CN219724641U - Full-automatic drilling device for bowling processing - Google Patents

Abstract

The utility model discloses a full-automatic drilling device for bowling processing, which comprises a frame, a first drill bit, a second drill bit, a third drill bit, a feeding mechanism, a gesture adjusting mechanism arranged on a feeding assembly and a clamping mechanism arranged on the gesture adjusting mechanism; the first drilling machine, the second drilling machine and the third drilling machine are fixedly connected with the frame; the clamping mechanism is used for fixing the bowling ball on the gesture adjusting mechanism, and the gesture adjusting mechanism can drive the bowling ball to rotate; the feeding mechanism can drive the gesture adjusting mechanism to move so as to push the bowling ball fixed on the gesture adjusting mechanism to the right front of one of the drill bits and drive the gesture adjusting mechanism to move along the length direction of the drill bit. The utility model can realize the automation of the whole bowling ball drilling operation, so that the bowling ball drilling operation is simpler, the bowling ball processing efficiency is greatly improved, and the utility model is beneficial to related enterprises to save labor cost.

Description

Full-automatic drilling device for bowling processing

Technical Field

The utility model relates to the technical field of bowling ball processing equipment, in particular to a full-automatic drilling device for bowling ball processing.

Background

In the existing bowling ball drilling machine, one machine can be provided with one drill bit, three finger holes on one ball are drilled, the drill bit needs to be replaced for three times, and drilling holes are marked on the ball manually, so that the machining process is complicated, and the machining efficiency is low. Moreover, the existing bowling ball drilling machine is manually operated, so that the machining error is large and the error probability is high.

Disclosure of Invention

The utility model provides a full-automatic drilling device for bowling processing, which aims to solve the defects of the prior art.

In order to achieve the above purpose, the present utility model provides the following technical solutions:

a full-automatic drilling device for bowling processing comprises a frame, a first drill bit, a second drill bit, a third drill bit, a first drilling machine for driving the first drill bit to rotate, a second drilling machine for driving the second drill bit to rotate and a third drilling machine for driving the third drill bit to rotate; the full-automatic drilling device for bowling processing also comprises a feeding mechanism, a gesture adjusting mechanism arranged on the feeding mechanism and a clamping mechanism arranged on the gesture adjusting mechanism; the first drilling machine, the second drilling machine and the third drilling machine are fixedly connected with the frame; the clamping mechanism is used for fixing the bowling ball on the gesture adjusting mechanism, and the gesture adjusting mechanism can drive the bowling ball to rotate; the feeding mechanism can drive the gesture adjusting mechanism to move so as to push the bowling ball fixed on the gesture adjusting mechanism to the right front of one of the drill bits and drive the gesture adjusting mechanism to move along the length direction of the drill bit.

In some embodiments, the first drill bit and the second drill bit are vertically disposed side by side, and the third drill bit is horizontally disposed and below the first drill bit.

In some embodiments, the feed mechanism includes a lift assembly, an infeed assembly, and a longitudinal feed assembly. The lifting component is connected with the bottom of the gesture adjusting mechanism and drives the gesture adjusting mechanism to move along the vertical direction; the transverse feeding component is connected with the bottom of the lifting component and drives the lifting component to move along the transverse direction; the longitudinal feed assembly is connected to the bottom of the infeed assembly and drives the infeed assembly to move in a longitudinal direction.

In some embodiments, the longitudinal feed assembly includes a housing, a longitudinal rail, and a first drive. The machine base is positioned below the third drill bit; the longitudinal guide rail is arranged at the top of the machine base, and the bottom of the transverse feeding assembly is connected with the longitudinal guide rail; the first driving device is connected with the base and the transverse feeding assembly and drives the transverse feeding assembly to move along the length direction of the longitudinal guide rail.

In some embodiments, the infeed assembly includes a frame, a cross rail, and a second drive. The bottom of the frame is connected with the longitudinal guide rail, and the first driving device can drive the frame to slide along the length direction of the longitudinal guide rail; the transverse guide rail is arranged at the top of the frame, and the bottom of the lifting assembly is connected with the transverse guide rail; the second driving device is connected with the frame and the lifting assembly and drives the lifting assembly to move along the length direction of the transverse guide rail.

