CN214815026U - Numerical control hinge drilling machine - Google Patents

Abstract

The utility model discloses a numerical control hinge drilling machine, which comprises a frame, an X-direction servo mechanism, a left fixed drilling and milling mechanism, a right movable drilling and milling mechanism, a left lifting conveying mechanism and a right lifting conveying mechanism; the X-direction servo mechanism is arranged at the upper part of the rack, the left fixed drilling and milling mechanism is fixed at one side of the rack, and the right movable drilling and milling mechanism is arranged at the other side of the rack, is driven by the X-direction servo mechanism and is matched with the left fixed drilling and milling mechanism; the left lifting conveying mechanism is arranged on one side of the left fixed drilling and milling mechanism, and the right lifting conveying mechanism is arranged on the right movable drilling and milling mechanism.

Description

Numerical control hinge drilling machine

Technical Field

The utility model relates to an aluminum alloy door and window processing technology field specifically is a numerical control hinge drilling machine.

Background

The aluminum alloy door and window is a type of window in a residential house, the hinge is installed on one side of a window sash and connected with a window frame, and in the manufacturing process of the aluminum alloy door and window, holes need to be drilled on the connected hinge so as to enable the hinge to be fixedly connected with the aluminum alloy door and window, so that a drilling machine needs to be used; however, the existing hinge drilling machine has the problems of low machining efficiency, difficult guarantee of machining precision and difficult batch production.

SUMMERY OF THE UTILITY MODEL

The utility model provides a numerical control hinge drilling machine solves current hinge drilling machine and has that machining efficiency is lower, and the machining precision is hardly guaranteed moreover, is difficult to form batch production's problem.

The utility model provides a technical scheme that its technical problem adopted is: a numerical control hinge drilling machine comprises a rack, an X-direction servo mechanism, a left fixed drilling and milling mechanism, a right movable drilling and milling mechanism, a left lifting conveying mechanism and a right lifting conveying mechanism; the X-direction servo mechanism is arranged at the upper part of the rack, the left fixed drilling and milling mechanism is fixed at one side of the rack, and the right movable drilling and milling mechanism is arranged at the other side of the rack, is driven by the X-direction servo mechanism and is matched with the left fixed drilling and milling mechanism; the left lifting conveying mechanism is arranged on one side of the left fixed drilling and milling mechanism, and the right lifting conveying mechanism is arranged on the right movable drilling and milling mechanism.

As a further improvement of the above scheme, the X-direction servo mechanism comprises an X-direction slider, a servo motor base, a servo motor, a lead screw support and a lead screw; the X-direction sliding block is arranged on the rack through an X-direction guide rail, the servo motor is arranged on one side of the rack through a servo motor seat, and the lead screw support is arranged on the other side of the rack and corresponds to the servo motor; one end of the screw rod is connected with the servo motor, and the other end of the screw rod is connected with the screw rod support.

As a further improvement of the scheme, a right moving beam is arranged on the right moving drilling and milling mechanism and is connected with the X-direction servo mechanism through a nut seat.

As a further improvement of the above scheme, the left fixed drilling and milling mechanism comprises a left fixed cross beam, a Y-direction guide rail, a Y-direction slider, a Y-direction slide seat, a drilling and milling power head, a driving mechanism, a pressing mechanism and a left workbench; the Y-direction guide rail is arranged at the upper part of the left fixed cross beam, the Y-direction sliding block is arranged on the Y-direction guide rail, the drilling and milling power head is arranged on the Y-direction sliding seat, the left workbench is arranged on the left fixed cross beam, and the pressing mechanism is arranged on the left workbench; the Y-direction sliding seat is also connected with a driving mechanism.

As a further improvement of the above scheme, the driving mechanism comprises a rack, a speed reducer, a servo motor and a gear; the rack is arranged on one side of the left fixed cross beam, the output end of the servo motor is connected with the speed reducer, the speed reducer is connected with the gear, and the gear is matched with the rack.

As a further improvement of the above scheme, a first positioning block and a second positioning block are further arranged on the left workbench; the first positioning block and the second positioning block are respectively arranged on two sides of the left workbench.

