on an inclined cavity and an equipment cavity;

the device comprises a first rack, a rotating shaft, a first gear and a second gear, wherein the first rack is fixedly connected to a second magnet, the rotating shaft is rotatably arranged in a device cavity, the first gear and the second gear are both connected to the rotating shaft in a key way, and the first rack is meshed with the first gear;

the device comprises a first guide groove, a moving magnet and a second guide groove, wherein the first guide groove and the second guide groove are respectively arranged at the lower end positions of a device cavity and a baffle, the moving magnet and a moving block are respectively sleeved in the first guide groove and the second guide groove in a sliding manner, and the moving magnet corresponds to the moving block;

the second rack is fixedly connected to the movable magnet, the second rack is connected with the second gear in a meshed mode, the storage cavity is formed in the baffle, the storage cavity is communicated with the equipment cavity, and the second rack is movably sleeved in the storage cavity.

Preferably, the bottom end of the inclined cavity and the bottom end of the driving block are both provided with inclined planes, the lowest point of the inclined plane of the inclined cavity is located at the leak hole, and the output end of the guide tube is located at the position above the inclined plane of the inclined cavity.

Preferably, the first magnet and the second magnet are opposite-pole attraction magnets, and the moving magnet and the moving block are opposite-pole attraction magnets.

Compared with the prior art, the invention has the following advantages:

1. when the material conveying impact driving block is driven by the second gear and the second rack in a meshed mode, the second rack moves rightwards, the second rack drives the moving magnet to slide rightwards in the first guide groove, the moving magnet drives the moving block to move together, and the moving block cleans the material conveying between the disc and the baffle plate so as to prevent the baffle plate from being blocked by the material conveying and influence the position adjustment of the baffle plate.

2. According to the invention, when the guide pipe is propped against the cover plate, the through hole is opened, so that the conveyed materials are discharged from the inclined cavity, the conveyed materials impacting the driving block are reduced, the driving block slides outwards in the inclined cavity under the elastic acting force of the spring, the moving block is driven to move leftwards, the gap between the disc and the baffle is cleaned again by the moving block, the conveyed materials between the disc and the baffle are cleaned in a reciprocating manner, and the blocking probability of the baffle is reduced.

Drawings

FIG. 1 is a schematic view of a feeding device for a disk feeder according to the present invention;

FIG. 2 is a schematic view of another view of a feeding device for a disk feeder according to the present invention;

FIG. 3 is a schematic view of a baffle plate of a feeding device for a disk feeder according to the present invention;

FIG. 4 is a schematic diagram showing a cross-sectional structure of a baffle plate of a feeding device for a disk feeder according to the present invention;

FIG. 5 is a schematic diagram showing a cross-sectional structure of a baffle plate of a feeding device for a disk feeder according to the present invention;

FIG. 6 is a schematic diagram showing a cross-sectional structure of a baffle plate of a feeding device for a disk feeder according to the present invention;

FIG. 7 is a schematic view of another view of a baffle plate of a feeding device for a disk feeder according to the present invention;

fig. 8 is a schematic diagram showing a cross-sectional structure of a baffle plate of a feeding device for a disk feeder according to the present invention.

In the figure: 1. a body; 2. a disc; 3. a rotating shaft; 4. a baffle; 5. a driving block; 6. a leak hole; 7. a moving block; 8. a motor; 9. a reversing box; 10. an output shaft; 11. a transmission belt; 12. an inclined cavity; 13. an equipment chamber; 14. a spring; 15. a through hole; 16. a guide tube; 17. a cover plate; 18. a first chute; 19. a first magnet; 20. a second chute; 21. a second magnet; 22. a first rack; 23. a rotation shaft; 24. a first gear; 25. a second gear; 26. a first guide groove; 27. a moving magnet; 28. a second guide groove; 29. a second rack; 30. and a storage cavity.

Description of the embodiments

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments.

