A feeding device for a drilling system

By designing a feeding device for drilling systems, the problem of continuous and stable feeding of small connecting pressure plate parts was solved, realizing automated feeding and reducing labor intensity and safety risks.

CN224359815UActive Publication Date: 2026-06-16成都西菱动力科技股份有限公司

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
成都西菱动力科技股份有限公司
Filing Date
2025-07-04
Publication Date
2026-06-16

AI Technical Summary

Technical Problem

Existing drilling systems cannot achieve continuous and stable feeding of small connecting pressure plate parts, resulting in frequent operations, high labor intensity, and a high risk of personnel injury.

Method used

A feeding device for a drilling system was designed, including a parts conveying track, a feeding chute, a feeding device, and a loading device. Through the cooperation of the parts conveying track, the feeding chute, the feeding device, and the loading device, continuous and stable feeding of small connecting pressure plate parts can be achieved.

Benefits of technology

It enables continuous and stable feeding of small connecting pressure plate parts, providing a fast and stable material source for the drilling system and automating the feeding of small connecting pressure plate parts.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses a kind of feeding devices for drilling system, it is related to the drilling technology field of small connecting pressboard class parts, including part conveying track, part conveying track is set longitudinally;Feeding chute, feeding chute is set transversely, and one end of feeding chute is equipped with feeding station, and the other end of feeding chute is equipped with feeding station, and the outlet of part conveying track is communicated with feeding station, and feeding station is used for with the butt joint communication of the feeding port of drilling system;Feeding device, the feeding device includes feeding cylinder and feeding push rod, and feeding push rod is connected with the piston rod of feeding cylinder, and feeding push rod is transversely aligned with feeding station;Feeding device, the feeding device includes including feeding cylinder and feeding cylinder, and feeding cylinder is connected with the piston rod of feeding cylinder, and feeding push rod is longitudinally aligned with feeding station.The utility model can realize the continuous stable feeding of small connecting pressboard class parts, provide quick stable material source for drilling system, realize feeding automation.
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Description

Technical Field

[0001] This utility model relates to the field of drilling technology for small connecting pressure plate parts, and in particular to a feeding device for a drilling system. Background Technology

[0002] Currently, the production of aerospace structural components, automotive engine turbochargers, and other products requires a large number of small connecting pressure plate parts. These parts are characterized by a length of 50-80 mm and a thickness of 4-5 mm, with a connecting hole at each end and chamfered openings. The hole diameter is approximately 3-8 mm, and the chamfering ensures that the connecting screws are flush with the connecting plate. Currently, these parts are manufactured manually by drilling double-ended through holes on a special tooling, followed by manual chamfering. This method is time-consuming, labor-intensive, and involves frequent operations, easily leading to fatigue and injury. The feeding devices of traditional drilling systems are not suitable for the drilling system for small connecting pressure plate parts developed by the inventor, making continuous and stable feeding of these parts impossible. Utility Model Content

[0003] This invention proposes a feeding device for drilling systems to solve the problem that existing devices cannot achieve continuous and stable feeding of small connecting pressure plate parts.

[0004] This utility model discloses a feeding device for a drilling system, comprising:

[0005] Parts conveying track, the parts conveying track is set longitudinally;

[0006] The feeding chute is arranged horizontally. One end of the feeding chute is equipped with a loading station, and the other end of the feeding chute is equipped with a feeding station. The outlet of the parts conveying track is connected to the feeding station, and the loading station is used to connect with the loading port of the drilling system.

[0007] A feeding device, comprising a feeding cylinder and a feeding push rod, wherein the feeding push rod is connected to the piston rod of the feeding cylinder and is laterally aligned with the feeding station;

[0008] The feeding device includes a feeding cylinder and a feeding cylinder. The piston rods of the feeding cylinder and the feeding cylinder are connected, and the feeding push rod is longitudinally aligned with the feeding station.