As a further improvement of the above scheme, the pressing mechanism comprises an upper pressing cylinder, an upper pressing cylinder mounting seat and an upper pressing block; the upper pressing cylinder is arranged on the left workbench through an upper pressing cylinder mounting seat, and the upper pressing block is arranged at the output end of the upper pressing cylinder and is matched and pressed with the left workbench.

As a further improvement of the above scheme, the left lifting conveying mechanism comprises a first lifting fixing seat, a second lifting fixing seat, a first lifting cylinder, a second lifting cylinder, a first lifting connecting plate, a second lifting connecting plate, a conveying belt supporting plate, a conveying belt, a driving wheel, a driven wheel and a conveying motor; the first lifting cylinder is arranged on the first lifting fixing seat, the first lifting fixing seat is arranged on one side of the conveying belt supporting plate through the first lifting connecting plate, the second lifting cylinder is arranged on the second lifting fixing seat, and the second lifting fixing seat is arranged on the other side of the conveying belt supporting plate through the second lifting connecting plate; the action wheel with from the driving wheel set up respectively in the both sides of conveyer belt backup pad just pass through the conveyer belt is connected, the action wheel still is connected with conveying motor.

Compared with the prior art, the beneficial effects of the utility model are that: the left fixed drilling and milling mechanism is fixed on the rack and cannot move along the X direction; the right moving drilling and milling mechanism can move along the X direction; the left fixed drilling and milling mechanism and the right movable drilling and milling mechanism are mutually mirror images in structure and have the same function; the left lifting conveying mechanism and the right lifting conveying mechanism are mutually mirror images in structure and have the same function; the left lifting conveying mechanism is fixed on the left fixed drilling and milling mechanism; the right lifting conveying mechanism is fixed on the right movable drilling and milling mechanism and moves along the X direction along with the right movable drilling and milling mechanism; the method has the advantages of high processing efficiency, accurate processing precision and capability of enabling the aluminum alloy doors and windows to form batch production.

Specifically, the left lifting conveying mechanism and the right lifting conveying mechanism are driven by a lifting cylinder I and a lifting cylinder II to lift, so that the conveying belt is higher than a left workbench, and is in head-on connection with the aluminum alloy doors and windows to convey to a workbench area.

The upper pressing cylinder drives the upper pressing block to press the aluminum alloy door and window upwards;

the drilling and milling power head is driven by a servo motor and a speed reducer and is driven by a gear rack to reach a drilling and milling position, and the drilling and milling power head has a telescopic feeding function to complete drilling and milling of a hole and a groove;

the upper pressing cylinder drives the upper pressing block to lift up, and upper pressing constraint on the aluminum alloy door and window is removed; the right moving drilling and milling mechanism is driven by the X-direction servo mechanism to loosen the holding of the aluminum alloy door and window;

the left lifting conveying mechanism and the right lifting conveying mechanism are lifted, so that the conveying belt is higher than the left workbench, the aluminum alloy door and window are driven to be separated from the workbench surface, and the conveying motor drives the conveying belt to transmit, so that the aluminum alloy door and window are output.

Drawings

FIG. 1 is a schematic view of the overall structure of a numerical control hinge drilling machine;

FIG. 2 is a schematic view of an X-direction servo mechanism;

FIG. 3 is a schematic structural view of a left drilling and milling mechanism;

fig. 4 is a schematic structural view of the left lifting and conveying mechanism.

In the drawings, the components represented by the respective reference numerals are listed below: 100 is a frame, 200 is an X-direction servo mechanism, 300 is a left drilling and milling mechanism, 400 is a right moving drilling and milling mechanism, 500 is a left lifting and conveying mechanism, 600 is a right lifting and conveying mechanism, 1 is an X-direction guide rail, 2 is an X-direction slide block, 201 is a servo motor base, 202 is a servo motor, 203 is a lead screw support, 204 is a lead screw, 205 is a nut base, 301 is a left fixed cross beam, 302 is a Y-direction guide rail, 303 is a Y-direction slide block, 304 is a Y-direction slide base, 305 is a drilling and milling power head, 306 is a rack, 307 is a speed reducer, 308 is a servo motor, 309 is a gear, 310 is an upper pressing cylinder, 311 is an upper pressing cylinder mounting base, 312 is an upper pressing block, 313 is a left workbench, 314 is a first positioning block, 315 is a second positioning block, 401 is a right moving cross beam, 501 is a first lifting and fixing base, 502 is a second lifting and fixing base, 503 is a first lifting and lifting cylinder, 504 is a second lifting cylinder, 505 is a first lifting cylinder, 506 is a second lifting connecting plate, 507 is a conveying belt supporting plate, 508 is a conveying belt, 509 is a driving wheel, 510 is a driven wheel, and 511 is a conveying motor.