In some embodiments, the lift assembly includes a slide plate, a linear travel drive module, a mounting plate, and a slide bar. The bottom of the sliding plate is connected with the transverse guide rail, and the second driving device can drive the sliding plate to move along the length direction of the transverse guide rail; the straight travel driving module is fixedly connected with the sliding plate; the mounting plate is arranged between the sliding plate and the third drill bit; one end of the sliding rod is fixedly connected with the mounting plate, the other end of the sliding rod penetrates through the sliding plate and is connected with the straight travel driving module, and the straight travel driving module can drive the sliding rod to move up and down so as to drive the mounting plate to move up and down.

In some embodiments, the attitude adjustment mechanism includes a first bearing housing, a second bearing housing, a flipping table, a flipping motor, and a swivel assembly. The first bearing seat and the second bearing seat are fixedly connected with the mounting plate; the overturning platform is arranged between the first bearing seat and the second bearing seat, and two ends of the overturning platform are respectively and rotatably connected with the first bearing seat and the second bearing seat; the overturning motor is fixedly connected with the mounting plate, one part of the overturning platform penetrates through the first bearing seat and is in transmission connection with the overturning motor, and the overturning motor drives the overturning platform to swing around the first axis; the top of the swivel assembly is provided with a slot for placing a bowling ball, and the swivel assembly can drive the bowling ball to rotate around a second axis which is perpendicular to the first axis.

In some embodiments, the clamping mechanism comprises at least two clamping assemblies, the clamping assemblies comprise a corner pressing cylinder and a pressing plate, one end of the corner pressing cylinder is fixedly connected with the rotating assembly, and the other end of the corner pressing cylinder is fixedly connected with the pressing plate.

In some embodiments, the full-automatic drilling device for bowling ball processing further includes a plurality of suction hoods respectively provided around the first drill, the second drill, and the third drill.

In some embodiments, the second drilling rig and the third drilling rig are identical in structure to the first drilling rig, which includes a drill motor, a speed reducer, and a drill chuck. The speed reducer is in transmission connection with the drilling motor, and at least one of the drilling motor and the speed reducer is fixedly connected with the frame; the drill chuck is fixedly connected with a rotating shaft on the speed reducer, and the first drill bit is connected with the drill chuck.

Compared with the prior art, the electric elements (such as a motor, an electromagnetic valve for controlling an air cylinder and the like) related to the utility model can be electrically connected with the PLC, and the PLC is used for controlling the rotation angles of the overturning motor and the revolving assembly and the displacement amounts of the lifting assembly, the transverse feeding assembly and the longitudinal feeding assembly, so that the manual marking of punching positions on bowling balls is not needed. The utility model can realize automatic control by utilizing the PLC controller, thereby realizing the automation of the whole bowling ball drilling operation, leading the bowling ball drilling operation to be simpler, greatly improving the efficiency of processing the bowling ball and being beneficial to the related enterprises to save the labor cost.

Drawings

In order to more clearly illustrate the embodiments of the utility model or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the utility model, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 and 2 are perspective views of an embodiment of the present utility model.

Fig. 3 is a schematic view of a first drill bit assembled with a first drilling machine according to an embodiment of the present utility model.

Fig. 4 is a front view of an assembled clamping assembly and swivel assembly showing the pressure plate in a closed position in accordance with an embodiment of the present utility model.

Fig. 5 is a top view of fig. 4.

Fig. 6 is a front view of an assembled clamping assembly and swivel assembly showing the pressure plate in an open position in accordance with an embodiment of the present utility model.

Fig. 7 is a partial view of fig. 2 showing the position of the first and second axes.

The reference numerals are explained as follows:

in the figure: 100. a feeding mechanism; 100a, a lifting assembly; 100b, infeed assembly; 100c, a longitudinal feed assembly; 200. a gesture adjusting mechanism; 300. a clamping mechanism; 1. a frame; 2. a first drill bit; 3. a second drill bit; 4. a third drill bit; 5. a first drilling machine; 501. a drill chuck; 502. a speed reducer; 503. a drilling motor; 6. a second drilling machine; 7. a third drilling machine; 8. a base; 9. a first driving device; 901. a servo motor; 902. a rack; 10. a longitudinal guide rail; 11. a frame; 12. a transverse guide rail; 13. a slide plate; 14. a straight travel driving module; 15. a mounting plate; 16. a slide bar; 17. a first bearing seat; 18. a second bearing seat; 19. a turnover table; 20. a turnover motor; 21. a swivel assembly; 2101. a slot hole; 22. a clamping assembly; 2201. a corner pressing cylinder; 2202. a pressing plate; 23. a dust hood; 24. an alignment sensor; 25. a slide block; 26. a bracket; E. a first axis; F. a second axis.