[0009] Furthermore, the feeding chute includes a chute body and a feeding block disposed on the chute body. The feeding push rod is aligned with and connected to the feeding block. The feeding block has a longitudinally arranged part slot. In the initial state, the feeding block is disposed at the feeding station. At this time, the part slot on the feeding block is aligned with the part conveying track. In the feeding state, the feeding block is pushed to the loading station by the feeding push rod. At this time, the part slot on the feeding block is aligned with the loading push rod and the loading port.

[0010] Furthermore, the upper end of the part slot on the feeding block is located on the top surface of the feeding block, and limiting plates are provided on both sides of the upper end of the slot.

[0011] Furthermore, the parts conveying track is a vibrating feeding track, which includes a track body and a vibrating feeder connected to the track body.

[0012] Furthermore, the feeding port is a longitudinally arranged feeding chute.

[0013] Furthermore, it also includes a rotatable turntable, wherein a number of equally spaced part mounting parts are provided around the rotatable turntable, and each part mounting part is provided with a feeding groove along the radial direction of the turntable.

[0014] Furthermore, a turntable driving device is provided below the turntable. The turntable driving device includes a reducer and a transmission rod. The transmission rod is vertically arranged. The shaft of the reducer is connected to one end of the transmission rod, and the other end of the transmission rod is connected to the bottom of the turntable. When the shaft of the reducer rotates, it drives the transmission rod to rotate, and the transmission rod drives the turntable to rotate.

[0015] Furthermore, it also includes a platform and a support frame, the support frame being supported at the bottom of the platform, the platform having mounting holes for the turntable to be installed, the turntable drive device being located below the platform, and the feeding chute, feeding device, and loading device being located on the platform.

[0016] Furthermore, a limiting structure is provided on one side port of the feeding chute inside the turntable.

[0017] Furthermore, the limiting structure is a pin located in the middle of the port.

[0018] The beneficial effects of this utility model are as follows:

[0019] The present invention proposes a feeding device for a drilling system, which, through the cooperation of a parts conveying track, a feeding chute, a feeding device, and a feeding device, enables continuous and stable feeding of small connecting pressure plate parts, provides a fast and stable material source for the drilling system, and automates the feeding of small connecting pressure plate parts. Attached Figure Description

[0020] Figure 1 This is a structural diagram of a fully automatic rapid drilling system according to an embodiment of this application;

[0021] Figure 2 This is a schematic diagram of the pressing unit in an embodiment of this application;

[0022] Figure 3 This is a front view of the component mounting part in the embodiments of this application;

[0023] Figure 4This is a top view of the component mounting part in the embodiments of this application;

[0024] Figure 5 This is a top view of a feeding device for a drilling system according to an embodiment of this application;

[0025] Figure 6 This is a side view of a feeding device for a drilling system according to an embodiment of this application;

[0026] Figure 7 This is a schematic diagram of the unloading unit in an embodiment of this application;

[0027] Figure 8 This is a top view of the unloading unit in an embodiment of this application;

[0028] Figure 9 This is a side view of the drilling apparatus in an embodiment of this application.

[0029] In the diagram: 1-System frame; 2-Unloading robot; 3-Turntable; 4-Part mounting component; 5-Clamping device; 6-Turntable drive device; 7-Reducer; 8-Transmission rod; 9-Part; 10-Part mounting base; 11-Pin; 12-Part slot; 13-Drilling device; 14-Push rod; 15-Hydraulic cylinder; 16-Feeding hydraulic cylinder; 17-Feeding push rod; 18-Feeding block; 19-Part conveying track; 20-Feeding chute ; 21-Feeding cylinder piston; 22-Feeding cylinder; 23-Feeding station; 24-Loading station; 25-Unloading piston rod; 26-Unloading cylinder; 27-Unloading fork; 28-Avoiding pin groove; 29-Equipment column; 30-Drill head; 31-Crossbeam; 32-Drilling system; 33-Vertical movement mechanism; 34-Vertical movement connecting plate; 35-Vertical movement support plate; 36-Support plate crossbeam hinge; 37-Vertical movement cylinder. Detailed Implementation

[0030] To make the objectives, technical solutions, and advantages of the embodiments of this utility model clearer, the technical solutions of the embodiments of this utility model will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some, not all, of the embodiments of this utility model. The components of the embodiments of this utility model described and shown in the accompanying drawings can generally be arranged and designed in various different configurations.

