CN117381513A

CN117381513A - Feeding device for sprocket machining

Info

Publication number: CN117381513A
Application number: CN202311409374.4A
Authority: CN
Inventors: 黄筱妍; 巫新锋
Original assignee: Feiben Chain Co ltd Of Jixi Anhui Province
Current assignee: Feiben Chain Co ltd Of Jixi Anhui Province
Priority date: 2023-10-27
Filing date: 2023-10-27
Publication date: 2024-01-12

Abstract

The invention discloses a feeding device for sprocket machining, which comprises a steering mechanism, wherein the steering mechanism comprises a steering table, the steering table is driven by a driving mechanism to rotate by 90 degrees, the steering table comprises a bottom plate, a vertical plate and a rotating plate, the vertical plate is fixed on the side wall of the bottom plate, and the lower end of the rotating plate is hinged with the upper end of the vertical plate; the material receiving mechanism is arranged on one side of the steering mechanism and comprises a feeding channel, a first feeding port is arranged on the feeding channel, a placing area and a feeding area are respectively arranged on two sides of the feeding channel, the placing area and the feeding area are respectively communicated with the feeding channel, one side, far away from the discharging port, of the feeding channel, one side, far away from the feeding channel, of the placing area, and one side, far away from the feeding channel, of the feeding area are respectively provided with a pushing mechanism; the material receiving seat is used for placing materials after the steering mechanism steers, and feeding is carried out through the feeding channel. The feeding device for sprocket machining can connect a blank cutting procedure with a sprocket machining procedure, simplifies the process and can enable the material receiving seat to feed orderly.

Description

Feeding device for sprocket machining

Technical Field

The invention relates to the field of sprocket machining, in particular to a feeding device for sprocket machining.

Background

The sprocket is a cog sprocket wheel for meshing with precisely pitched blocks on links or cables. The chain wheel is widely applied to mechanical transmission and the like in the industries of chemical industry, textile machinery, escalator, wood processing, three-dimensional parking garage, agricultural machinery, food processing, instrument and instrument, petroleum and the like. When the chain wheel is processed, firstly, the cylindrical blank is cut, and then the cut blank is conveyed to a cutting position of the chain wheel for drilling, tooth processing and other operations. When cutting, the cylindrical blanks are generally transversely placed for cutting due to the long length, and then directly fall into a collecting box. When the chain wheel is processed, carding is carried out on the direction of the cut cylindrical blanks, so that the cylindrical blanks are vertically placed in the receiving seat at last, and then the receiving seat conveys the blanks. Because the orientation of the blanks in the collecting box is different and disordered, a recognition mechanism is generally arranged to recognize the orientation of the blanks in the feeding process, and then the blanks which are not vertically placed are turned, but the problem of missed detection can occur due to more feeding. Secondly, the material receiving seat after the completion of the use of the sprocket wheel processing can be put into the material receiving seat by the mechanical arm again, because the material receiving seat at the material receiving position is moving and running all the time, the material receiving seat after the completion of the use is put into the material receiving seat, the position of the material receiving seat which is ordered can be influenced, the position of the material receiving seat can be deviated, the manual movement and the resetting of the deviated material receiving seat are required by a worker, and the time and the labor are wasted.

Disclosure of Invention

The invention aims to provide a feeding device for sprocket machining, which can connect a blank cutting procedure with a sprocket machining procedure, simplify the process and enable a receiving seat to feed orderly.

In one aspect, the invention provides a feed device for sprocket processing. According to an embodiment of the invention, the apparatus comprises:

the steering mechanism comprises a steering table, the steering table is driven by the driving mechanism to rotate by 90 degrees, the steering table comprises a bottom plate, a vertical plate and a rotating plate, the vertical plate is fixed on the side wall of the bottom plate, and the lower end of the rotating plate is hinged with the upper end of the vertical plate;

the material receiving mechanism is arranged on one side of the steering mechanism and comprises a feeding channel, a first feeding port is arranged on the feeding channel, a placing area and a feeding area are respectively arranged on two sides of the feeding channel, the placing area and the feeding area are respectively communicated with the feeding channel, and a pushing mechanism is respectively arranged on one side, far away from the discharging port, of the feeding channel, on one side, far away from the feeding channel, of the placing area;

the material receiving seat is used for placing materials after the steering mechanism steers, and feeding is carried out through the feeding channel.

