CN213672803U - Automatic attack brill equipment - Google Patents

Abstract

The utility model discloses an automatic tapping and drilling device, which comprises a frame, wherein a guiding device, a punching device, a chamfering device, a tapping device and a material pushing mechanism are arranged on the frame; the punching device, the chamfering device and the tapping device are distributed at equal intervals along the guide device; the material pushing mechanism comprises a feeding knife, a knife holder, a first linear driving device and a second linear driving device; the first linear driving device is used for driving the tool apron to be close to or far away from the guide device; the second linear driving device is used for driving the feeding knife to move in the extending direction of the guide device, at least three feeding grooves are formed in the feeding knife, the openings of the feeding grooves face the guide device, and the distance between every two adjacent feeding grooves is the distance a. The scheme uses automatic feeding and automatically executes each process on the workpieces, reduces labor consumption, simultaneously performs different processes on a plurality of workpieces, and is favorable for improving the overall production efficiency of a factory. The utility model is used for electron device production facility technical field.

Description

Automatic attack brill equipment

Technical Field

The utility model relates to an electronic device production facility technical field, especially an automatic attack brill equipment.

Background

With the development of electronic technology, power tubes in various electronic devices are widely applied, and almost all electronic device switching power supply circuits are used. Therefore, the demand of the radiator correspondingly applied to the power tube is gradually increased, and the capacity of the medium-power tube radiator produced by adopting the traditional process is far from meeting the actual demand. The radiator needs to be subjected to multiple steps of stamping, chamfering, tapping and the like.

At present, two machining modes are mainly used for workpieces needing stamping, chamfering and tapping, one mode is single-process single-product manual machining, and the other mode is single-process single-product automatic machining. The two processing modes of the existing radiator have low efficiency and large manpower, and are not beneficial to the rapid production of workpieces.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is: an automatic tapping and drilling device is provided to solve one or more technical problems in the prior art, and at least provide a beneficial choice or creation condition.

The utility model provides a solution of its technical problem is:

an automatic tapping and drilling device comprises a rack, wherein a guide device, a punching device, a chamfering device, a tapping device and a material pushing mechanism are arranged on the rack; the guide means extends in a straight line; the punching device, the chamfering device and the tapping device are distributed at equal intervals along the extending direction of the guide device by taking the distance a as an interval; the material pushing mechanism comprises a feeding knife, a knife holder, a first linear driving device and a second linear driving device; the first linear driving device is arranged on the rack, the output end of the first linear driving device is connected with the tool apron, and the first linear driving device is used for driving the tool apron to be close to or far away from the guiding device; the second linear driving device is installed on the tool apron, the output end of the second linear driving device is connected with the feeding knife, the second linear driving device is used for driving the feeding knife to move in the extending direction of the guiding device, at least three feeding grooves are formed in the feeding knife, the openings of the feeding grooves face the guiding device, and the distance between every two adjacent feeding grooves is the distance a.

According to the scheme, when the automatic tapping and drilling equipment is used, a workpiece is firstly placed on the guide device, then the first linear driving device drives the feeding cutter to approach the guide device, the workpiece is clamped into the feeding groove, and then the second linear driving device drives the feeding cutter to move forward by a distance a; when the feeding knife moves forward by a distance a, the first linear driving device drives the feeding knife to move away from the guiding device, and then the second linear driving device drives the feeding knife to retreat to wait for executing next feeding; and the punching device works to punch a hole on the workpiece, after the punching process is finished, the pushing device executes the next operation, the first linear driving device drives the feeding knife to be close to the guide device, the second linear driving device drives the feeding knife to move forwards, the first linear driving device drives the feeding knife to be far away from the guide device, the second linear driving device drives the feeding knife to move backwards, and the chamfering device, the punching device and the tapping device work to execute different works on the workpiece on different stations. The scheme uses automatic feeding and automatically executes each process on the workpieces, reduces labor consumption, simultaneously performs different processes on a plurality of workpieces, and is favorable for improving the overall production efficiency of a factory.

As a further improvement of the technical scheme, the opening of the feeding groove is provided with a chamfer.

Through the scheme, if the notch of the feeding groove is a sharp corner, the sharp corner can possibly scratch the surface of the workpiece when the workpiece enters the feeding groove, and the chamfer enables the workpiece to be aligned more easily when the workpiece enters the feeding groove, so that the smooth production is ensured; and the chamfer reduces the surface abrasion when the workpiece enters the feeding groove, and is beneficial to ensuring the quality of the workpiece.

As a further improvement of the technical scheme, the feeding cutter further comprises a yielding groove, the yielding groove corresponds to the feeding grooves one by one, and the yielding groove and the feeding grooves are formed with elastic clamping rods.

Through the scheme, the elastic clamping rod enables the workpiece with the length slightly larger than the width of the abdicating groove to enter the feeding groove and be pushed forwards by the feeding groove.