[0031] Therefore, the following detailed description of the embodiments of the present invention provided in the accompanying drawings is not intended to limit the scope of the claimed invention, but merely to illustrate selected embodiments of the invention. All other embodiments obtained by those skilled in the art based on the embodiments of the present invention without inventive effort are within the scope of protection of the present invention.

[0032] It should be noted that similar labels and letters in the following figures indicate similar items. Therefore, once an item is defined in one figure, it does not need to be further defined and explained in subsequent figures.

[0033] In the description of this utility model, it should be understood that the terms "upper", "lower", "inner", "outer", "left", "right", etc., indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings, or the orientation or positional relationship that the utility model product is usually placed in during use, or the orientation or positional relationship that is commonly understood by those skilled in the art. They are only used to facilitate the description of this utility model and to simplify the description, and are not intended to indicate or imply that the device or component referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on this utility model.

[0034] In the description of this utility model, it should also be noted that, unless otherwise explicitly specified and limited, terms such as "set" and "connection" should be interpreted broadly. For example, "connection" can be a fixed connection, a detachable connection, or an integral connection; it can be a mechanical connection or an electrical connection; it can be a direct connection or an indirect connection through an intermediate medium; it can be a connection within two components. Those skilled in the art can understand the specific meaning of the above terms in this utility model according to the specific circumstances.

[0035] The specific embodiments of this utility model will now be described in detail with reference to the accompanying drawings.

[0036] The specific structure of the feeding device for a drilling system according to this utility model is as follows:

[0037] like Figure 5 and Figure 6 As shown, a feeding device for a drilling system includes a horizontally arranged feeding chute 20 and a part conveying track 19 connected to it in a T-shape. A feeding cylinder 22 is installed on the right side of the feeding chute 20. The feeding chute 20 includes a chute body and a feeding block 18 disposed on the chute body. A feeding push rod 21 is aligned with and connected to the feeding block 18. The feeding block 18 is provided with a part slot in the longitudinal direction. The feeding push rod 21 can push it to the leftmost F feeding position and align it with the feeding port and the part conveying track 19.

[0038] The system also includes a rotatable turntable 3, which has several equally spaced part mounting pieces 4 around its circumference. Each part mounting piece 4 has a feeding groove along the radial direction of the turntable 3. A limiting structure is provided on one side of the feeding groove near the turntable 3. The limiting structure is a pin 11 located in the middle of the port. This device is installed at the front end of the system frame 1, aligning the feeding block 18 pushed to the leftmost feeding station F with the feeding groove on the turntable 3 in the middle of the system frame 1. The feeding push rod 17 of the feeding cylinder 16 is adjusted to be in a straight line with the feeding block 18 and the feeding groove, and the feeding push rod 17 is positioned to push the part 9. Then, the part conveying track 19 is connected to the vibratory feeding device and the system is fixed in place. The turntable drive device 6 includes a reducer 7 and a transmission rod 8.

[0039] It also includes a system bracket 1, which includes a platform and a support frame. The support frame is supported at the bottom of the platform. The platform has mounting holes for the turntable. The turntable drive device 6 is located below the platform. The feeding chute 20, the feeding device, and the loading device are located on the platform.

[0040] The upper slot of the part slot on the feeding block 18 is located on the top surface of the feeding block 18, and a limiting plate is provided on both sides of the upper slot.

[0041] The parts conveying track 19 is a vibrating feeding track, which includes a track body and a vibrating feeder connected to the track body.

[0042] In the initial state, the feeding block 18 is set on the feeding station. At this time, the part slot on the feeding block 18 is aligned with the part conveying track. In the feeding state, the feeding block 18 is pushed to the loading station by the feeding push rod 21. At this time, the part slot on the feeding block 18 is aligned with the loading push rod 17 and the loading chute.