In addition, the feeding device for sprocket processing according to the above embodiment of the present invention may further have the following additional technical features:

in some embodiments of the present invention, a sliding groove is formed on the vertical plate, a limiting block is arranged in the sliding groove, a first moving groove is formed in the bottom plate, the first moving groove is communicated with the sliding groove, a first rack is arranged in the first moving groove, a first spring is fixed at the bottom of the first moving groove, the upper end of the first spring is fixed with the first rack, a second moving groove is formed in the vertical plate, a second rack is arranged in the second moving groove, and a gear is arranged between the first rack and the second rack and is meshed with the gear respectively.

In some embodiments of the present invention, a groove one is provided on an inner wall of an upper portion of the chute, a spring two is provided in the groove one, and an end of the spring two away from the groove one is fixed with the stop block.

In some embodiments of the present invention, the driving mechanism includes a motor, an output shaft of the motor is fixed with a rotating shaft, the rotating shaft is fixed with a rotating frame, a first cylinder is fixed on the rotating frame, and a piston rod of the first cylinder is fixed with a lower end of the bottom plate.

In some embodiments of the present invention, a second cylinder is fixed on the rotating frame, a piston rod of the second cylinder is fixed with a fixing frame, a first push rod and a second push rod are fixed on the fixing frame, and a through hole for the first push rod and the second push rod to pass through is formed in the bottom plate.

In some embodiments of the invention, the material receiving seat comprises a supporting plate and three side plates, wherein the three side plates are fixed at the upper end of the supporting plate, a groove II is formed at the upper end of the supporting plate, a spring III is fixed in the groove II, the upper end of the spring III is fixed with a clamping block, and the vertical section of the clamping block is in a right-angle triangle shape.

In some embodiments of the invention, a movement mechanism is also included for moving the receptacles within the feed channel onto the transfer mechanism.

In some embodiments of the present invention, the moving mechanism includes a moving plate, two opposite clamping plates are fixed on the moving plate, the moving plate can move, an electromagnet is fixed at opposite ends of the clamping plates, and an iron plate is fixed on the outer wall of the receiving seat.

In some embodiments of the present invention, the moving mechanism further includes a mounting frame, a sliding hole is formed on the mounting frame, a screw rod and a sliding block are arranged in the sliding hole, one end of the screw rod is connected with the inner wall of the sliding hole through a bearing, the other end of the screw rod is fixed with an output shaft of the motor, the screw rod passes through the sliding block and is connected with the sliding block through threads, a third air cylinder is fixed on the sliding block, and a piston rod of the third air cylinder is fixed with the moving plate.

In some embodiments of the invention, the mounting is secured to a rotatable turntable.

Compared with the prior art, the invention has the beneficial effects that:

1) According to the invention, the steering mechanism is arranged and is directly arranged at the outlet of the blank cutting device, so that all blanks can be conveniently steered without additionally arranging an identification mechanism, and the omission problem can be avoided.

2) According to the invention, the placement area is arranged and is specially used for placing the used material receiving seats, so that the material receiving seats in the placement area orderly enter the feeding channel, and the position of the material receiving seats does not need to be manually adjusted.