Detailed Description

In order to make the objects, technical solutions and advantages of the present utility model more apparent, the technical solutions of the present utility model will be described in detail below. It will be apparent that the described embodiments are only some, but not all, embodiments of the utility model. All other embodiments, based on the examples herein, which are within the scope of the utility model as defined by the claims, will be within the scope of the utility model as defined by the claims.

Referring to fig. 1 to 7, the utility model provides a full-automatic drilling device for bowling processing, which comprises a frame 1, a first drill bit 2, a second drill bit 3, a third drill bit 4, a first drilling machine 5 for driving the first drill bit 2 to rotate, a second drilling machine 6 for driving the second drill bit 3 to rotate and a third drilling machine 7 for driving the third drill bit 4 to rotate, wherein the first drilling machine 5, the second drilling machine 6 and the third drilling machine 7 are fixedly connected with the frame 1. The full-automatic drilling device for bowling processing also comprises a feeding mechanism 100, a gesture adjusting mechanism 200 arranged on the feeding mechanism 100 and a clamping mechanism 300 arranged on the gesture adjusting mechanism 200. Wherein the clamping mechanism 300 is used for fixing the bowling ball on the gesture adjusting mechanism 200, and the gesture adjusting mechanism 200 can drive the bowling ball to rotate; the feeding mechanism 100 may drive the attitude adjusting mechanism 200 to move to push the bowling ball fixed on the attitude adjusting mechanism 200 to the right front of one of the drill bits and drive the attitude adjusting mechanism 200 to move along the length direction of the drill bit.

In the present embodiment, the first drill bit 2 and the second drill bit 3 are vertically arranged side by side, and the third drill bit 4 is horizontally arranged below the first drill bit 2. As shown in fig. 1, the first drill bit 2 and the second drill bit 3 are parallel to each other, and the lower end of the first drill bit 2 and the lower end of the second drill bit 3 are positioned at approximately the same height. Along the transverse direction, the first drill bit 2, the second drill bit 3 and the third drill bit 4 are sequentially arranged from right to left, and the arrangement mode can avoid collision between the third drill bit 4 and the gesture adjusting mechanism 200 or the clamping mechanism 300 when the first drill bit 2 or the second drill bit 3 is used for drilling.

In this embodiment, the feed mechanism 100 includes a lift assembly 100a, an infeed assembly 100b, and a longitudinal feed assembly 100c. The lifting assembly 100a is connected with the bottom of the gesture adjusting mechanism 200 and drives the gesture adjusting mechanism 200 to move along the vertical direction; the infeed assembly 100b is connected to the bottom of the elevator assembly 100a and drives the elevator assembly 100a to move in a lateral direction; the longitudinal feed assembly 100c is coupled to the bottom of the infeed assembly 100b and drives the infeed assembly 100b to move in a longitudinal direction.

As shown in fig. 1 and 2, the X, Y and Z axes in the figures represent the lateral, longitudinal and vertical directions, respectively. The planes of the first drill bit 2 and the second drill bit 3 are parallel to the XZ plane, and the transverse feeding component 100b drives the lifting component 100a to move along the transverse direction, so that the gesture adjusting mechanism 200 is driven to move along the transverse direction, and the processing stations of the bowling ball fixed on the gesture adjusting mechanism 200 can be switched. In use, the clamping mechanism 300 stably secures the bowling ball to the attitude adjustment mechanism 200, preventing the drill from rotating the bowling ball.

In this embodiment, the longitudinal feed assembly 100c comprises a housing 8, a longitudinal rail 10 and a first drive means 9. The stand 8 is located below the third drill bit 4, and the stand 8 may be directly fixed to the ground. A longitudinal rail 10 is provided at the top of the housing 8 and the bottom of the infeed assembly 100b is connected to the longitudinal rail 10. The first driving means 9 is connected to the housing 8 and the infeed assembly 100b and drives the infeed assembly 100b along the length of the longitudinal rail 10.