[0043] The following is a specific embodiment of the feeding device for a drilling system applied to a fully automatic high-speed drilling system, which further illustrates this utility model.

[0044] This utility model applies to a fully automatic rapid drilling system, which includes: a pressing unit, a feeding device for the drilling system, a unloading unit, and a drilling device. It may also include a computer control and auxiliary system. This utility model can realize fully automatic rapid drilling of small connecting pressure plate parts.

[0045] like Figure 1 , Figure 2 , Figure 3 and Figure 4As shown, the pressing unit includes a system frame 1 and a pressing device 5, a unloading robot 2, a turntable drive device 6, and a turntable 3 mounted on the system frame 1. The turntable drive device 6 includes a reducer 7 and a transmission rod 8. Six sets of part mounting components 4 are installed on the turntable 3 of this pressing device, distributed at 60-degree intervals. The part mounting component 4 for the A loading station is located at the front left of the system frame 1, and the mounting component for the unloading station is located at position D, which is 60 degrees to the left of the front left. The remaining B1, B2, C1, and C2 are four drilling stations for drilling the front end hole, drilling the rear end hole, countersinking the front end hole, and countersinking the rear end hole, respectively. Four sets of pressing devices 5 are installed on the system frame 1 at positions corresponding to B1, B2, C1, and C2 for rapid pressing of parts. The unloading robot 2 is installed at position D, which constitutes the rapid pressing and unloading of part 9. The part mounting component 4 includes a part mounting base 10 and a part slot 12 set on the part mounting base 10. The clamping device 5 includes a hydraulic cylinder 15 and a push rod 14. The output shaft of the hydraulic cylinder 15 is connected to one end of the push rod 14, and the other end of the push rod 14 is aligned with the radially outward end port of the part slot 12 corresponding to the drilling station.

[0046] like Figure 7 and Figure 8 As shown, the unloading unit includes an unloading cylinder 26, an unloading piston rod 25, and an unloading fork 27 mounted on the end of the unloading piston rod 25. The unloading unit is installed at the front left of the system frame 1 and consists of the unloading cylinder 26, the unloading piston rod 25, and the unloading fork 27 connected to the end of the unloading piston rod 25. The unloading unit is mounted on the system frame 1, with the unloading piston rod 25 extending above the part mounting component 4 at the unloading point D on the turntable 3. The unloading fork 27, mounted on the end of the unloading piston rod 25, is positioned slightly behind the pin 11 behind the part slot 12 on the part mounting component 4, so that the unloading fork 27 can push the machined part 9 out of the part slot 12, achieving automatic unloading. A pin-avoiding groove 28 is machined on the unloading fork 27 to avoid interference with the pin 11.

[0047] like Figure 9 The drilling apparatus shown consists of a device column 29 mounted on a system frame 1, a vertical moving mechanism 33 mounted on the top of the device column, a crossbeam 31, and a drill bit system 32 mounted on the crossbeam 31. The device column 29 supports the vertical moving mechanism, which comprises a vertical moving cylinder 37 mounted on the top of the device column 29, a vertical moving support plate 35 connected to the upper end of the piston of the vertical moving cylinder 37, a vertical moving connecting plate 34, and the drill bit system 32 on the crossbeam 31. The drill bit system 32 includes a bottom drill bit 30 located at one end of the crossbeam 31.

[0048] Computer control and auxiliary systems are used to control the motors and reducers of each hydraulic cylinder.