Referring to fig. 1 to 8, a feeding device for a disk feeder includes a body 1, and the body 1 is provided with:

the device comprises a disc 2, a rotating shaft 3 and a baffle 4, wherein the disc 2 is arranged on a machine body 1, the rotating disc 2 is used for conveying materials, the rotating shaft 3 is rotatably arranged on the machine body 1, a locking structure for locking the rotating shaft 3 is arranged on the machine body 1, the locking structure is used for fixing the position of the baffle 4, the baffle 4 is fixedly sleeved on the rotating shaft 3, and the baffle 4 is used for scraping and conveying materials; the position of the baffle 4 is adjusted by rotating the baffle 4 and the rotating shaft 3;

the device comprises a driving block 5, a leak hole 6 and a moving block 7, wherein the driving block 5 is arranged in a baffle 4, the driving block 5 is impacted by conveyed materials, the leak hole 6 is arranged in the baffle 4, the leak hole 6 is used for releasing the conveyed materials in the baffle 4, the moving block 7 is arranged on the baffle 4, and the moving block 7 is used for cleaning a gap between the baffle 4 and a disc 2;

a driving mechanism is provided in the shutter 4, and the driving mechanism is used for driving the moving block 7.

The machine body 1 is also provided with:

the motor 8 and the reversing box 9 are fixedly arranged on the machine body 1, and the reversing box 9 is positioned below the disc 2;

the output shaft 10, the input shaft and the transmission belt 11, the output shaft 10 and the input shaft are both rotatably installed in the reversing box 9, the disc 2 is fixedly connected with the output shaft 10, and the output end of the motor 8 is in transmission connection with the input shaft. After the input shaft is driven to rotate, the output shaft 10 is driven to rotate by utilizing the internal structure in the reversing box 9;

the output end and the input shaft of the motor 8 are fixedly provided with driving wheels, and the output end and the input shaft of the motor 8 are provided with driving belts 11 in a matched manner through the driving wheels.

As shown in fig. 3 to 8, the driving mechanism includes:

the device comprises an inclined cavity 12, a device cavity 13 and a spring 14, wherein the inclined cavity 12 and the device cavity 13 are both arranged in the baffle 4, the inclined cavity 12 is communicated with the outer end of the baffle 4, the spring 14 is welded in the inclined cavity 12, the driving block 5 is sleeved in the inclined cavity 12 in a sliding manner, and the driving block 5 is fixedly connected with the free end of the spring 14;

the guide tube 16 is fixedly arranged in the inclined cavity 12, the input end of the guide tube 16 is sleeved in the through hole 15 in a sliding manner, the through hole 15 and the guide tube 16 are matched and applied to guide conveyed materials impacting the driving block 5, the cover plate 17 is rotatably arranged on the driving block 5, the cover plate 17 is used for opening and closing the through hole 15, as shown in fig. 3, the cover plate 17 only rotates towards the front end position of fig. 3, the through hole 15 is opened, a torsion spring is fixedly arranged on the cover plate 17, and the cover plate 17 is movably abutted against the guide tube 16; after the cover plate 17 is separated from the guide tube 16, the initial state of the cover plate 17 is restored by the elastic force of the torsion spring, and then the through hole 15 is closed;

the first sliding groove 18, the first magnet 19, the second sliding groove 20 and the second magnet 21, wherein the first sliding groove 18 and the second sliding groove 20 are respectively arranged on the inclined cavity 12 and the equipment cavity 13, the first magnet 19 and the second magnet 21 are respectively sleeved in the first sliding groove 18 and the second sliding groove 20 in a sliding way, the first magnet 19 corresponds to the second magnet 21, and the first magnet 19 is fixedly connected with the driving block 5;

the first rack 22 is fixedly connected to the second magnet 21, the rotating shaft 23 is rotatably installed in the equipment cavity 13, the first gear 24 and the second gear 25 are both connected to the rotating shaft 23 in a key way, and the first rack 22 is meshed and connected with the first gear 24;

the first guide groove 26, the moving magnet 27 and the second guide groove 28, the first guide groove 26 and the second guide groove 28 are respectively arranged at the lower end positions of the equipment cavity 13 and the baffle 4, the moving magnet 27 and the moving block 7 are respectively sleeved in the first guide groove 26 and the second guide groove 28 in a sliding way, and the moving magnet 27 corresponds to the moving block 7;

the second rack 29 and accomodate the chamber 30, second rack 29 fixed connection is on moving magnet 27, and second rack 29 and second gear 25 meshing are connected, accomodate the chamber 30 and offer in baffle 4, and accomodate chamber 30 and equipment chamber 13 and be linked together, when second rack 29 moves to the right, second rack 29 moves into accomodate chamber 30.