As shown in fig. 2, in this embodiment, there are two longitudinal rails 10 in common, and both longitudinal rails 10 are fixedly connected to the top of the housing 8 and parallel to each other. In a specific implementation, the first driving device 9 mainly comprises a servo motor 901, a gear and a rack 902, wherein the rack 902 is fixedly connected with the machine base 8 and is parallel to the longitudinal guide rail 10, the gear is installed on a rotating shaft of the servo motor 901 and is meshed with the rack 902, and the servo motor 901 is fixedly connected with the bottom of the transverse feeding assembly 100 b. When the servo motor 901 is operated, the infeed assembly 100b moves along the length of the longitudinal rail 10. In other embodiments, the first driving device 9 may be a linear module of other forms.

In some embodiments, the infeed assembly 100b includes a frame 11, a cross rail 12, and a second drive. The bottom of the frame 11 is connected with the longitudinal guide rail 10, and the first driving device 9 can drive the frame 11 to slide along the length direction of the longitudinal guide rail 10; the transverse guide rail 12 is arranged at the top of the frame 11, and the bottom of the lifting assembly 100a is connected with the transverse guide rail 12; the second driving means is connected to the frame 11 and the elevation assembly 100a and drives the elevation assembly to move along the length direction of the lateral guide rail 12.

As shown in fig. 2, in this embodiment, there are two transverse rails 12 in common, and both transverse rails 12 are fixedly connected to the top of the frame 11 and parallel to each other. In order to achieve the connection between the frame 11 and the longitudinal rails 10, the bottom of the frame 11 is provided with four slides 25 matching the longitudinal rails 10, each two slides 25 being connected to one longitudinal rail 10, typically the slides 25 being detachably connected to the body of the frame 11. The second driving device in this embodiment is also mainly composed of a servo motor 901, a gear and a rack 902, and the connection manner between the second driving device and the frame 11 and the slide 13 can be seen from the first driving device 9, and the second driving device is not shown in the figure in order to more clearly show the structure of the present drilling device.

In this embodiment, the lift assembly 100a includes a slide 13, a linear travel drive module 14, a mounting plate 15, and a slide bar 16. The bottom of the sliding plate 13 is connected with the transverse guide rail 12, and the second driving device can drive the sliding plate 13 to move along the length direction of the transverse guide rail 12; the straight travel driving module 14 is fixedly connected with the sliding plate 13; the mounting plate 15 is arranged between the slide plate 13 and the third drill bit 4; one end of the slide bar 16 is fixedly connected with the mounting plate 15, the other end of the slide bar 16 penetrates through the slide plate 13 and is connected with the straight travel driving module 14, and the straight travel driving module 14 can drive the slide bar 16 to move up and down so as to drive the mounting plate 15 to move up and down. In order to achieve the connection between the slide 13 and the transverse rail 12, the bottom of the slide 13 is provided with four slide blocks 25 matching the transverse rail 12, each two slide blocks 25 being connected to one transverse rail 12, typically the slide blocks 25 being detachably connected to the slide 13 body. The straight travel driving module 14 may be a private electric cylinder, an air cylinder, a hydraulic cylinder, or the like.

In the present embodiment, the posture adjustment mechanism 200 includes a first bearing housing 17, a second bearing housing 18, a flipping table 19, a flipping motor 20, and a swivel assembly 21. The first bearing seat 17 and the second bearing seat 18 are fixedly connected with the mounting plate 15, the first bearing seat 17 and the second bearing seat 18 are positioned at the same height, the shaft hole on the first bearing seat 17 is coaxial with the shaft hole on the second bearing seat 18, and the axis of the shaft hole on the first bearing seat 17 is parallel to the X axis; the overturning platform 19 is arranged between the first bearing seat 17 and the second bearing seat 18, end shafts matched with the bearing seats are arranged at two ends of the overturning platform 19, and the end shafts at the two ends are respectively arranged in shaft holes of the first bearing seat 17 and the second bearing seat 18, so that rotatable connection of the overturning platform 19 and the first bearing seat 17 and the second bearing seat 18 is realized; the overturning motor 20 is fixedly connected with the mounting plate 15, a part of the overturning platform 19 passes through the first bearing seat 17 and is in transmission connection with the overturning motor 20, and the overturning motor 20 drives the overturning platform 19 to swing around a first axis E (namely the axis of the end shaft or the shaft hole); the top of the swivel assembly 21 is provided with a slot 2101 for placing a bowling ball, and the swivel assembly 21 is adapted to drive the bowling ball to rotate about a second axis F which is perpendicular to the first axis E.