As a further improvement of the technical scheme, the chamfering device is arranged below the guide device and comprises a chamfering drill bit, a chamfering rotary driver and a chamfering linear driver, the chamfering linear driver drives the chamfering rotary driver to move up and down, the chamfering rotary driver drives the chamfering drill bit to rotate, and the guide device is provided with a through hole for the chamfering drill bit to pass through.

Through the scheme, the chamfering device is used for chamfering the workpiece.

As a further improvement of the above technical solution, the punching device comprises a punching driver, a punching upper die and a punching lower die, the punching driver is a linear driver, and an output end of the punching driver is connected with the punching upper die; the punching lower die is arranged on the frame.

Through above-mentioned scheme, punching device punches a hole to the work piece.

As a further improvement of the above technical solution, the tapping device includes a tapping linear driver, a tapping rotary driver, and a tapping drill, the tapping linear driver drives the tapping rotary driver to move up and down, and the tapping rotary driver drives the tapping drill to rotate.

Through the scheme, the tapping device taps the workpiece.

As a further improvement of the above technical scheme, the guiding device comprises a feeding guiding section, a discharging guiding section and an upper limiting plate, the feeding guiding section and the discharging guiding section are sequentially arranged along the extending direction of the guiding device, the upper limiting plate comprises a feeding end and a discharging end, the feeding end is arranged above the feeding guiding section, the discharging end is arranged above the discharging guiding section, and the feeding end and the discharging end are bent upwards.

Through above-mentioned scheme, circular-arc lamellar body can lead when the spacing board leads to the feeding direction section on getting into to the work piece, makes the work piece can with get into smoothly the region between spacing board and the feeding direction section.

As a further improvement of the technical scheme, the feeding guide section and the discharging guide section are respectively provided with a limiting rail in an upward protruding mode, and the extending direction of the limiting rail is the same as that of the guide device.

Through above-mentioned scheme, the spacing rail sets up according to the concrete shape of work piece, and the spacing rail is injectd the position of work piece, breaks away from the region between spacing board and the feeding guide section on avoiding the work piece motion.

As a further improvement of the technical scheme, a guide rail is arranged on the tool apron, the extending direction of the guide rail is parallel to the extending direction of the guide device, the guide rail is connected with a sliding table in a sliding manner, and the feeding knife is connected with the sliding table.

Through the scheme, the guide rail and the sliding table are used for reducing friction when the second linear driving device drives the material pushing device to move.

As a further improvement of the technical scheme, the vibration plate feeding device further comprises a feeding device, wherein the feeding device comprises a feeding linear driver, a feeding seat and a vibration plate, the feeding seat is arranged at the outlet end of the vibration plate, and the feeding linear driver drives the feeding seat to move up and down.

The utility model has the advantages that: the scheme uses automatic feeding and automatically executes each process on the workpieces, reduces labor consumption, simultaneously performs different processes on a plurality of workpieces, and is favorable for improving the overall production efficiency of a factory.

The utility model is used for electron device production facility technical field.

Drawings

In order to more clearly illustrate the technical solution in the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly described below. It is clear that the described figures represent only some embodiments of the invention, not all embodiments, and that a person skilled in the art can also derive other designs and figures from these figures without inventive effort.

Fig. 1 is a schematic overall structure diagram of an embodiment of the present invention;

fig. 2 is a schematic overall structure diagram of a main execution component of the embodiment of the present invention;

fig. 3 is a schematic view of the overall structure of the tapping device according to the embodiment of the present invention;

fig. 4 is a schematic view of the overall structure of the chamfering device according to the embodiment of the present invention;

fig. 5 is a schematic view of the overall structure of the feeding device according to the embodiment of the present invention;

fig. 6 is a schematic overall structure diagram of a guide device according to an embodiment of the present invention;

fig. 7 is a schematic view of the overall structure of the pushing mechanism of the embodiment of the present invention

Fig. 8 is a schematic view of the overall structure of another angle of the pushing mechanism according to the embodiment of the present invention.

In the figure, 100, a rack; 200. a guide device; 210. a feed guide section; 220. a discharge guide section; 230. an upper limiting plate; 231. a feeding end; 232. a discharge end; 240. a limit rail; 300. a punching device; 310. a punch driver; 320. punching an upper die; 330. punching a lower die; 400. a chamfering device; 410. chamfering the drill bit; 420. a chamfer angle rotary driver; 430. chamfering the linear driver; 500. a tapping device; 510. a linear driver for tapping; 520. a tapping rotary drive; 530. tapping drill bits; 600. a material pushing mechanism; 610. a feeding knife; 611. a sliding table; 612. a feed chute; 613. a yielding groove; 614. an elastic clamping rod; 620. a tool apron; 621. a guide rail; 630. a first linear driving device; 640. a second linear drive; 700. a feeding device; 710. a feeding linear driver; 720. a feeding seat; 800. and (5) vibrating the disc.