Drawings

FIG. 1 is a schematic view of a sprocket processed feeding apparatus according to an embodiment of the present invention;

FIG. 2 is a schematic view of the structure of a steering stage and a driving mechanism according to an embodiment of the present invention;

FIG. 3 is a schematic view of a steering stage according to an embodiment of the present invention;

fig. 4 is an enlarged view at a in fig. 3;

FIG. 5 is a schematic view of the structure of the first and second push rods according to the embodiment of the present invention;

FIG. 6 is a schematic view of a material receiving seat according to an embodiment of the present invention;

fig. 7 is a schematic view of the structure of a support plate in an embodiment of the present invention;

in the figure, 1, a rotating shaft, 2, a connecting rod, 3, a circular rotating plate, 4, a fixed plate, 5, a first cylinder, 6, a bottom plate, 7, a vertical plate, 8, a rotating plate, 9, a sliding groove, 10, a limiting block, 11, a groove I, 12, a spring II, 13, a stop block, 14, a moving groove I, 15, a spring I, 16, a rack I, 17, a moving groove II, 18, a rack II, 19, a gear, 20, a second cylinder, 21, a fixed frame, 22, a push rod I, 23, a push rod II, 24, a perforation I, 25, a perforation II, 26, a feeding channel, 27, a feeding port I, 28, a placement area, 29, a feeding area, 30, a cylinder IV, 31, a cylinder V, 32, a cylinder VI, 33, a perforation III, 34, a side plate, 35, a supporting plate 36, a groove II, 37, a spring III, 38, a clamping block, 39, a rotating table, 40, a mounting bracket 41, a moving plate 42, a sliding hole, 43, a screw rod, 44, a sliding block, 45, a cylinder III, 46, a clamping plate, 47, an electromagnet, an iron plate 48, 49, a side plate 50, and a feeding port II.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1, a feeding device for sprocket processing includes a steering mechanism, a receiving seat, and a moving mechanism.

As shown in fig. 2, the steering mechanism comprises a steering table and a driving mechanism, and the steering table is driven by the driving mechanism to rotate by 90 degrees. The drive mechanism includes a motor that may be fixed to the frame (the motor and frame are not shown). The output shaft of the motor is fixed with the rotating shaft 1, and the rotating shaft 1 can be connected with the frame through a bearing, so that the stability is improved. The rotating shaft 1 is fixed with the rotating frame, the rotating frame comprises a connecting rod 2 and a circular rotating plate 3, the circular rotating plate 3 is fixed with the rotating shaft 1 through a plurality of connecting rods 2, and the circular rotating plate 3 can be provided with two rotating plates. The fixing plate 4 can be fixed on the connecting rod, the first air cylinder 5 is fixed on the fixing plate 4, and the piston rod of the first air cylinder 5 is fixed with the lower end of the steering table. The steering table comprises a bottom plate 6, a vertical plate 7 and a rotating plate 8, wherein the vertical plate 7 is fixed on the side wall of the bottom plate 6, the lower end of the rotating plate 8 is hinged with the upper end of the vertical plate 7, and the upper end of the bottom plate 6 can be symmetrically fixed with two side plates 49. The electromagnet and the iron plate can be fixed on the periphery of the bottom plate 6 and the circular rotating plate 3 respectively, so that the stability is enhanced. The vertical plate 7 is provided with a chute 9, a limiting block 10 is arranged in the chute 9, and the limiting block 10 extends to one side of the rotating plate 8 when positioned at the uppermost end of the chute 9, so that the limiting block can limit the rotating plate 8. As shown in fig. 4, a first groove 11 is formed in the inner wall of the upper portion of the chute 9, a second spring 12 is arranged in the first groove 11, and one end, away from the first groove 11, of the second spring 12 is fixed with a stop block 13. The stop block 13 can play a supporting role on the limiting block 10, and the limiting block 10 is prevented from sliding to the bottommost end of the sliding groove 9 under the action of gravity. As shown in fig. 3, a first moving groove 14 is arranged in the bottom plate 6, the first moving groove 14 is communicated with the sliding groove 9, and the lower end of the sliding groove 9 is positioned below the upper end of the first moving groove 14. A first rack 16 is arranged in the first moving groove 14, a first spring 15 is fixed at the bottom of the first moving groove 14, and the upper end of the first spring 15 is fixed with the first rack 16. The vertical plate 7 is internally provided with a second moving groove 17, a second rack 18 is arranged in the second moving groove 17, a gear 19 is arranged between the first rack 16 and the second rack 18 and is respectively connected with the gear 19 in a meshed manner, the vertical plate 7 is internally provided with a cavity, the gear 19 is arranged in the cavity through a rotating shaft, and the rotating shaft is connected with the inner wall of the cavity through a bearing. The rotating frame is fixedly provided with a second air cylinder 20, a piston rod of the second air cylinder 20 is fixed with a fixed frame 21, a first push rod 22 and a second push rod 23 are fixed on the fixed frame 21, the first push rod 22 is longer than the second push rod 23, the second push rod 23 is provided with two push rods and is respectively arranged on two sides of the first rack 16, and the second push rod 23 is positioned below the limiting block 10. As shown in fig. 2, the bottom plate 6 is provided with a first through hole 24 and a second through hole 25 for the first push rod 22 and the second push rod 23 to pass through, the second through hole 25 is communicated with the first through hole 24, and the second through hole 25 is communicated with the first moving groove 14.