The overturning motor 20 can adopt a servo motor 901, and the overturning motor 20 is connected with an end shaft at the end part of the overturning platform 19 in a gear transmission or belt transmission mode. The swivel assembly 21 may be a commercially available swivel table that is electrically driven and primarily functions to carry the bowling ball and to rotate the bowling ball about the second axis F. The second axis F in this embodiment is perpendicular to the upper end surface of the swivel assembly 21, and is parallel to the Z axis when the swivel table 19 is in the position shown in fig. 2. The slot 2101 is preferably a circular hole, and the diameter of the slot 2101 is smaller than the diameter of the bowling ball. The slot 2101 may be a regular polygonal hole, and the inscribed circle of the slot 2101 may have a smaller diameter than the bowling ball.

In this embodiment, the clamping mechanism 300 includes three clamping assemblies 22. In other embodiments, the clamping mechanism 300 may also be comprised of two, four, or more than four clamping assemblies 22. As shown in fig. 4, the clamping assembly 22 includes a corner pressing cylinder 2201 and a pressing plate 2202, one end of the corner pressing cylinder 2201 is fixedly connected with the rotating assembly 21, and the other end of the corner pressing cylinder 2201 is fixedly connected with the pressing plate 2202. The corner hold-down cylinder 2201 is telescopic to adjust the distance between the platen 2202 and the swing assembly 21 and the corner hold-down cylinder 2201 can drive the platen 2202 to rotate in a plane parallel to the top surface of the swing assembly 21. All the corner pressing cylinders 2201 are connected with the electromagnetic valves through air pipes, and the actions of the corner pressing cylinders are controlled through the electromagnetic valves.

In the present embodiment, the full automatic drilling apparatus for bowling ball processing further includes three suction hoods 23, and the three suction hoods 23 are respectively installed around the first drill 2, the second drill 3, and the third drill 4. Only the suction hood 23 mounted around the third drill bit 4 is shown in fig. 2, and the suction hoods 23 mounted around the first drill bit 2 and the second drill bit 3 are not shown. One end of the dust hood 23 is connected with a dust collection device, when the device is used for drilling holes on bowling balls, dust generated in the drilling process can be sucked away by the dust hood 23 arranged around a drill bit, the cleaning of air in a production workshop is facilitated, and the health of workers is further guaranteed.

In the present embodiment, the second drilling machine 6 and the third drilling machine 7 are identical in structure to the first drilling machine, and the first drilling machine 5 includes a drill motor 503, a speed reducer 502, and a drill chuck 501. The speed reducer 502 is in transmission connection with the drilling motor 503, and the first drilling machine 5 and/or the speed reducer 502 are/is fixedly connected with the frame 1; the drill chuck 501 is fixedly connected with a rotating shaft on the speed reducer 502, and the first drill bit 2 is connected with the drill chuck 501.

As shown in fig. 2, in this embodiment, a support 26 is fixed to the second drilling machine 6, an alignment sensor 24 is installed at the end of the support 26, and a receiving end corresponding to the alignment sensor 24 is installed at the center of the turning assembly 21, so that the equipment can be aligned by the alignment sensor 24 before the equipment is processed.

In order to facilitate understanding of the working principle of the full-automatic drilling device for bowling processing provided by the utility model, the working process of the utility model is briefly described below, and mainly comprises the following six steps.