[0049] The system frame 1 is rectangular, and a turntable drive device 6 is installed inside. The turntable drive device 6 includes a reducer 7, a transmission rod 8, and a connected turntable 3. Six sets of part mounting components 4 are evenly distributed at 60 degrees on the part transposition turntable. The part mounting components 4 are machined with part slots 12 and pins 11 for limiting and clamping parts, forming a part mounting device. Four sets of clamping devices 5 are installed on the top of the system frame 1 corresponding to the front and rear drilling and counterboring positions of parts B1, B2, C1, and C2 on the turntable 3. The clamping devices 5 on the system frame 1 and the part mounting components 4 on the turntable 3 work together to quickly clamp the parts. An unloading robot 2 is installed on the front left of the system frame 1, on a straight line corresponding to the unloading position D on the turntable 3, for rapid automatic unloading. A feeding unit is connected to the system frame 1. The feeding unit consists of a T-shaped structure formed by a feeding chute 20 and a parts conveying track 19. A feeding cylinder 22 is installed at the right end of the feeding chute 20, and the feeding push rod 21 is adjusted. The feeding station 23 is set at position E in the middle of the feeding chute 20, which is connected to the parts conveying track 19, to receive the parts 9 to be processed, which are vibrated and conveyed by the vibrating feeder through the parts conveying track 19. A feeding station 24 is set at position A on the turntable 3 at the leftmost end of the feeding chute 20, which is aligned with the parts mounting part 4 on the turntable 3. A feeding cylinder 16 is installed on the straight line corresponding to the feeding block 18 at the parts mounting part 4 and the feeding station 24, to push the parts 9 to be processed in the feeding block 18 at the feeding station F into the parts mounting part 4 on the turntable 3. A material unloading robot 2 is installed on the left front of the system frame 1, in a straight line with the unloading station at position D on the turntable 3. The unloading piston rod 25 of the robot passes over the part mounting part 4 at point D, so that the unloading fork 27 installed at the front end of the unloading piston rod 25 is located slightly behind the pin 11 behind the part slot 12, which facilitates unloading. When the unloading piston rod 25 moves, the opening of the unloading fork 27, i.e., the avoidance groove 28, can pass through the pin 11. The drilling device 13 is supported on the system frame 1 by the device column 29. This system has four sets of drilling devices 13 installed at the front and rear drilling and counterboring positions for parts B1, B2, C1, and C2. The drilling device 13 consists of a vertical moving mechanism 33, a crossbeam 31, and a drilling tool system 32. The vertical movement mechanism 33 is installed at the top of the device column 29. The vertical movement cylinder 37 is connected to the vertical movement connecting plate 34 and the support beam hinge 36 via the vertical movement support plate 35. The vertical movement mechanism 33 is used to adjust the stroke of drill bits of different lengths during processing, saving processing time. The drilling system 32 is installed on the beam 31 and processes according to computer instructions. The drilling system 32 includes a bottom drill head 30 located at one end of the beam 31.

[0050] The workflow is as follows:

[0051] Adjust the feeding block 18 in the feeding chute 20 of the feeding unit on the system frame 1 to be fixed to the part mounting part 4 on the turntable 3, which serves as the feeding chute; adjust the unloading fork 27 on the unloading robot 2 on the system frame 1 to the appropriate position of the pin 11 in the part slot 12 on the part mounting part 4 at the unloading station at point D; adjust the push rod 14 of the clamping device 5 on the system frame 1 to the appropriate position. Adjust the vertical movement mechanism 33 according to the condition of the drill bit in the drilling system 32 to position the drill head 30 in a suitable position and set the machining program.

[0052] When the system starts, the part 9 to be processed, delivered from the vibratory feeding station 24, is sent via the part conveying track 19 to the part slot of the feeding block 18 at station E on the feeding chute 20. The feeding cylinder 22 starts and pushes the feeding block 18 from feeding station 23 (E) to the feeding station F at the left end of the feeding chute 20 via the feeding push rod 21. At this time, the feeding cylinder 16 starts and the feeding push rod 17 extends to push the part 9 to be processed in the feeding block 18 at the feeding station F into the part slot 12 of the part mounting part 4 at point A on the turntable 3. Then the feeding cylinder 16 returns to the initial position and the feeding cylinder 22 starts and pulls the feeding block 18 back to the feeding station E of the feeding chute 20 to wait for the next feeding. At the same time, the turntable drive device 6 starts and drives the turntable 3 to rotate 60 degrees counterclockwise, so that the part mounting part 4 at point A, after the part has been fed, rotates to the drilling station at the front hole at point B1 and stops. The system activates the clamping device 5, and the push rod 14 extends from the outside in to clamp the part 9 to be processed between the push rod and the pin 11. After the part is clamped, the drilling device 13 starts to process the front end hole. After the front end hole is processed, the drilling device 13 rises to the predetermined position and stops; the clamping device 5 releases and loosens the part, and then the turntable drive device 6 starts, driving the turntable 3 to rotate counterclockwise 60 degrees again. At the same time, the part loaded at A is sent to the B1 front end hole drilling station, and the part with the drilled front end hole is sent from the B1 station to the B2 rear end hole drilling station. The above steps are repeated, and the processed part is sent to the D unloading station. At this time, the unloading robot 2 starts, the unloading cylinder 26 starts, and the unloading piston rod 25 moves from the inside to the outside. The unloading fork 27 pushes the part 9 out of the part slot 12 at D, completing the unloading. After the complete processing of one part is completed, the processing operation is repeated.