As shown in fig. 1, the receiving mechanism is disposed at one side of the steering mechanism, and the receiving mechanism includes a feed channel 26. The feed channel 26 is formed by a strip box body with an open upper end, and one end of the feed channel 26, which is close to the steering mechanism, is provided with a feed inlet I27. The feed channel 26 both sides are equipped with respectively and place district 28 and feed district 29, place district 28 and feed district 29 respectively with feed channel 26 intercommunication, place district 28 upper end and be close to the one end of feed channel 26 and be uncovered, the upper end of feed district 29 and be uncovered near the one end of feed channel 26, and feed district 29 is provided with feed inlet two 50, the material receiving seat in the feed district 29 is by feed inlet two 50 feeding, accessible current conveyer belt realization feeding. One side of the feeding channel 26 far away from the discharge hole is provided with a fourth air cylinder 30, one side of the placement area 28 far away from the feeding channel 26 is provided with a fifth air cylinder 31, one side of the feeding area 29 far away from the feeding channel 26 is provided with a sixth air cylinder 32 respectively, and the feeding channel 26, the placement area 28 and the feeding area 29 are provided with a third perforation 33 for the piston rods of the fourth air cylinder 30, the fifth air cylinder 31 and the sixth air cylinder 32 to penetrate through respectively. Gravity sensors are respectively arranged at the bottoms of the placement area 28 and the bottom of the first 27 parts of the feeding channel 26, and are connected with the gravity sensors through a controller, and the work of other power mechanisms is controlled. Further, the feeding channel 26 can be arranged to be movable in the horizontal direction, so that the feeding channel can be conveniently in butt joint with the material receiving platform, and an existing driving mechanism can be adopted as a moving driving mechanism.

The material receiving seat is used for feeding through the feeding channel 26 and is used for placing materials after the steering mechanism steers. As shown in fig. 6, the material receiving seat comprises a support plate 35 and three side plates 34, the three side plates 34 are fixed at the upper end of the support plate 35, the upper end of the material receiving seat and the side end at the first 27 of the material inlet are both open, as shown in fig. 7, the upper end of the support plate 35 is provided with a second groove 36, a third spring 37 is fixed in the second groove 36, the upper end of the third spring 37 is fixed with a clamping block 38, the vertical section of the clamping block 38 is in a right-angle triangle shape, and one side far away from the three side plates 34 is provided with a bevel edge.

As shown in fig. 1, the moving mechanism is used to move the receiving seats in the feed channel 26 onto the transfer mechanism. The moving mechanism includes a rotary table 39, a mounting frame 40, and a moving plate 41, and the rotary table 39 is rotatable under motor control. The mounting frame 40 is fixed at the upper end of the rotary table 39, a sliding hole 42 is formed in the mounting frame 40, a screw rod 43 and a sliding block 44 are arranged in the sliding hole 42, and the sliding block 44 is abutted against the inner wall of the sliding hole 42. One end of a screw rod 43 is connected with the inner wall of the sliding hole 42 through a bearing, the other end of the screw rod 43 is fixed with an output shaft of a motor, the screw rod 43 penetrates through a sliding block 44 and is connected with the sliding block 44 through threads, a third air cylinder 45 is fixed on the sliding block 44, and a piston rod of the third air cylinder 45 is fixed with the moving plate 41. Two opposite clamping plates 46 are fixed on the moving plate 41, electromagnets 47 are respectively embedded and fixed at opposite ends of the clamping plates 46, and iron plates 48 are embedded and fixed on the outer wall of the material receiving seat.

