CN219043667U - Numerical control drilling machine for flange machining - Google Patents

Abstract

The utility model relates to the technical field of numerically-controlled drilling machines, in particular to a numerically-controlled drilling machine for flange machining, which comprises a base, a clamping mechanism positioned at one end of the base and a moving mechanism positioned at the other end of the base, wherein a first drilling mechanism and a second drilling mechanism are arranged on the moving mechanism, and the first drilling mechanism and the second drilling mechanism horizontally face the clamping mechanism. The distance between the first drilling mechanism and the second drilling mechanism is set according to the distance between the two holes of the center symmetry of the flange to be processed, after the holes are drilled, the clamping mechanism is rotated according to actual needs, and the distance between the first drilling mechanism and the second drilling mechanism is not required to be adjusted at the moment, so that the method is simple to operate, short in time consumption and high in efficiency.

Description

Numerical control drilling machine for flange machining

Technical Field

The utility model relates to the technical field of numerical control drilling machines, in particular to a numerical control drilling machine for flange machining.

Background

Flanges are parts used for connection between pipelines and equipment and are usually connected with gaskets and bolts in a detachable connection as a set of combined sealing structures. The flange is provided with a plurality of holes for bolting, one hole is drilled in the flange, the other hole is drilled after the flange is drilled, the flange generally has 4 holes, 8 holes, 12 holes and 16 holes or more holes, if the flange is drilled, the drill bit is adjusted to drill the other hole after the hole is drilled, the operation is very complicated, the time is consumed, and the processing efficiency is affected.

Disclosure of Invention

In order to solve the technical problems, the utility model provides a numerical control drilling machine for flange machining.

The utility model provides a numerical control drilling machine for flange processing, which adopts the following technical scheme:

the utility model provides a numerical control drilling machine is used in flange processing, includes the base, is located fixture of base one end and is located the moving mechanism of base other end be equipped with first drilling mechanism and second drilling mechanism on the moving mechanism, first drilling mechanism and second drilling mechanism level orientation fixture.

Through adopting above-mentioned technical scheme, according to waiting to process the distance setting between the first drilling mechanism and the second drilling mechanism of the distance in two holes of flange central symmetry, after drilling, rotatory fixture is according to actual need, at this moment need not adjust the distance between first drilling mechanism and the second drilling mechanism, direct drilling can, this method easy operation, it is consuming time short, efficient.

Preferably, the first drilling mechanism comprises a first drill bit, a first drilling machine, a first air cylinder, a first mounting plate and a first connecting plate, wherein the first drill bit is arranged at the output end of the first drilling machine, the other end of the first drilling machine is arranged at the output end of the first air cylinder, the first air cylinder is fixed on the first mounting plate, and the first connecting plate is arranged on the side surface of the first mounting plate, which is away from the first drill bit.

Preferably, the second drilling mechanism comprises a second drill bit, a second drilling machine, a second air cylinder, a second mounting plate and a second connecting plate, wherein the second drill bit is arranged at the output end of the second drilling machine, the other end of the second drilling machine is arranged at the output end of the second air cylinder, the second air cylinder is fixed on the second mounting plate, and the second connecting plate is arranged on the side surface of the second mounting plate, deviating from the second drill bit.

Preferably, a first slider is arranged at the lower end of the side surface of the first mounting plate deviating from the first drill bit, a second slider is arranged at the lower side surface of the first connecting plate, a third slider is arranged at the lower end of the side surface of the second mounting plate deviating from the second drill bit, and a fourth slider is arranged at the lower side surface of the second connecting plate.

Preferably, the moving mechanism comprises a cross beam, a first driving motor, a second driving motor, a first guide rail and a second guide rail, wherein the first guide rail is arranged on the side surface of the cross beam close to the first drill bit along the direction of the cross beam, the second guide rail is arranged on the upper side surface of the cross beam along the direction of the cross beam, the first mounting plate is arranged on the side surface of the cross beam through a first sliding block and a first guide rail, the first mounting plate is arranged on the top of the cross beam through a second sliding block and a second guide rail, the second mounting plate is arranged on the side surface of the cross beam through a third sliding block and a first guide rail, the second mounting plate is arranged on the bottom of the cross beam through a fourth sliding block and a second guide rail, and the first driving motor is arranged on the first connecting plate, and the second driving motor is arranged on the second connecting plate.

By adopting the technical scheme, the first drilling mechanism and the second drilling mechanism can slide on the cross beam.