Detailed Description

The present invention will be described in further detail with reference to specific examples. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Referring to fig. 1-4, the present invention discloses a numerical control hinge drilling machine, which comprises a frame 100, an X-direction servo mechanism 200, a left fixed drilling and milling mechanism 300, a right mobile drilling and milling mechanism 400, a left lifting and conveying mechanism 500 and a right lifting and conveying mechanism 600; the X-direction servo mechanism 200 is arranged at the upper part of the frame 100, the left fixed drilling and milling mechanism 300 is fixed at one side of the frame 100, and the right movable drilling and milling mechanism 400 is arranged at the other side of the frame 100, is driven by the X-direction servo mechanism 200 and is matched with the left fixed drilling and milling mechanism 300; the left lifting conveying mechanism 500 is arranged on one side of the left fixed drilling and milling mechanism 300, and the right lifting conveying mechanism 600 is arranged on the right movable drilling and milling mechanism 400;

in the above, the left fixed drilling and milling mechanism 300 is fixed on the frame 100 and cannot move in the X direction; the right moving drilling and milling mechanism 400 can move along the X direction through the sliding block and the guide rail; the left fixed drilling and milling mechanism 300 and the right movable drilling and milling mechanism 400 are mutually mirror images in structure and have the same function; the left lifting conveying mechanism 500 and the right lifting conveying mechanism 600 are mutually mirror images in structure and have the same function; the left lifting conveying mechanism 500 is fixed on the left fixed drilling and milling mechanism 300; the right lifting and conveying mechanism 600 is fixed on the right mobile drilling and milling mechanism 400 and moves along the X direction along with the right mobile drilling and milling mechanism 400.

In the above embodiment, specifically, the X-direction servo mechanism 200 includes an X-direction slider 2, a servo motor base 201, a servo motor 202, a lead screw support 203, a lead screw 204, and a nut base 205; the X-direction sliding block 2 is arranged on the rack 100 through an X-direction guide rail 1, the servo motor 202 is arranged on one side of the rack 100 through a servo motor base 201, and the lead screw support 203 is arranged on the other side of the rack 100 and corresponds to the servo motor 202; one end of the lead screw 204 is connected with the servo motor 202, and the other end of the lead screw 204 is connected with the lead screw support 203.

The right moving drilling and milling mechanism 400 is provided with a right moving beam 401, and the right moving beam 401 is connected with the X-direction servo mechanism 200 through a nut seat 205.

The left fixed drilling and milling mechanism 300 comprises a left fixed cross beam 301, a Y-direction guide rail 302, a Y-direction slider 303, a Y-direction sliding seat 304, a drilling and milling power head 305, a rack 306, a speed reducer 307, a servo motor 308, a gear 309, an upper pressing cylinder 310, an upper pressing cylinder mounting seat 311, an upper pressing block 312, a left workbench 313, a first positioning block 314 and a second positioning block 315.

Specifically, the Y-direction guide rail 302 is arranged at the upper part of the left fixed cross beam 301, the Y-direction slider 303 is arranged on the Y-direction guide rail 302, the drilling and milling power head 305 is arranged on the Y-direction sliding base 304, the left workbench 313 is arranged on the left fixed cross beam 301, and the pressing mechanism is arranged on the left workbench 313; when the pressing mechanism is used, the pressing mechanism is fixed on the left workbench 313, the Y-direction sliding seat 304 is further connected with a driving mechanism, and the driving mechanism comprises a rack 306, a speed reducer 307, a servo motor 308 and a gear 309; the rack 306 is arranged on one side of the left fixed cross beam 301, the output end of the servo motor 308 is connected with the speed reducer 307, the speed reducer 307 is connected with the gear 309, and the gear 309 is matched with the rack 306; the first positioning block 314 and the second positioning block 315 are respectively disposed on the left workbench 313.