Detailed Description

The conception, the specific structure, and the technical effects produced by the present invention will be clearly and completely described below in conjunction with the embodiments and the accompanying drawings to fully understand the objects, the features, and the effects of the present invention. Obviously, the described embodiments are only a part of the embodiments of the present invention, and not all embodiments, and other embodiments obtained by those skilled in the art without inventive labor based on the embodiments of the present invention all belong to the protection scope of the present invention. In addition, all the coupling/connection relationships mentioned herein do not mean that the components are directly connected, but mean that a better coupling structure can be formed by adding or reducing coupling accessories according to specific implementation conditions. All technical characteristics in the invention can be interactively combined on the premise of not conflicting with each other.

Referring to fig. 1 to 8, an automatic tapping and drilling device includes a frame 100, and a guide device 200, a punching device 300, a chamfering device 400, a tapping device 500, a material pushing mechanism 600, and a material loading device 700 are disposed on the frame 100. The rack 100 is further provided with a human-computer interaction platform for controlling the automatic tapping and drilling equipment.

One end of the frame 100 is configured as a feed side and the end of the frame 100 distal from the feed end 231 is configured as a discharge side. The feeding device 700 is arranged on the feeding side, the feeding device 700 comprises a feeding linear driver 710, a feeding seat 720 and a vibration disc 800, the vibration disc 800 can effectively prevent fool and is high in efficiency, the feeding seat 720 is arranged at the outlet end of the vibration disc 800, the feeding linear driver 710 drives the feeding seat 720 to move up and down, and the feeding linear driver 710 is a linear cylinder.

The guide 200 extends along the discharge side-the feed side. The guide device 200 includes a feed guide section 210, a discharge guide section 220, and an upper limiting plate 230. The feeding guide section 210 and the discharging guide section 220 respectively protrude upwards to form a limit rail 240, and the extending direction of the limit rail 240 is the same as that of the guide device 200. The feeding guide section 210 and the discharging guide section 220 are sequentially disposed along the discharging side-the feeding side.

The upper limiting plate 230 comprises a feeding end 231 and a discharging end 232, the feeding end 231 is arranged above the feeding guide section 210, the discharging end 232 is arranged above the discharging guide section 220, the feeding end 231 and the discharging end 232 are bent upwards, and a flat plate-shaped member is arranged between the feeding end 231 and the discharging end 232 of the upper limiting plate 230.

The punching device 300, the chamfering device 400 and the tapping device 500 are arranged in sequence along the feeding side and the discharging side, and the punching device 300, the chamfering device 400 and the tapping device 500 are distributed at equal intervals with a distance a.

The punching device 300 comprises a punching driver 310, a punching upper die 320 and a punching lower die 330, wherein the punching driver 310 is a cylinder straight line, and the output end of the punching driver is connected with the punching upper die 320; the lower punching die 330 is installed on the frame 100, and the lower punching die 330 is disposed between the feeding guide section 210 and the discharging guide section 220.

Chamfering device 400 is arranged below guiding device 200, chamfering device 400 comprises chamfering drill bit 410, chamfering rotary driver 420 and chamfering linear driver 430, chamfering linear driver 430 is a linear cylinder, chamfering linear driver 430 drives chamfering rotary driver 420 to move up and down, chamfering rotary driver 420 drives chamfering drill bit 410 to rotate, and guiding device 200 is provided with a through hole for chamfering drill bit 410 to pass through.

The tapping device 500 includes a linear tapping driver 510, a rotary tapping driver 520, and a tapping drill 530, wherein the linear tapping driver 510 is a linear cylinder, the linear tapping driver 510 drives the rotary tapping driver 520 to move up and down, and the rotary tapping driver 520 drives the rotary tapping drill 530 to rotate.

The material pushing mechanism 600 includes a feeding blade 610, a blade holder 620, a first linear driving device 630 and a second linear driving device 640, and both the first linear driving device 630 and the second linear driving device 640 are provided as cylinders. A first linear driving device 630 is installed on the frame 100, an output end of the first linear driving device 630 is connected with the tool apron 620, and the first linear driving device 630 is used for driving the tool apron 620 to approach or depart from the guiding device 200; the second linear driving device 640 is installed on the tool post 620, and the tool post 620 is further provided with a stopper for limiting the maximum displacement distance of the second linear driving device 640. The tool apron 620 is provided with a guide rail 621, the extending direction of the guide rail 621 is parallel to the extending direction of the guide device 200, the guide rail 621 is connected with a sliding table 611 in a sliding manner, and the feeding knife 610 is connected with the sliding table 611. The output end of the second linear driving device 640 is connected to the feeding blade 610, and the second linear driving device 640 is used for driving the feeding blade 610 to move in the extending direction of the guiding device 200.