Preferably, the output ends of the first driving motor and the second driving motor are respectively provided with a gear, racks are arranged on the cross beam along the direction of the cross beam, and the first driving motor and the second driving motor are connected with the cross beam through the racks and the gears.

Through adopting above-mentioned technical scheme, first driving motor drives first drilling mechanism and removes on the crossbeam, and second driving motor drives second drilling mechanism and removes on the crossbeam.

Preferably, a first displacement sensor and a second displacement sensor are arranged in the middle of the upper end of the cross beam, the first displacement sensor faces the first connecting plate vertically, and the second displacement sensor faces the second connecting plate vertically.

By adopting the technical scheme, the distance between the first drilling mechanism and the second drilling mechanism is convenient to adjust.

Preferably, the clamping mechanism comprises a servo motor and a three-jaw chuck, wherein the output end of the servo motor is connected with one side of the three-jaw chuck, which is away from the clamping part, and the clamping part of the three-jaw chuck faces the first drilling mechanism and the second drilling mechanism.

Preferably, the base is detachably provided with a protective cover, the protective cover is made of metal, and the three-jaw chuck is positioned in the protective cover.

By adopting the technical scheme, the protective cover is arranged to prevent waste scraps from splashing.

Preferably, the two sides of the outer wall of the protective cover are detachably covered with the magnet sheets.

Through adopting above-mentioned technical scheme, set up the magnet piece in the side and can adsorb the sweeps, wait to process the back of finishing, dismantle the protection casing, take off the magnet piece, be convenient for the clearance and the recovery of sweeps.

In summary, the utility model has the following beneficial technical effects:

1. the distance between the first drilling mechanism and the second drilling mechanism is set according to the distance between the two holes of the center symmetry of the flange to be processed, after the holes are drilled, the clamping mechanism is rotated according to actual needs, and the distance between the first drilling mechanism and the second drilling mechanism is not required to be adjusted at the moment, so that the method is simple to operate, short in time consumption and high in efficiency.

2. The first displacement sensor and the second displacement sensor are arranged in the middle of the cross beam, so that the distance between the first drilling mechanism and the second drilling mechanism can be conveniently adjusted.

3. The setting protection casing can prevent that the sweeps that produces among the drilling from splashing, sets up the magnet piece on the lateral wall of protection casing, is convenient for to the clearance and the recovery of sweeps.

Drawings

FIG. 1 is a top view of the present utility model;

FIG. 2 is a front view of the present utility model;

FIG. 3 is an enlarged view at A in FIG. 2;

FIG. 4 is a rear view of the present utility model;

fig. 5 is a schematic structural view of the shield.

Reference numerals illustrate: 1. a base; 2. a servo motor; 3. a three-jaw chuck; 4. a first drill bit; 5. a first drilling machine; 6. a first cylinder; 7. a first mounting plate; 8. a first connection plate; 9. a first driving motor; 10. a cross beam; 11. a second guide rail; 12. a rack; 13. a second driving motor; 14. a second connecting plate; 15. a second mounting plate; 16. a second cylinder; 17. a second drilling machine; 18. a second drill bit; 19. a third slider; 20. A first guide rail; 21. a fourth slider; 22. a first slider; 23. a second slider; 24. a protective cover; 25. a magnet sheet.

Detailed Description

The utility model is described in further detail below with reference to fig. 1-5.

Referring to fig. 1-5, the embodiment discloses a numerical control drilling machine for flange processing, which comprises a base 1, a clamping mechanism positioned at one end of the base 1 and a moving mechanism positioned at the other end of the base 1, wherein a first drilling mechanism and a second drilling mechanism are arranged on the moving mechanism, and the first drilling mechanism and the second drilling mechanism face the clamping mechanism horizontally. The distance between the first drilling mechanism and the second drilling mechanism is set according to the distance between the two holes of the center symmetry of the flange to be processed, after the holes are drilled, the clamping mechanism is rotated according to actual needs, and the distance between the first drilling mechanism and the second drilling mechanism is not required to be adjusted at the moment, so that the method is simple to operate, short in time consumption and high in efficiency.

The first drilling mechanism comprises a first drill bit 4, a first drilling machine 5, a first air cylinder 6, a first mounting plate 7 and a first connecting plate 8, wherein the first drill bit 4 is arranged at the output end of the first drilling machine 5, the other end of the first drilling machine 5 is arranged at the output end of the first air cylinder 6, the first air cylinder 6 is fixed on the first mounting plate 7, and the first connecting plate 8 is arranged on the side face of the first mounting plate 7 deviating from the first drill bit 4.