When the conveyed material impacts the driving block 5, the moving block 7 moves rightwards under the meshing transmission of the first gear 22 and the first gear 24 and the meshing transmission of the second gear 25 and the second gear 29, and the moving block 7 clears the conveyed material between the disc 2 and the baffle 4 so as to prevent the baffle 4 from being blocked;

when the guide pipe 16 is propped against the cover plate 17, the conveying material of the impact driving block 5 enters the inclined cavity 12 so as to reduce the impact force of the conveying material on the driving block 5, and the moving block 7 moves leftwards under the elastic acting force of the spring 14 so as to reciprocally remove the conveying material between the disc 2 and the baffle 4, thereby reducing the risk of the baffle 4 being blocked;

inclined planes are arranged at the bottom end of the inclined cavity 12 and the bottom end of the driving block 5, the lowest point of the inclined plane of the inclined cavity 12 is positioned at the leak hole 6, and the output end of the guide pipe 16 is positioned above the inclined plane of the inclined cavity 12; when the conveying material in the guide pipe 16 falls to the inclined surface of the inclined cavity 12, as shown in fig. 4, the conveying material moves to the left end of the inclined cavity 12 under the guidance of the inclined surface of the inclined cavity 12, and the conveying material is discharged from the leak hole 6;

the first magnet 19 and the second magnet 21 are opposite-pole attraction magnets, and the moving magnet 27 and the moving block 7 are opposite-pole attraction magnets.

The invention can explain its functional principle by the following modes of operation:

starting a motor 8, wherein the output end of the motor 8 drives an input shaft of a reversing box 9 to synchronously rotate through a transmission belt 11, an output shaft 10 is driven to rotate by utilizing the internal structure of the reversing box 9, the output shaft 10 drives a disc 2 to rotate, conveying materials fall onto the disc 2 through external blanking equipment, the disc 2 drives the conveying materials to rotate, the conveying materials collide with a baffle 4 and a driving block 5, and the conveying materials are scraped from the disc 2 and fall onto an external conveying belt for conveying;

when the material is conveyed to impact the driving block 5, the driving block 5 slides towards the inner side of the inclined cavity 12, the guide pipe 16 slides in the through hole 15, the driving block 5 extrudes the spring 14, the driving block 5 drives the first magnet 19 to slide inwards in the first sliding groove 18, the first magnet 19 drives the second magnet 21 to move together, the second magnet 21 slides inwards in the second sliding groove 20, as shown in fig. 5, the second magnet 21 drives the first rack 22 to move upwards, the first rack 22 is meshed with the first gear 24 for transmission, the first gear 24 drives the rotary shaft 23 to rotate, the rotary shaft 23 drives the second gear 25 to rotate, the second gear 25 and the second rack 29 are meshed for transmission, the second rack 29 is driven to move rightwards, the second rack 29 drives the moving magnet 27 to slide rightwards in the first guide groove 26, the moving magnet 27 drives the moving block 7 to move together, the moving block 7 slides rightwards in the second guide groove 28, and the moving block 7 cleans the gap between the disc 2 and the baffle 4;

when the guide pipe 16 abuts against the cover plate 17, the through hole 15 is opened, the conveyed material of the impact driving block 5 enters the guide pipe 16 and falls onto the inclined surface of the inclined cavity 12, the conveyed material moves into the leakage hole 6 under the guide of the inclined surface of the inclined cavity 12, the conveyed material of the impact driving block 5 is discharged from the inclined cavity 12, the conveyed material of the impact driving block 5 is reduced, the driving block 5 slides outwards in the inclined cavity 12 under the elastic force of the spring 14, the first rack 22 moves downwards through the heteropolar attraction force between the first magnet 19 and the second magnet 21, as shown in fig. 5, the second rack 25 and the second rack 29 are meshed and transmitted under the meshing transmission of the first rack 22 and the first gear 24, the second rack 29 moves leftwards, and the moving block 7 moves leftwards through the heteropolar attraction force between the moving magnet 27 and the moving block 7, and the moving block 7 cleans the gap between the disc 2 and the baffle plate 4 again.

The foregoing is only a preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art, who is within the scope of the present invention, should make equivalent substitutions or modifications according to the technical scheme of the present invention and the inventive concept thereof, and should be covered by the scope of the present invention.

Claims

1. The utility model provides a feeding device that disc feeder used, includes organism (1), its characterized in that, be provided with in organism (1):

the device comprises a disc (2), a rotating shaft (3) and a baffle (4), wherein the disc (2) is arranged on a machine body (1), the rotating disc (2) is used for conveying materials, the rotating shaft (3) is rotatably arranged on the machine body (1), the baffle (4) is fixedly sleeved on the rotating shaft (3), and the baffle (4) is used for scraping off the conveyed materials;

the device comprises a driving block (5), a leak hole (6) and a moving block (7), wherein the driving block (5) is arranged in a baffle (4), the driving block (5) is impacted by conveyed materials, the leak hole (6) is formed in the baffle (4), the leak hole (6) is used for releasing the conveyed materials in the baffle (4), the moving block (7) is arranged on the baffle (4), and the moving block (7) is used for cleaning a gap between the baffle (4) and a disc (2);

the driving mechanism is arranged in the baffle plate (4) and is used for driving the moving block (7).