Working principle: when the gravity sensor of the first feeding port 27 senses that the position of the first feeding port does not have a receiving seat, and the gravity sensor in the placement area 28 also senses that the placement area 28 does not have a receiving seat, the sixth cylinder 32 is started, the sixth cylinder 32 pushes the receiving seat of the first feeding port 29 into the first feeding port 26, and then the fourth cylinder 30 is started again to push the receiving seat in the first feeding port 26 to the first feeding port 27. When the gravity sensor of the discharge hole senses that the position of the discharge hole does not have a receiving seat, and the gravity sensor in the placement area 28 also senses that the placement area 28 has the receiving seat, the fifth cylinder 31 is started, the fifth cylinder 31 pushes the receiving seat in the placement area 28 into the feeding channel 26, then the fourth cylinder 30 is started again, and the receiving seat in the feeding channel 26 is pushed to the first feeding hole 27. Thereby ensuring that the first 27 part of the feeding port is always provided with a receiving seat.

After the cylindrical blanks are cut, starting the first air cylinder 5, enabling the first air cylinder 5 to drive the bottom plate 6 to move upwards, enabling the side end of the rotating plate 8 to contact with the side end of the cut blanks until the blanks contact with the limiting block 10, enabling the blanks to move downwards relatively to squeeze the limiting block 10, enabling the limiting block 10 to squeeze the limiting block 13, and enabling the second spring 12 to shrink. Under the action of gravity of the blank and the limiting block 10, the limiting block 10 moves downwards until the blank contacts with the upper end of the bottom plate 6, the limiting block 10 moves to the lowest end of the chute 9, the limiting block 10 extrudes the first rack 16, the first rack 16 moves downwards, the first rack 16 drives the gear 19 to rotate, the gear 19 drives the second rack 18 to move upwards, the second rack 18 extrudes the rotating plate 8, the rotating plate 8 rotates until the rotating plate 8 is vertical to the vertical plate 7, namely, the rotating plate 8 is positioned at the upper end of the blank at the moment, and the blank can be prevented from sliding in the subsequent rotating process. The first cylinder 5 is reset, and the bottom plate 6 moves to the periphery of the circular rotating plate 3.

The motor is utilized to drive the rotating shaft 1 to rotate, the rotating shaft 1 drives the circular rotating plate 3 and the steering table to rotate 90 degrees, the receiving table rotates to the first 27 of the feeding hole of the feeding channel 26, and the upper end face of the vertical plate 7 is level with the upper end face of the first 27 of the feeding hole. Then, the second cylinder 20 is started, the second cylinder 20 drives the first push rod 22 and the second push rod 23 to move forwards, the first push rod 22 passes through the first through hole 24 to contact the blank first, the blank is pushed forwards, the blank extrudes the rotating plate 8 until the rotating plate rotates to the horizontal direction, and at the moment, the first cylinder 5 can be operated to enable the rotating plate 8 to abut against the first feeding hole 27. And in the rotating process of the rotating plate 8, the second rack 18 is extruded to reset, the second rack 18 drives the gear 19 to rotate, and the gear 19 drives the first rack 16 to move upwards to reset. The second push rod 23 is used for pushing the limiting block 10 to move to the uppermost end of the sliding groove 9, the stop block 13 pops up, and the limiting block 10 is limited.

The first push rod 22 pushes the blank on the steering table into the receiving seat, the clamping block 38 is extruded when the blank enters the receiving seat, and after the blank completely enters the receiving seat, the clamping block 38 drives the clamping block 38 to reset under the action of the third spring 37, so that the blank is prevented from falling from the side open end of the receiving seat. After the blank enters the receiving seat, the steering table is reset and rotated to the position right above the rotating shaft 1.