The pressing mechanism comprises an upper pressing cylinder 310, an upper pressing cylinder mounting seat 311 and an upper pressing block 312; the upper pressing cylinder 310 is arranged on the left workbench 313 through an upper pressing cylinder mounting seat 311; the upper pressing block 312 is disposed at an output end of the upper pressing cylinder 310 and is matched with the left workbench 313 for pressing.

The left lifting conveying mechanism 500 comprises a first lifting fixing seat 501, a second lifting fixing seat 502, a first lifting cylinder 503, a second lifting cylinder 504, a first lifting connecting plate 505, a second lifting connecting plate 506, a conveying belt supporting plate 507, a conveying belt 508, a driving wheel 509, a driven wheel 510 and a conveying motor 511; the first lifting cylinder 503 is arranged on the first lifting fixing seat 501, the first lifting fixing seat 501 is arranged on one side of the conveyor belt supporting plate 507 through a first lifting connecting plate 505, the second lifting cylinder 504 is arranged on the second lifting fixing seat 502, and the second lifting fixing seat 502 is arranged on the other side of the conveyor belt supporting plate 507 through a second lifting connecting plate 506; the driving wheel 509 and the driven wheel 510 are respectively disposed on two sides of the conveying belt supporting plate 507 and connected through the conveying belt 508, and the driving wheel 509 is further connected with a conveying motor 511.

In summary, when the numerical control hinge drilling machine is used, the left lifting conveying mechanism 500 and the right lifting conveying mechanism 600 are driven by the first lifting cylinder 503 and the second lifting cylinder 504 to lift, so that the conveying belt 508 is higher than the left workbench 313 to meet the aluminum alloy doors and windows and convey the aluminum alloy doors and windows to a workbench area, the left lifting conveying mechanism 500 and the right lifting conveying mechanism 600 fall down, so that the aluminum alloy doors and windows fall on the surface of the left workbench 313, the right moving drilling and milling mechanism 400 is driven by the X-direction servo mechanism 200 to reach a window forming size position, and the aluminum alloy doors and windows are tightly held and restrained by the first positioning block 314 and the second positioning block 315 fixed on the left workbench 313.

The upper pressing cylinder 310 drives the upper pressing block 312 to press the aluminum alloy door and window upwards;

the drilling and milling power head 305 is driven by a servo motor 308 and a speed reducer 307, is driven by a rack 306 through a gear 309, reaches a drilling and milling position, and has a telescopic feeding function to complete the drilling and milling of a hole and a groove;

after the processing is finished, the upper pressing cylinder 310 drives the upper pressing block 312 to lift up, and the upper pressing constraint on the aluminum alloy door and window is removed; the right moving drilling and milling mechanism 400 is driven by the X-direction servo mechanism 200 to loosen the holding of the aluminum alloy door and window;

the left lifting conveying mechanism 500 and the right lifting conveying mechanism 600 are lifted, so that the conveying belt 508 is higher than the left workbench 313, the aluminum alloy doors and windows are driven to be separated from the workbench surface, the conveying motor 511 drives the conveying belt 508 to transmit, and the aluminum alloy doors and windows are output.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are used merely for convenience of description and for simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; the two components can be directly connected or indirectly connected through an intermediate medium, and the two components can be communicated with each other. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art through specific situations.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, a plurality of improvements and decorations can be made without departing from the principle of the present invention, and these improvements and decorations should also be regarded as the protection scope of the present invention.

Claims (8)

1. The numerical control hinge drilling machine is characterized by comprising a rack (100), an X-direction servo mechanism (200), a left fixed drilling and milling mechanism (300), a right movable drilling and milling mechanism (400), a left lifting conveying mechanism (500) and a right lifting conveying mechanism (600); the X-direction servo mechanism (200) is arranged at the upper part of the rack (100), the left fixed drilling and milling mechanism (300) is fixed at one side of the rack (100), and the right movable drilling and milling mechanism (400) is arranged at the other side of the rack (100), is driven by the X-direction servo mechanism (200) and is matched with the left fixed drilling and milling mechanism (300); the left fixed drilling and milling mechanism and the right movable drilling and milling mechanism are structurally mirrored; the left lifting conveying mechanism (500) is arranged on one side of the left fixed drilling and milling mechanism (300), and the right lifting conveying mechanism (600) is arranged on the right movable drilling and milling mechanism (400).

