CN221069888U

CN221069888U - Magnet feeder that can overturn

Info

Publication number: CN221069888U
Application number: CN202322520774.4U
Authority: CN
Inventors: 徐锭成; 徐海洋
Original assignee: Dongyang Haicheng Electromechanical Materials Co ltd
Current assignee: Dongyang Haicheng Electromechanical Materials Co ltd
Priority date: 2023-09-18
Filing date: 2023-09-18
Publication date: 2024-06-04
Anticipated expiration: 2033-09-18

Abstract

The utility model discloses a reversible magnet feeder, which relates to the technical field of feeders and comprises a first connecting frame and a rotating roller, wherein a driving motor is fixedly arranged at the right end of the outer side of the first connecting frame, a transmission shaft lever is arranged at the output end of the driving motor and is rotationally connected with the inner side of the right end of the first connecting frame through a bearing, the rotating roller is fixedly arranged in the middle of the surface of the transmission shaft lever, separation blades are uniformly distributed on the surface of the rotating roller, and the shape of the separation blades is a right triangle. This magnet feeder that can overturn compares with current ordinary magnet feeder, accomplishes automatic turn-over face work to magnet, is convenient for the manual work and inspects magnet both sides face, need not the manual turn-over face that turns over of manual work, reduces the manual work volume, and is provided with a plurality of separation blades and can continuously rotate and turn over the turn-over face to a plurality of magnets that follow-up transported, has improved the efficiency of work greatly.

Description

Magnet feeder that can overturn

Technical Field

The utility model relates to the technical field of magnet feeders, in particular to a reversible magnet feeder.

Background

In the production process of the magnet, the magnet is required to be fed, detected, fed with good products and fed with defective products, and the current detection mode is mainly implemented by manual detection and material separation operation.

The utility model discloses a magnet loading attachment, this file, material conveying mechanism will wait to process magnet and convey to magnet separating mechanism, magnet screening mechanism, magnet detection mechanism and magnet feeding mechanism in proper order, and magnet separating mechanism is to wait to process magnet heating and makes its temporary demagnetization, and magnet screening mechanism is to wait to process magnet after the separation according to different specification sizes and screen, and magnet detection mechanism is to wait to process magnet surface to detect, magnet feeding mechanism will reject the passing and send out, and the conforming article continues to convey through material conveying mechanism, can realize automatic magnet material loading to magnet material loading in-process can not adsorb together because of magnetic force, and the magnetism of magnet can resume by oneself after the temperature reduction, can screen through changing the specification size of screen tray to magnet simultaneously, but magnet is carrying the inspection in-process, need to detect magnet both sides, and the device needs the manual turn-over to detect, and magnet is carried in a large number, and manual turn-over detects very manpower one by one, and turn speed is slower, influences whole work efficiency.

In view of the above, an improvement of the conventional structure has been studied and proposed as a reversible magnet feeder.

Disclosure of utility model

The utility model aims to provide a reversible magnet feeder, which solves the problems in the prior art.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a magnet feeder that can overturn, includes first link and rotatory roller, the outside right-hand member fixed mounting of first link has driving motor, driving motor's output is provided with the transmission axostylus axostyle, and the transmission axostylus axostyle passes through the bearing and rotates with the right-hand member inboard of first link to be connected, rotatory roller is fixed to be set up in the surface middle part of transmission axostylus axostyle, rotatory roller's surface evenly distributed is provided with partition vane, and partition vane's shape is right triangle, the right-hand member of first link is provided with the assembly frame through fixing bolt, the second link is installed through fixing bolt to the upper end inboard of assembly frame.

Preferably, the sinking groove of the first connecting frame is internally provided with a second conveyor belt, the outer side of the left end of the first connecting frame is provided with a stepping motor, and the stepping motor is connected with the second conveyor belt.

Preferably, a sorting bin is arranged above the surface of the first connecting frame, a partition plate is fixedly arranged above the inner surface of the sorting bin, and four partition plates are uniformly distributed above the inner surface of the sorting bin.

Preferably, a guide head is arranged at one end of the partition plate, which is close to the assembly frame, and a distributing roller is rotatably arranged in the middle of the surface of the guide head through a bearing.

Preferably, grooves are formed in two sides of the surface of the partition board, and guide rollers are rotatably arranged at the upper end and the lower end of the inner surface of the grooves through bearings.