And the third air cylinder 45 is started, and the third air cylinder 45 drives the clamping plate 46 to move to two sides of the material receiving seat, and the electromagnetic plate on the clamping plate 46 is electrified, so that the clamping plate 46 is fixed with the material receiving seat. The clamping plate 46 is driven to move upwards by the screw rod 43, so that the material receiving seat is separated from the feeding channel 26, the rotary table 39 is rotated, the material receiving seat is moved to the upper part of the feeding conveyor belt, and then the material receiving seat is placed on the conveyor belt through the screw rod 43 and conveyed to a sprocket machining part. When the use of the receiving seat is completed, the receiving seat is moved into the placement area 28 by the mechanical arm.

The foregoing is merely illustrative and explanatory of the invention, as it is well within the scope of the invention, as it is intended to provide those skilled in the art with various modifications, additions and substitutions to the specific embodiments disclosed and those skilled in the art without departing from the scope of the invention as disclosed in the accompanying claims.

Claims

1. A sprocket tooling feed apparatus comprising:

2. A sprocket process feeding apparatus as set forth in claim 1 wherein: the novel sliding block is characterized in that a sliding groove is formed in the vertical plate, a limiting block is arranged in the sliding groove, a first moving groove is formed in the bottom plate and communicated with the sliding groove, a first rack is arranged in the first moving groove, a first spring is fixed at the bottom of the first moving groove, the upper end of the first spring is fixed with the first rack, a second moving groove is arranged in the vertical plate, a second rack is arranged in the second moving groove, and a gear is arranged between the first rack and the second rack and is in meshed connection with the gear respectively.

3. A sprocket machined feed apparatus as set forth in claim 2 wherein: the inner wall of the upper part of the sliding groove is provided with a first groove, a second spring is arranged in the first groove, and one end, away from the first groove, of the second spring is fixed with the stop block.

4. A sprocket process feeding apparatus as set forth in claim 1 wherein: the driving mechanism comprises a motor, an output shaft of the motor is fixed with a rotating shaft, the rotating shaft is fixed with a rotating frame, a first cylinder is fixed on the rotating frame, and a piston rod of the first cylinder is fixed with the lower end of the bottom plate.

5. The sprocket process feeding apparatus as set forth in claim 4, wherein: the rotary frame is fixedly provided with a second air cylinder, a piston rod of the second air cylinder is fixed with a fixing frame, the fixing frame is fixedly provided with a first push rod and a second push rod, and the bottom plate is provided with a through hole for the first push rod and the second push rod to pass through.

6. A sprocket process feeding apparatus as set forth in claim 1 wherein: the material receiving seat comprises a supporting plate and three side plates, wherein the three side plates are fixed at the upper end of the supporting plate, a second groove is formed in the upper end of the supporting plate, a third spring is fixed in the second groove, the upper end of the third spring is fixed with a clamping block, and the vertical section of the clamping block is in a right-angle triangle shape.

7. A sprocket process feeding apparatus as set forth in claim 1 wherein: the device also comprises a moving mechanism, wherein the moving mechanism is used for moving the receiving seat in the feeding channel to the conveying mechanism.

8. The sprocket process feeding apparatus as set forth in claim 7, wherein: the moving mechanism comprises a moving plate, two opposite clamping plates are fixed on the moving plate and can move, electromagnets are respectively fixed at opposite ends of the clamping plates, and an iron plate is fixed on the outer wall of the material receiving seat.

9. The sprocket process feeding apparatus as set forth in claim 7, wherein: the moving mechanism further comprises a mounting frame, a sliding hole is formed in the mounting frame, a screw rod and a sliding block are arranged in the sliding hole, one end of the screw rod is connected with the inner wall of the sliding hole through a bearing, the other end of the screw rod is fixed with an output shaft of the motor, the screw rod penetrates through the sliding block and is connected with the sliding block through threads, a third air cylinder is fixed on the sliding block, and a piston rod of the third air cylinder is fixed with the moving plate.

10. A sprocket process feeding apparatus as set forth in claim 9 wherein: the mounting frame is fixed on the rotatable rotating table.