2. Feeding device for a disc feeder according to claim 1, characterized in that the machine body (1) is further provided with:

the motor (8) and the reversing box (9) are fixedly arranged on the machine body (1), and the reversing box (9) is positioned below the disc (2);

the novel reversing device comprises an output shaft (10), an input shaft and a transmission belt (11), wherein the output shaft (10) and the input shaft are rotatably arranged in a reversing box (9), the disc (2) is fixedly connected with the output shaft (10), and the output end of the motor (8) is in transmission connection with the input shaft.

3. Feeding device for a disc feeder according to claim 2, characterized in that the output end and the input shaft of the motor (8) are fixedly provided with driving wheels, and that the output end and the input shaft of the motor (8) are provided with driving belts (11) by means of the driving wheels in a matching manner.

4. A feeder apparatus for a disc feeder as claimed in claim 1, wherein said drive mechanism comprises:

the device comprises an inclined cavity (12), a device cavity (13) and a spring (14), wherein the inclined cavity (12) and the device cavity (13) are formed in a baffle plate (4), the inclined cavity (12) is communicated with the outer end of the baffle plate (4), the spring (14) is welded in the inclined cavity (12), the driving block (5) is sleeved in the inclined cavity (12) in a sliding manner, and the driving block (5) is fixedly connected with the free end of the spring (14);

the guide tube (16) is fixedly installed in the inclined cavity (12), the input end of the guide tube (16) is slidably sleeved in the through hole (15), the through hole (15) and the guide tube (16) are matched and applied to conveying materials of the drainage impact driving block (5), the cover plate (17) is rotatably installed on the driving block (5), the cover plate (17) is used for opening and closing the through hole (15), a torsion spring is fixedly installed on the cover plate (17), and the cover plate (17) and the guide tube (16) are movably abutted against each other;

the device comprises a first chute (18), a first magnet (19), a second chute (20) and a second magnet (21), wherein the first chute (18) and the second chute (20) are respectively arranged on an inclined cavity (12) and an equipment cavity (13), the first chute (18) and the second chute (20) are respectively sleeved with the first magnet (19) and the second magnet (21) in a sliding way, the first magnet (19) and the second magnet (21) are corresponding, and the first magnet (19) is fixedly connected with a driving block (5);

the device comprises a first rack (22), a rotating shaft (23), a first gear (24) and a second gear (25), wherein the first rack (22) is fixedly connected to a second magnet (21), the rotating shaft (23) is rotatably installed in a device cavity (13), the first gear (24) and the second gear (25) are both connected to the rotating shaft (23) in a key way, and the first rack (22) is in meshed connection with the first gear (24);

the device comprises a first guide groove (26), a moving magnet (27) and a second guide groove (28), wherein the first guide groove (26) and the second guide groove (28) are respectively arranged at the lower end positions of a device cavity (13) and a baffle plate (4), the moving magnet (27) and a moving block (7) are respectively sleeved in the first guide groove (26) and the second guide groove (28) in a sliding manner, and the moving magnet (27) corresponds to the moving block (7);

the second rack (29) and accomodate chamber (30), second rack (29) fixed connection is on moving magnet (27), and second rack (29) and second gear (25) meshing are connected, accomodate chamber (30) and offer in baffle (4), and accomodate chamber (30) and equipment chamber (13) and be linked together, second rack (29) movable sleeve is located in accomodate chamber (30).

5. The feeding device for a disc feeder according to claim 4, wherein the bottom end of the inclined cavity (12) and the bottom end of the driving block (5) are respectively provided with an inclined surface, the lowest point of the inclined surface of the inclined cavity (12) is positioned at the position of the leak hole (6), and the output end of the guide pipe (16) is positioned above the inclined surface of the inclined cavity (12).

6. The feeder device for a disk feeder according to claim 4, wherein the first magnet (19) and the second magnet (21) are opposite-pole attracting magnets, and the moving magnet (27) and the moving block (7) are opposite-pole attracting magnets.