Preferably, a first conveyor belt is arranged in the sinking groove of the second connecting frame, a servo motor is fixedly arranged on the outer side of the right end of the surface of the second connecting frame, and the servo motor is connected with the first conveyor belt.

Preferably, a heating box is fixedly arranged above the surface of the second connecting frame, a baffle is fixedly arranged at an outlet below the front side of the surface of the heating box, and the baffle is spaced from the surface of the first conveyor belt by a certain height according to the thickness of the magnet.

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

1. According to the utility model, through the arrangement of the driving motor, the transmission shaft rod, the rotating roller and the separation blades, after the first conveyor belt conveys the magnet to the tail end, the magnet falls to the middle part of the interval of the separation blades, the back surface of the magnet leans against the front inclined surface of the separation blades in an inclined way, the driving motor drives the rotating roller and the separation blades to rotate continuously through the transmission shaft rod, so that the magnet rotates along with the rotation, when the separation blades rotate to incline to one side, the magnet is influenced by gravity, the right angle surface of the separation blades leans forwards, the back surface of the magnet is exposed upwards, when the separation blades rotate to be flush with the second conveyor belt, the part of the magnet protruding the separation blades is overlapped on the surface of the second conveyor belt and is conveyed along with the second conveyor belt, automatic turnover surface work is finished on the magnet, the two sides of the magnet is convenient to check, manual turnover surface is not needed, the manual labor is reduced, and a plurality of separation blades can rotate continuously to turn over the plurality of subsequently conveyed magnets, so that the working efficiency is greatly improved;

2. according to the utility model, through the arrangement of the first conveyor belt, the servo motor, the heating box and the baffle, the servo motor drives the first conveyor belt to move and convey, the magnets are driven to be conveyed, the magnets enter the heating box and are continuously heated, the magnets lose magnetism temporarily due to high temperature, the magnets can continue to move along with the first conveyor belt after losing magnetism, the magnets which are adsorbed and stacked can be pushed by the baffle, the magnets are tiled on the first conveyor belt, the magnets are prevented from being mutually adsorbed and overlapped due to magnetic force, the subsequent overturning work is influenced, and the magnets can be automatically tiled, so that people can directly topple and fully put the magnets when the magnets are placed for conveying, the magnets do not need to be manually put horizontally one by one, and the conveying efficiency is further improved;

3. According to the utility model, through the arrangement of the second conveyor belt, the stepping motor, the sorting bin, the partition plate, the guide head, the distributing roller, the groove and the guide roller, the stepping motor drives the second conveyor belt to convey the magnets with the turnover surface, the magnets can enter the sorting bin, and the second conveyor belt continuously drives the magnets to advance, so that the magnets can collide with the guide head, rotate through the distributing roller and move into the guide cavities formed on two sides of the partition plate, and when the magnets move in the cavities, the positions of the magnets are continuously corrected through the plurality of guide rollers on the partition plate, so that the conveyed magnets can be orderly and uniformly placed, conveyed, collected and stored, and the positions of the magnets can be automatically ordered, so that the magnets are conveyed more orderly.

Drawings

FIG. 1 is a schematic view of the overall three-dimensional structure of the present utility model;

FIG. 2 is a schematic view of the divider vane and rotating roller configuration of the present utility model;

FIG. 3 is a schematic diagram of a right side cross-sectional structure of a first connector of the present utility model;

fig. 4 is an enlarged schematic view of the structure of fig. 3 a according to the present utility model.

In the figure: 1. a first connection frame; 2. a driving motor; 3. a transmission shaft lever; 4. a rotating roller; 5. a partition blade; 6. an assembly frame; 7. a second connecting frame; 8. a first conveyor belt; 9. a servo motor; 10. a heating box; 11. a baffle; 12. a second conveyor belt; 13. a stepping motor; 14. sorting bins; 15. a partition plate; 16. a guide head; 17. a distributing roller; 18. a groove; 19. and (5) guiding the roller.