2. The numerical control hinge drilling machine according to claim 1, characterized in that the X-direction servo mechanism (200) comprises an X-direction slider (2), a servo motor base (201), a servo motor (202), a lead screw support (203) and a lead screw (204); the X-direction sliding block (2) is arranged on the rack (100) through an X-direction guide rail (1), the servo motor (202) is arranged on one side of the rack (100) through a servo motor base (201), and the lead screw support (203) is arranged on the other side of the rack (100) and corresponds to the servo motor (202); one end of the lead screw (204) is connected with the servo motor (202), and the other end of the lead screw (204) is connected with the lead screw support (203).

3. The numerical control hinge drilling machine as claimed in claim 2, characterized in that a right moving beam (401) is arranged on the right moving drilling and milling mechanism (400), and the right moving beam (401) is connected with the X-direction servo mechanism (200) through a nut seat (205).

4. The numerical control hinge drilling machine as claimed in claim 1, characterized in that the left fixed drilling and milling mechanism (300) comprises a left fixed beam (301), a Y-directional guide rail (302), a Y-directional slider (303), a Y-directional slide (304), a drilling and milling power head (305), a driving mechanism, a pressing mechanism and a left working table (313); the Y-direction guide rail (302) is arranged at the upper part of the left fixed cross beam (301), the Y-direction sliding block (303) is arranged on the Y-direction guide rail (302), the drilling and milling power head (305) is arranged on the Y-direction sliding seat (304), the left workbench (313) is arranged on the left fixed cross beam (301), and the pressing mechanism is arranged on the left workbench (313); the Y-direction sliding seat (304) is also connected with a driving mechanism.

5. The numerical control hinge drilling machine according to claim 4, characterized in that the driving mechanism comprises a rack (306), a reducer (307), a servo motor (308) and a gear (309); the rack (306) is arranged on one side of the left fixed cross beam (301), the output end of the servo motor (308) is connected with the speed reducer (307), the speed reducer (307) is connected with the gear (309), and the gear (309) is matched with the rack (306).

6. The numerical control hinge drilling machine as claimed in claim 4, characterized in that a first positioning block (314) and a second positioning block (315) are further arranged on the left working table (313); the first positioning block (314) and the second positioning block (315) are respectively arranged on two sides of the left workbench (313).

7. The numerical control hinge drilling machine according to claim 4, wherein the pressing mechanism comprises an upper pressing cylinder (310), an upper pressing cylinder mounting seat (311) and an upper pressing block (312); the upper pressing cylinder (310) is arranged on the left workbench (313) through an upper pressing cylinder mounting seat (311); the upper pressing block (312) is arranged at the output end of the upper pressing cylinder (310) and is matched and pressed with the left workbench (313).

8. The numerical control hinge drilling machine as claimed in claim 1, wherein the left lifting and conveying mechanism (500) comprises a first lifting and fixing seat (501), a second lifting and fixing seat (502), a first lifting and conveying cylinder (503), a second lifting and conveying cylinder (504), a first lifting and connecting plate (505), a second lifting and connecting plate (506), a conveyor belt supporting plate (507), a conveyor belt (508), a driving wheel (509) and a driven wheel (510); the first lifting cylinder (503) is arranged on the first lifting fixing seat (501), the first lifting fixing seat (501) is arranged on one side of the conveyor belt supporting plate (507) through a first lifting connecting plate (505), the second lifting cylinder (504) is arranged on a second lifting fixing seat (502), and the second lifting fixing seat (502) is arranged on the other side of the conveyor belt supporting plate (507) through a second lifting connecting plate (506); drive wheel (509) and follow driving wheel (510) set up respectively in the both sides of conveyer belt backup pad (507) and pass through conveyer belt (508) are connected, drive wheel (509) still are connected with conveying motor (511).

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