The second drilling mechanism comprises a second drill bit 18, a second drilling machine 17, a second air cylinder 16, a second mounting plate 15 and a second connecting plate 14, wherein the second drill bit 18 is arranged at the output end of the second drilling machine 17, the other end of the second drilling machine 17 is arranged at the output end of the second air cylinder 16, the second air cylinder 16 is fixed on the second mounting plate 15, and the second connecting plate 14 is arranged on the side surface of the second mounting plate 15, which is away from the second drill bit 18.

A first slider 22 is provided at the lower end of the side of the first mounting plate 7 facing away from the first drill bit 4, a second slider 23 is provided at the lower side of the first connecting plate 8, a third slider 19 is provided at the lower end of the side of the second mounting plate 15 facing away from the second drill bit 18, and a fourth slider 21 is provided at the lower side of the second connecting plate 14.

The moving mechanism comprises a cross beam 10, a first driving motor 9, a second driving motor 13, a first guide rail 20 and a second guide rail 11, wherein the first guide rail 20 is arranged on the side surface of the cross beam 10 close to the first drill bit 4 along the direction of the cross beam 10, the second guide rail 11 is arranged on the upper side surface of the cross beam 10 along the direction of the cross beam 10, a first mounting plate 7 is arranged on the side surface of the cross beam 10 through a first sliding block 22 and the first guide rail 20, a first connecting plate 8 is arranged on the top of the cross beam 10 through a second sliding block 23 and the second guide rail 11, a second mounting plate 15 is arranged on the side surface of the cross beam 10 through a third sliding block 19 and the first guide rail 20, a second connecting plate 14 is arranged on the bottom of the cross beam 10 through a fourth sliding block 21 and the second guide rail 11, the first driving motor 9 is arranged on the first connecting plate 8, and the second driving motor 13 is arranged on the second connecting plate 14. The first and second drilling mechanisms are slidable on the cross beam 10.

The output ends of the first driving motor 9 and the second driving motor 13 are respectively provided with a gear, a rack 12 is arranged on the cross beam 10 along the direction of the cross beam 10, and the first driving motor 9 and the second driving motor 13 are connected with the cross beam 10 through the racks 12. The first driving motor drives the first drilling mechanism to move on the cross beam 10, and the second driving motor drives the second drilling mechanism to move on the cross beam 10.

A first displacement sensor and a second displacement sensor are arranged in the middle of the upper end of the cross beam 10, wherein the first displacement sensor faces the first connecting plate 8 vertically, and the second displacement sensor faces the second connecting plate 14 vertically. The distance between the first drilling mechanism and the second drilling mechanism is convenient to adjust.

The clamping mechanism comprises a servo motor 2 and a three-jaw chuck 3, wherein the output end of the servo motor 2 is connected with one side, deviating from the clamping part, of the three-jaw chuck 3, and the clamping part of the three-jaw chuck 3 faces towards the first drilling mechanism and the second drilling mechanism.

The base 1 is detachably provided with a protective cover 24, the protective cover 24 is made of metal, and the three-jaw chuck 3 is positioned in the protective cover 24. The shield 24 is provided to prevent the splatter of debris.

Magnet pieces 25 are detachably covered on both sides of the outer wall of the shield 24. The side face is provided with the magnet piece 25, so that scraps can be adsorbed, after the processing is finished, the protective cover 24 is detached, and the magnet piece 25 is taken down, so that the scraps can be cleaned and recovered conveniently.

The implementation principle of the numerical control drilling machine for flange machining provided by the embodiment of the utility model is as follows: the flange to be processed is clamped on the three-jaw chuck 3, the distance between the first drilling mechanism and the second drilling mechanism is adjusted according to the distance between two holes to be drilled on the same diameter of the flange, the first drilling mechanism and the second drilling mechanism are not required to be adjusted after the first drilling, the three-jaw chuck 3 is only required to be rotated to a proper position and then drilling is continued, the two holes can be processed through one-time drilling of the device, the positions of the first drilling mechanism and the second drilling mechanism are not required to be moved for many times, the three-jaw chuck 3 is only required to be simply rotated, the operation is convenient, the drilling efficiency is high, and the protective cover is set to play a role in safety protection.

The above embodiments are not intended to limit the scope of the present utility model, so: all equivalent changes in structure, shape and principle of the utility model should be covered in the scope of protection of the utility model.