1. Placing bowling balls to be processed: prior to beginning the processing of the bowling ball, the attitude adjustment mechanism 200 is in an initial position, the pressure plate 2202 on the clamping assembly 22 is in an open position (see fig. 6), and the bowling ball to be processed is placed in the slot 2101;

2. fixing bowling balls: the corner pressing cylinder 2201 drives the pressing plate 2202 to rotate, the pressing plate 2202 points to the center of the rotary assembly 21, then the corner pressing cylinder 2201 drives the pressing plate 2202 to move downwards, and the pressing plate 2202 presses on the bowling ball, so that the bowling ball is fixed;

3. processing a first finger hole: the transverse feeding assembly 100b drives the lifting assembly 100a to move rightwards, the gesture adjusting mechanism 200 arranged on the lifting assembly 100a synchronously moves rightwards until the gesture adjusting mechanism moves right below the first drill bit 2, the first drill bit 2 points to the center of the bowling ball, then the straight stroke driving module 14 pushes the mounting plate 15 to move upwards, the bowling ball starts drilling operation after contacting with the first drill bit 2, and the drilling depth can be controlled by controlling the stroke of the straight stroke driving module 14; after the first finger hole is machined, the straight travel driving module 14 drives the mounting plate 15 to move downwards so that the first drill bit 2 withdraws from the bowling ball;

4. machining a second finger hole: the transverse feeding assembly 100b drives the lifting assembly 100a to move leftwards to the right lower part of the second drill bit 3, then the turning motor 20 drives the turning assembly 21 to turn over, so that the point of a second finger hole to be processed on the bowling ball is aligned with the second drill bit 3 up and down, and then the straight travel driving module 14 pushes the mounting plate 15 to move upwards to drill holes; after the second finger hole is machined, the straight travel driving module 14 drives the mounting plate 15 to move downwards so that the second drill bit 3 withdraws from the bowling ball;

5. processing a third finger hole: the transverse feeding assembly 100b drives the lifting assembly 100a to move right below the third drill bit to the left, then the overturning motor 20 and the revolving assembly 21 rotate a certain angle, meanwhile, the straight stroke driving module 14 adjusts the height of the mounting plate 15 to enable the point of a third finger hole to be processed on the bowling ball to be aligned with the front and back of the third drill bit 4, then the longitudinal feeding assembly 100c drives the transverse feeding assembly 100b to move towards the third drill bit 4 for drilling, and the depth of the third finger hole can be controlled by controlling the stroke of the longitudinal feeding assembly 100 c; after the third finger hole is finished, the longitudinal feed assembly 100c is reversely moved to withdraw the third drill 4 from the bowling ball;

6. the device returns to the initial position: the turnover motor 20 and the turning unit 21 are then rotated to keep the turnover table 19 and the turning unit 21 horizontal, the infeed unit 100b drives the elevation unit 100a again to return to the original position, and the rotation angle pushing cylinder 2201 is then lifted and rotated to bring the pressing plate 2202 to the opened position, thereby completing the whole process of bowling.

The electrical components (such as a motor, a solenoid valve for controlling a cylinder, etc.) according to the present utility model can be electrically connected to the PLC controller, and the rotational angles of the turnover motor 20 and the swing assembly 21 and the displacement amounts of the elevation assembly 100a, the lateral feeding assembly 100b, and the longitudinal feeding assembly 100c are controlled by the PLC controller, so that it is not necessary to manually mark the punching position on the bowling ball. The utility model can realize automatic control by utilizing the PLC controller, thereby realizing the automation of the whole bowling ball drilling operation, leading the bowling ball drilling operation to be simpler, greatly improving the efficiency of processing the bowling ball and reducing the processing error. In addition, the utility model is beneficial to the related enterprises to save labor cost.

The foregoing is merely illustrative of the present utility model, and the present utility model is not limited thereto, and any person skilled in the art will readily recognize that variations or substitutions are within the scope of the present utility model. Therefore, the protection scope of the present utility model shall be subject to the protection scope of the claims.

Claims (10)

1. The utility model provides a bowling ball processing is with full-automatic drilling equipment, includes frame, first drill bit, second drill bit, third drill bit, is used for the drive first drill bit pivoted first rig, be used for the drive second drill bit pivoted second rig and be used for the drive third drill bit pivoted third rig, its characterized in that: the device also comprises a feeding mechanism, a gesture adjusting mechanism arranged on the feeding mechanism and a clamping mechanism arranged on the gesture adjusting mechanism; the first drilling machine, the second drilling machine and the third drilling machine are fixedly connected with the frame; the clamping mechanism is used for fixing the bowling ball on the gesture adjusting mechanism, and the gesture adjusting mechanism can drive the bowling ball to rotate; the feeding mechanism can drive the gesture adjusting mechanism to move so as to push the bowling ball fixed on the gesture adjusting mechanism to the right front of one of the drill bits and drive the gesture adjusting mechanism to move along the length direction of the drill bit.