The feeding knife 610 is provided with three feeding grooves 612, the openings of the feeding grooves 612 face the guiding device 200, and the openings of the feeding grooves 612 are provided with chamfers. The distance between two adjacent feed chutes 612 is a distance a. The feeding blade 610 is provided with an abdicating groove 613, the abdicating groove 613 corresponds to the feeding groove 612 one by one, and the abdicating groove 613 and the feeding groove 612 form an elastic clamping rod 614.

While the preferred embodiments of the present invention have been described in detail, it will be understood by those skilled in the art that the invention is not limited to the details of the embodiments shown, but is capable of various modifications and substitutions without departing from the spirit of the invention.

Claims (10)

1. The utility model provides an automatic attack brill equipment which characterized in that: the punching machine comprises a rack (100), wherein a guide device (200), a punching device (300), a chamfering device (400), a tapping device (500) and a material pushing mechanism (600) are arranged on the rack (100); the guide (200) extends in a straight line; the punching device (300), the chamfering device (400) and the tapping device (500) are distributed at equal intervals by taking the distance a as an interval along the extending direction of the guide device (200); the material pushing mechanism (600) comprises a feeding knife (610), a knife holder (620), a first linear driving device (630) and a second linear driving device (640); the first linear driving device (630) is mounted on the frame (100), the output end of the first linear driving device (630) is connected with the tool apron (620), and the first linear driving device (630) is used for driving the tool apron (620) to approach or separate from the guide device (200); the second linear driving device (640) is installed on the tool apron (620), the output end of the second linear driving device (640) is connected with the feeding knife (610), the second linear driving device (640) is used for driving the feeding knife (610) to move in the extending direction of the guide device (200), at least three feeding grooves (612) are formed in the feeding knife (610), the openings of the feeding grooves (612) face the guide device (200), and the distance between every two adjacent feeding grooves (612) is a distance a.

2. An automatic tapping and drilling device according to claim 1, wherein: the opening of the feeding groove (612) is provided with a chamfer.

3. An automatic tapping and drilling device according to claim 1, wherein: the feeding knife (610) further comprises an abdicating groove (613), the abdicating groove (613) corresponds to the feeding groove (612) one by one, and the abdicating groove (613) and the feeding groove (612) are provided with elastic clamping rods (614).

4. An automatic tapping and drilling device according to claim 1, wherein: the chamfering device (400) is arranged below the guiding device (200), the chamfering device (400) comprises a chamfering drill bit (410), a chamfering rotary driver (420) and a chamfering linear driver (430), the chamfering linear driver (430) drives the chamfering rotary driver (420) to move up and down, the chamfering rotary driver (420) drives the chamfering drill bit (410) to rotate, and the guiding device (200) is provided with a through hole for the chamfering drill bit (410) to pass through.

5. An automatic tapping and drilling device according to claim 1, wherein: the punching device (300) comprises a punching driver (310), an upper punching die (320) and a lower punching die (330), wherein the punching driver (310) is a linear driver, and the output end of the punching driver is connected with the upper punching die (320); the punching lower die (330) is arranged on the frame (100).

6. An automatic tapping and drilling device according to claim 1, wherein: the tapping device (500) comprises a tapping linear driver (510), a tapping rotary driver (520) and a tapping drill bit (530), wherein the tapping linear driver (510) drives the tapping rotary driver (520) to move up and down, and the tapping rotary driver (520) drives the tapping drill bit (530) to rotate.

7. An automatic tapping and drilling device according to claim 1, wherein: guider (200) include feeding direction section (210), ejection of compact direction section (220) and go up spacing board (230), and feeding direction section (210) and ejection of compact direction section (220) set gradually along guider (200) extending direction, go up spacing board (230) and include feed end (231) and discharge end (232), feed end (231) set up in the top of feeding direction section (210), discharge end (232) set up in the top of ejection of compact direction section (220), feed end (231) and discharge end (232) upwards buckle.

8. An automatic tapping and drilling device according to claim 7, wherein: the feeding guide section (210) and the discharging guide section (220) are respectively provided with a limiting rail (240) in an upward protruding mode, and the extending direction of the limiting rail (240) is the same as that of the guide device (200).

9. An automatic tapping and drilling device according to claim 1, wherein: be provided with guide rail (621) on blade holder (620), the extending direction of guide rail (621) is on a parallel with the extending direction of guider (200), guide rail (621) slide and are connected with slip table (611), pay-off sword (610) is connected with slip table (611).

10. An automatic tapping and drilling device according to claim 1, wherein: the feeding device (700) comprises a feeding linear driver (710), a feeding seat (720) and a vibration disc (800), wherein the feeding seat (720) is arranged at the outlet end of the vibration disc (800), and the feeding linear driver (710) drives the feeding seat (720) to move up and down.

Images