Claims (10)

1. The utility model provides a numerical control drilling machine for flange processing which characterized in that: the drilling machine comprises a base (1), a clamping mechanism located at one end of the base (1) and a moving mechanism located at the other end of the base (1), wherein a first drilling mechanism and a second drilling mechanism are arranged on the moving mechanism, and the first drilling mechanism and the second drilling mechanism horizontally face the clamping mechanism.

2. The numerical control drilling machine for flange machining according to claim 1, wherein: the first drilling mechanism comprises a first drill bit (4), a first drilling machine (5), a first air cylinder (6), a first mounting plate (7) and a first connecting plate (8), wherein the first drill bit (4) is arranged at the output end of the first drilling machine (5), the other end of the first drilling machine (5) is arranged at the output end of the first air cylinder (6), the first air cylinder (6) is fixed on the first mounting plate (7), and the first connecting plate (8) is arranged at the side face of the first mounting plate (7) deviating from the first drill bit (4).

3. The numerical control drilling machine for flange machining according to claim 2, wherein: the second drilling mechanism comprises a second drill bit (18), a second drilling machine (17), a second air cylinder (16), a second mounting plate (15) and a second connecting plate (14), wherein the second drill bit (18) is arranged at the output end of the second drilling machine (17), the other end of the second drilling machine (17) is arranged at the output end of the second air cylinder (16), the second air cylinder (16) is fixed on the second mounting plate (15), and the second connecting plate (14) is arranged at the side face of the second mounting plate (15) deviating from the second drill bit (18).

4. A numerically controlled drilling machine for flange machining according to claim 3, wherein: the lower end of the side face of the first mounting plate (7) deviating from the first drill bit (4) is provided with a first sliding block (22), the lower side face of the first connecting plate (8) is provided with a second sliding block (23), the lower end of the side face of the second mounting plate (15) deviating from the second drill bit (18) is provided with a third sliding block (19), and the lower side face of the second connecting plate (14) is provided with a fourth sliding block (21).

5. The numerical control drilling machine for flange machining according to claim 4, wherein: the moving mechanism comprises a cross beam (10), a first driving motor (9), a second driving motor (13), a first guide rail (20) and a second guide rail (11), wherein the first guide rail (20) is arranged on the side face of the cross beam (10) close to the first drill bit (4) along the direction of the cross beam (10), the second guide rail (11) is arranged on the upper side face of the cross beam (10) along the direction of the cross beam (10), the first mounting plate (7) is arranged on the side face of the cross beam (10) through a first sliding block (22) and the first guide rail (20), the first connecting plate (8) is arranged on the top of the cross beam (10) through a second sliding block (23) and the second guide rail (11), the second mounting plate (15) is arranged on the side face of the cross beam (10) through a third sliding block (19) and the first guide rail (20), the second connecting plate (14) is arranged on the bottom of the cross beam (10) along the direction of the cross beam (10), and the first driving motor (9) is arranged on the first connecting plate (8) through a fourth sliding block (21) and the second guide rail (11).

6. The numerical control drilling machine for flange machining according to claim 5, wherein: the output ends of the first driving motor (9) and the second driving motor (13) are respectively provided with a gear, a rack (12) is arranged on the cross beam (10) along the direction of the cross beam (10), and the first driving motor (9) and the second driving motor (13) are connected with the cross beam (10) through the racks and the gears (12).

7. The numerical control drilling machine for flange machining according to claim 6, wherein: a first displacement sensor and a second displacement sensor are arranged in the middle of the upper end of the cross beam (10), the first displacement sensor faces the first connecting plate (8) vertically, and the second displacement sensor faces the second connecting plate (14) vertically.

8. The numerical control drilling machine for flange machining according to claim 1, wherein: the clamping mechanism comprises a servo motor (2) and a three-jaw chuck (3), wherein the output end of the servo motor (2) is connected with one side, deviating from the clamping part, of the three-jaw chuck (3), and the clamping part of the three-jaw chuck (3) faces towards the first drilling mechanism and the second drilling mechanism.

9. The numerical control drilling machine for flange machining according to claim 8, wherein: the base (1) is detachably provided with a protective cover (24), the protective cover (24) is made of metal, and the three-jaw chuck (3) is positioned in the protective cover (24).

10. The numerical control drilling machine for flange machining according to claim 9, wherein: magnet sheets (25) are detachably covered on two side surfaces of the outer wall of the protective cover (24).

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