2. The full-automatic drilling apparatus for bowling ball processing in accordance with claim 1 wherein: the first drill bit and the second drill bit are vertically arranged side by side, and the third drill bit is horizontally arranged and positioned below the first drill bit.

3. The full-automatic drilling device for bowling processing of claim 2 wherein said feed mechanism includes:

the lifting assembly is connected with the bottom of the gesture adjusting mechanism and drives the gesture adjusting mechanism to move along the vertical direction;

a lateral feed assembly coupled to the bottom of the lift assembly and driving the lift assembly to move in a lateral direction;

a longitudinal feed assembly coupled to the bottom of the infeed assembly and driving the infeed assembly to move in a longitudinal direction.

4. A fully automatic bowling ball processing in accordance with claim 3 wherein said longitudinal feed assembly includes:

the base is positioned below the third drill bit;

the longitudinal guide rail is arranged at the top of the machine base, and the bottom of the transverse feeding assembly is connected with the longitudinal guide rail;

and the first driving device is connected with the base and the transverse feeding assembly and drives the transverse feeding assembly to move along the length direction of the longitudinal guide rail.

5. The full-automatic bowling ball processing device of claim 4 wherein said infeed assembly includes:

the bottom of the frame is connected with the longitudinal guide rail, and the first driving device can drive the frame to slide along the length direction of the longitudinal guide rail;

the transverse guide rail is arranged at the top of the frame, and the bottom of the lifting assembly is connected with the transverse guide rail;

and the second driving device is connected with the frame and the lifting assembly and drives the lifting assembly to move along the length direction of the transverse guide rail.

6. The full-automatic bowling ball processing device of claim 5 wherein said elevator assembly includes:

the bottom of the sliding plate is connected with the transverse guide rail, and the second driving device can drive the sliding plate to move along the length direction of the transverse guide rail;

the straight travel driving module is fixedly connected with the sliding plate;

the mounting plate is arranged between the sliding plate and the third drill bit;

the sliding rod is fixedly connected with the mounting plate at one end, the other end of the sliding rod penetrates through the sliding plate and is connected with the straight travel driving module, and the straight travel driving module can drive the sliding rod to move up and down so as to drive the mounting plate to move up and down.

7. The full-automatic drilling device for bowling processing of claim 6 wherein: the gesture adjusting mechanism comprises:

the first bearing seat is fixedly connected with the mounting plate;

the second bearing seat is fixedly connected with the mounting plate;

the overturning platform is arranged between the first bearing seat and the second bearing seat, and two ends of the overturning platform are respectively and rotatably connected with the first bearing seat and the second bearing seat;

the overturning motor is fixedly connected with the mounting plate, one part of the overturning platform penetrates through the first bearing seat and is in transmission connection with the overturning motor, and the overturning motor drives the overturning platform to swing around a first axis;

the top of the swivel assembly is provided with a slot hole for placing the bowling ball, and the swivel assembly can drive the bowling ball to rotate around a second axis, and the second axis is perpendicular to the first axis.

8. The full-automatic drilling device for bowling processing of claim 7 wherein: the clamping mechanism comprises at least two clamping assemblies, each clamping assembly comprises a corner pressing cylinder and a pressing plate, one end of each corner pressing cylinder is fixedly connected with the corresponding rotating assembly, and the other end of each corner pressing cylinder is fixedly connected with the corresponding pressing plate.

9. A full-automatic bowling ball processing drilling apparatus in accordance with any one of claims 1 to 8 wherein: the device also comprises a plurality of dust suction hoods, wherein the dust suction hoods are arranged around the first drill bit, the second drill bit and the third drill bit.

10. The full-automatic drilling apparatus for bowling ball processing in accordance with any one of claims 1 to 8, wherein said second and third drills are identical in structure to said first drill, said first drill comprising:

a drilling motor;

the speed reducer is in transmission connection with the drilling motor, and at least one of the drilling motor and the speed reducer is fixedly connected with the frame;

the drill chuck is fixedly connected with a rotating shaft on the speed reducer, and the first drill bit is connected with the drill chuck.