Detailed Description

The following description of the embodiments of the present utility model 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 utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

As shown in fig. 1-2, a reversible magnet feeder comprises a first connecting frame 1 and a rotary roller 4, wherein a driving motor 2 is fixedly arranged at the right end of the outer side of the first connecting frame 1, a transmission shaft lever 3 is arranged at the output end of the driving motor 2, the transmission shaft lever 3 is rotatably connected with the inner side of the right end of the first connecting frame 1 through a bearing, the rotary roller 4 is fixedly arranged in the middle part of the surface of the transmission shaft lever 3, separation blades 5 are uniformly distributed on the surface of the rotary roller 4, the separation blades 5 are right-angled triangle, an assembly frame 6 is arranged at the right end of the first connecting frame 1 through a fixing bolt, and a second connecting frame 7 is arranged at the inner side of the upper end of the assembly frame 6 through a fixing bolt.

Further, the front side of the separation blade 5 is provided with an inclined plane, the rear side is provided with a right-angle surface, and when the magnet falls into the middle part of the interval of the separation blade 5, the back surface of the magnet is inclined to lean against the inclined plane of the front side of the separation blade 5.

Further, the driving motor 2 drives the rotating roller 4 and the separating blades 5 to continuously rotate through the transmission shaft lever 3.

Further, when the partition blade 5 is rotated to incline to one side, the magnet will lean against the right-angle surface of the partition blade 5 in the front direction under the influence of gravity, so that the original back surface of the magnet will be exposed upwards.

Further, the length of the magnet is greater than that of the separation blade 5, so that when the separation blade 5 rotates to be flush with the second conveyor belt 12, the part of the magnet protruding out of the separation blade 5 can be lapped on the surface of the second conveyor belt 12, and then is conveyed along with the second conveyor belt 12, and automatic turnover face work is completed on the magnet.

As shown in fig. 1, 3 and 4, the second conveyor belt 12 is arranged inside the sink tank of the first connecting frame 1, the stepping motor 13 is arranged outside the left end of the first connecting frame 1, the stepping motor 13 is connected with the second conveyor belt 12, the sorting bin 14 is arranged above the surface of the first connecting frame 1, the partition plate 15 is fixedly arranged above the inner surface of the sorting bin 14, four partition plates 15 are uniformly distributed above the inner surface of the sorting bin 14, the guide head 16 is arranged at one end of the partition plate 15 close to the assembly frame 6, the distribution roller 17 is rotatably arranged in the middle of the surface of the guide head 16 through a bearing, the grooves 18 are formed in both sides of the surface of the partition plate 15, the guide rollers 19 are rotatably arranged at the upper end and the lower end of the inner surface of the grooves 18 through a bearing, the first conveyor belt 8 is arranged inside the sink tank of the second connecting frame 7, the servo motor 9 is fixedly arranged outside the right end of the surface of the second connecting frame 7, the servo motor 9 is connected with the first conveyor belt 8, the heating box 10 is fixedly arranged above the surface of the second connecting frame 7, the heating box 10 is fixedly arranged at the front side of the heating box 10, and the magnet is fixedly arranged at the front side of the heating box 11 at a certain distance from the front side of the heating box 11, and the front surface of the heating box is arranged at a certain distance from the front side of the heating box 11, and a certain distance is arranged at the front side of the front of the heating box 11, and a certain distance, according to the height, and the magnet is arranged.

Further, the servo motor 9 drives the first conveyor belt 8 to move and convey, and drives the magnet to carry out preliminary conveying.

Further, the heating box 10 heats the magnet transported to the inside, so that the magnetism of the magnet temporarily disappears, and the magnet to be attracted and stacked can be pushed by the baffle 11, so that the magnet is tiled on the first conveyor belt 8, and the magnet is prevented from being attracted and stacked by the magnetic force.

Further, the stepping motor 13 drives the second conveyor belt 12 to convey the magnet with the turnover surface.

Further, the magnet can get into the inside of letter sorting storehouse 14, because second conveyer belt 12 constantly drives the magnet and advances, and the magnet can collide guide head 16, rotates through allocating roller 17, moves in the direction cavity that forms to baffle 15 both sides, adjusts the transport output position of magnet, prevents that the magnet from carrying the time of being mixed and disorderly.

Further, when the magnet moves in the cavity, the position is continuously corrected by the guide rollers 19 on the partition plate 15, so that the conveyed magnet can be orderly and linearly and uniformly placed.