[0053] The above description is only a preferred embodiment of the present utility model. It should be noted that for those skilled in the art, several improvements and modifications can be made without departing from the technical principles of the present utility model, and these improvements and modifications should also be considered within the protection scope of the present utility model.

Claims

1. A feeding device for a drilling system, characterized in that, include: Parts conveying track, the parts conveying track is set longitudinally; The feeding chute is arranged horizontally. One end of the feeding chute is equipped with a loading station, and the other end of the feeding chute is equipped with a feeding station. The outlet of the parts conveying track is connected to the feeding station, and the loading station is used to connect with the loading port of the drilling system. A feeding device, comprising a feeding cylinder and a feeding push rod, wherein the feeding push rod is connected to the piston rod of the feeding cylinder and is laterally aligned with the feeding station; The feeding device includes a feeding cylinder and a feeding cylinder. The piston rods of the feeding cylinder and the feeding cylinder are connected, and the feeding push rod is longitudinally aligned with the feeding station.

2. The feeding device for a drilling system according to claim 1, characterized in that, The feeding chute includes a chute body and a feeding block disposed on the chute body. A feeding push rod is aligned with and connected to the feeding block. The feeding block has a longitudinally arranged part slot. In the initial state, the feeding block is disposed at the feeding station, and the part slot on the feeding block is aligned with the part conveying track. In the feeding state, the feeding block is pushed to the loading station by the feeding push rod, and the part slot on the feeding block is aligned with the loading push rod and the loading port.

3. A feeding device for a drilling system according to claim 2, characterized in that, The upper slot of the part slot on the feeding block is located on the top surface of the feeding block, and limit plates are provided on both sides of the upper slot.

4. A feeding device for a drilling system according to claim 1, characterized in that, The parts conveying track is a vibrating feeding track, which includes a track body and a vibrating feeder connected to the track body.

5. A feeding device for a drilling system according to claim 1, characterized in that, The feeding port is a longitudinally arranged feeding chute.

6. A feeding device for a drilling system according to claim 5, characterized in that, It also includes a rotatable turntable, which has a number of equally spaced part mounting parts around its circumference, and each part mounting part has a feeding groove along the radial direction of the turntable.

7. A feeding device for a drilling system according to claim 6, characterized in that, A turntable drive device is provided below the turntable. The turntable drive device includes a reducer and a transmission rod. The transmission rod is vertically arranged. The shaft of the reducer is connected to one end of the transmission rod, and the other end of the transmission rod is connected to the bottom of the turntable. When the shaft of the reducer rotates, it drives the transmission rod to rotate, and the transmission rod drives the turntable to rotate.

8. A feeding device for a drilling system according to claim 1, characterized in that, It also includes a platform and a support frame. The support frame is supported at the bottom of the platform. The platform has mounting holes for the turntable. The turntable drive device is located below the platform. The feeding chute, feeding device, and loading device are located on the platform.

9. A feeding device for a drilling system according to claim 1, characterized in that, The feeding chute has a limiting structure on one side of the port inside the turntable.

10. A feeding device for a drilling system according to claim 9, characterized in that, The limiting structure is a pin located in the middle of the port.