CN217621071U - Compact structure's full numerical control bores row structure - Google Patents

Abstract

The utility model discloses a full numerical control drill gang structure with compact structure, which comprises a base, two X-direction driving mechanisms, two Y-direction driving mechanisms and two drilling modules; the base extends along the Y-axis direction; the two X-direction driving mechanisms are symmetrically arranged at the tops of the two ends of the base respectively; the two Y-direction driving mechanisms are symmetrically arranged at the bottoms of the two ends of the base respectively; the two drilling modules are positioned below the base and driven by two Y-direction driving mechanisms to move back and forth along the Y-axis direction respectively, and each drilling module comprises a drilling saddle, a drilling bag and a Z-direction driving mechanism. Set up two X through the cooperation to actuating mechanism, two Y to actuating mechanism and two drilling modules, make the utility model has the advantages of reasonable design, compactness, it is small, can effectively improve the flexibility of drilling processing to can furthest improve the efficiency of drilling processing operation, facilitate for the production operation.

Description

Compact structure's full numerical control bores row structure

Technical Field

The utility model belongs to the technical field of the wood working machinery and specifically relates to indicate a compact structure's full numerical control bores row structure.

Background

The development of electronic technology, digital control technology, laser technology, microwave technology and high-pressure jet technology brings new vitality to the automation, flexibility, intelligence and integration of furniture machinery, so that the variety of machine tools is continuously increased, and the technical level is continuously improved.

At the in-process of carrying out the drilling processing operation to panel, present wood machinery all adopts and bores the row, bores the row and has a plurality of drill bits and can carry out porous processing to panel in coordination with work, can effectively improve production efficiency, brings very big facility for the processing production operation. In the working process of the drill row, the drill pack needs to be controlled to move in the X-axis direction, the Y-axis direction and the Z-axis direction so as to move the drill pack to a specified position for drilling. In the prior art, due to the fact that the structural design of the drill row is unreasonable, the flexibility of drilling machining is limited, and the efficiency of drilling machining operation cannot be improved to the greatest extent. Therefore, there is a need to improve the existing drill row and design a fully numerical control drill row structure.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model discloses to the disappearance that prior art exists, its main objective provides a compact structure's full numerical control bores row structure, and its structural design is reasonable, compact, and is small, effectively improves the flexibility of drilling processing.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a full numerical control drill gang structure with compact structure comprises a base, two X-direction driving mechanisms, two Y-direction driving mechanisms and two drilling modules; the base extends along the Y-axis direction; the two X-direction driving mechanisms are symmetrically arranged at the tops of the two ends of the base respectively; the two Y-direction driving mechanisms are symmetrically arranged at the bottoms of the two ends of the base respectively; the two drilling modules are positioned below the base and driven by two Y-direction driving mechanisms to move back and forth along the Y-axis direction respectively, and each drilling module comprises a drilling saddle, a drilling bag and a Z-direction driving mechanism; the drilling saddle is connected with the Y-direction driving mechanism and driven by the Y-direction driving mechanism to move back and forth along the Y-axis direction; the drill bag can be movably arranged on the drilling saddle back and forth along the Z-axis direction; the Z-direction driving mechanism is arranged on the drilling saddle and drives the drill bag to move back and forth along the Z-axis direction.

As a preferable scheme, the X-direction driving mechanism comprises a first motor base, a speed reducer, a first servo motor and a helical gear; the first motor base is fixed on the base; the speed reducer is fixed on the first motor base through the first mounting plate; the first servo motor is fixed on the speed reducer and drives the speed reducer to operate; the helical gear is mounted on an output shaft of the speed reducer.

As a preferable scheme, the Y-direction driving mechanism comprises a second motor base, a Y-direction screw rod, a Y-direction nut base and a second servo motor; the second motor base is fixed on the bottom surface of the end part of the base; two ends of the Y-direction screw rod are respectively and rotatably arranged on the bottom surface of the base through a fixed seat and a supporting seat, and the Y-direction screw rod extends along the Y-axis direction; the Y-direction nut seat is in threaded connection with the Y-direction screw rod and is fixed at the top of the drilling saddle; the second servo motor is fixed on the second motor base and drives the Y-direction screw rod to rotate back and forth.

Preferably, the drilling saddle comprises a Z-axis fixing plate and a Y-axis sliding plate, the Z-axis fixing plate extends vertically, the Y-axis sliding plate is fixed at the top end of the Z-axis fixing plate and extends forwards horizontally, the Y-direction nut seat is fixed on the top surface of the Y-axis sliding plate, the Y-axis sliding plate is installed at the bottom of the base through a Y-direction sliding block, and rib plates are fixed between two sides of the Y-axis sliding plate and two sides of the Z-axis fixing plate.