Working principle: when the reversible magnet feeder is used, firstly, the magnets are all dumped on the first conveyor belt 8 manually, the servo motor 9 drives the first conveyor belt 8 to move and convey, the magnets are driven to be conveyed, the magnets enter the heating box 10 and continuously heat up, the magnets lose magnetism temporarily due to high temperature, the magnets continue to move along with the first conveyor belt 8 after losing magnetism, the magnets which are adsorbed and stacked can be pushed by the baffle 11, the magnets are flatly paved on the first conveyor belt 8, the magnets are prevented from being adsorbed and overlapped by magnetic force, the magnets fall to the middle part of the interval of the separation blades 5 after being conveyed to the tail end by the first conveyor belt 8, the back surfaces of the magnets obliquely lean against the inclined surfaces of the front sides of the separation blades 5, the driving motor 2 drives the rotary roller 4 and the separation blades 5 to rotate continuously through the transmission shaft lever 3, the magnets rotate along with the separation blades 5, when the separation blade 5 rotates to incline to one side, under the influence of gravity, the magnet can lean against the right-angle surface of the separation blade 5 in the front, the back surface of the magnet can be exposed upwards, when the separation blade 5 rotates to be flush with the second conveyor belt 12, the part of the magnet protruding the separation blade 5 can overlap the surface of the second conveyor belt 12 and carry along the second conveyor belt 12, the magnet finishes the automatic turnover surface work, then the stepping motor 13 drives the second conveyor belt 12 to carry the magnet with the turnover surface, the magnet can enter the sorting bin 14, the magnet is continuously driven to advance by the second conveyor belt 12, the magnet can collide the guide head 16 and rotate through the distributing roller 17, the magnet moves into the guide cavity formed at two sides of the partition plate 15, when the magnet moves in the cavity, the position of the magnet is continuously corrected by the plurality of guide rollers 19 on the partition plate 15, the delivered magnet is enabled, can be orderly and uniformly placed, which is the working principle of the reversible magnet feeder.

Claims

1. The utility model provides a magnet feeder that can overturn, includes first link (1) and rotatory roller (4), its characterized in that, the outside right-hand member fixed mounting of first link (1) has driving motor (2), the output of driving motor (2) is provided with driving shaft pole (3), and driving shaft pole (3) are connected through bearing and the inboard rotation of the right-hand member of first link (1), rotatory roller (4) are fixed to be set up in the surface middle part of driving shaft pole (3), the surface evenly distributed of rotatory roller (4) is provided with separation blade (5), and separation blade (5) are right triangle in shape, the right-hand member of first link (1) is provided with assembly jig (6) through fixing bolt, second link (7) are installed through fixing bolt to the upper end inboard of assembly jig (6).

2. A reversible magnet feeder according to claim 1, characterized in that the sink inside of the first connecting frame (1) is provided with a second conveyor belt (12), and the left end outside of the first connecting frame (1) is provided with a stepping motor (13), and the stepping motor (13) is connected with the second conveyor belt (12).

3. A reversible magnet feeder according to claim 1, characterized in that the surface top of the first connecting frame (1) is provided with a sorting bin (14), and that the inner surface top of the sorting bin (14) is fixedly provided with a partition (15), and that the partition (15) is evenly distributed along the inner surface top of the sorting bin (14).

4. A reversible magnet feeder according to claim 3, characterized in that the end of the partition plate (15) close to the assembly frame (6) is provided with a guide head (16), and the middle part of the surface of the guide head (16) is rotatably provided with a distributing roller (17) through a bearing.

5. A reversible magnet feeder according to claim 3, wherein grooves (18) are formed on both sides of the surface of the partition plate (15), and guide rollers (19) are rotatably provided at both upper and lower ends of the inner surface of the grooves (18) through bearings.

6. The reversible magnet feeder according to claim 1, wherein a first conveyor belt (8) is arranged in the sink of the second connecting frame (7), a servo motor (9) is fixedly arranged on the outer side of the right end of the surface of the second connecting frame (7), and the servo motor (9) is connected with the first conveyor belt (8).

7. A reversible magnet feeder according to claim 1, characterized in that a heating box (10) is fixedly arranged above the surface of the second connecting frame (7), a baffle (11) is fixedly arranged at the outlet below the front side of the surface of the heating box (10), and the baffle (11) is spaced from the surface of the first conveyor belt (8) by a certain height according to the thickness of the magnet.