Preferably, the drill bag comprises a Z-axis sliding plate, a drill bag mounting plate and a drill bag body, wherein the front side surface of the Z-axis fixing plate is provided with a Z-direction guide rail, the Z-axis sliding plate is slidably mounted on the Z-direction guide rail through a Z-direction sliding block, the drill bag mounting plate is fixed on the front side surface of the Z-axis sliding plate, and the drill bag body is fixed on the front side surface of the drill bag mounting plate.

Preferably, the Z-direction driving mechanism comprises a Z-direction lead screw, a Z-direction nut seat and a third servo motor, the Z-direction lead screw is rotatably mounted on the front side surface of the Z-axis fixing plate, and the Z-direction lead screw extends along the Z-axis direction; the Z-direction nut seat is screwed with the Z-direction screw rod and is fixed on the rear side surface of the Z-axis sliding plate; the third servo motor is fixed on the Y-axis sliding plate and drives the Z-direction screw rod to rotate back and forth, and the third servo motor protrudes upwards out of the base.

Compared with the prior art, the utility model obvious advantage and beneficial effect have, particularly, can know by above-mentioned technical scheme:

set up two X through the cooperation to actuating mechanism, two Y to actuating mechanism and two drilling modules, make the utility model has the advantages of reasonable design, compactness, it is small, can effectively improve the flexibility of drilling processing to can furthest improve the efficiency of drilling processing operation, facilitate for the production operation.

To illustrate the structural features and functions of the present invention more clearly, the present invention will be described in detail with reference to the accompanying drawings and specific embodiments.

Drawings

FIG. 1 is a perspective view of a preferred embodiment of the present invention;

FIG. 2 is a perspective view of another angle of the preferred embodiment of the present invention;

fig. 3 is an exploded view of the preferred embodiment of the present invention;

fig. 4 is an exploded view of the X-direction drive mechanism in the preferred embodiment of the present invention;

FIG. 5 is an exploded view of the Y-drive mechanism in the preferred embodiment of the invention;

FIG. 6 is an exploded view of the drilling module in accordance with the preferred embodiment of the present invention;

fig. 7 is an exploded view of the drill saddle in the preferred embodiment of the present invention.

The attached drawings indicate the following:

10. base 20, X-direction drive mechanism

21. First motor cabinet 22 and speed reducer

23. First servo motor 24 and helical gear

25. First mounting plate 30, Y-direction drive mechanism

31. Second motor base 32 and Y-direction screw rod

33. Y-direction nut seat 34 and second servo motor

35. Fixing seat 36 and supporting seat

40. Drilling module 41 and drilling saddle

411. Z-axis fixing plate 412 and Y-axis sliding plate

413. Y-direction slide block 414 and rib plate

415. Z-direction guide rail 42 and drill bag

421. Z-axis sliding plate 422 and drill bag mounting plate

423. Drill pack body 424 and Z-direction sliding block

43. Z-direction driving mechanism 431 and Z-direction screw rod

432. A Z-direction nut seat 433 and a third servo motor.

Detailed Description

Referring to fig. 1 to 7, a detailed structure of a preferred embodiment of the present invention is shown, which includes a base 10, two X-directional driving mechanisms 20, two Y-directional driving mechanisms 30, and two drilling modules 40.

The base 10 extends along the Y-axis direction, and the base 10 is a welded type splicing structure.

The two X-direction driving mechanisms 20 are symmetrically arranged at the top of the two ends of the base 10, respectively, and the two X-direction driving mechanisms 20 are used for being installed in cooperation with an external equipment rack so as to drive the utility model to move back and forth along the X-axis direction; specifically, the X-direction driving mechanism 20 includes a first motor base 21, a speed reducer 22, a first servo motor 23, and a helical gear 24; the first motor base 21 is fixed on the base 10; the speed reducer 22 is fixed on the first motor base 21 through a first mounting plate 25; the first servo motor 23 is fixed on the speed reducer 22 and drives the speed reducer 22 to operate; the helical gear 24 is mounted on the output shaft of the reduction gear 22, and the helical gear 24 is mounted to engage with a rack on the external frame.

The two Y-direction driving mechanisms 30 are symmetrically arranged at the bottom of the two ends of the base 10 respectively; specifically, the Y-direction driving mechanism 30 includes a second motor seat 31, a Y-direction lead screw 32, a Y-direction nut seat 33, and a second servo motor 34; the second motor base 31 is fixed on the bottom surface of the end part of the base 10; two ends of the Y-direction screw 32 are rotatably mounted on the bottom surface of the base 10 through a fixing seat 35 and a supporting seat 36, respectively, and the Y-direction screw 32 extends along the Y-axis direction; the Y-direction nut seat 33 is connected with the Y-direction screw rod 32 in a screwing way; the second servo motor 34 is fixed on the second motor base 31 and drives the Y-direction screw rod 32 to rotate back and forth.

The two drilling modules 40 are positioned below the base 10 and driven by the two Y-direction driving mechanisms 30 to move back and forth along the Y-axis direction, and each drilling module 40 comprises a drilling saddle 41, a drilling bag 42 and a Z-direction driving mechanism 43; the drilling saddle 41 is connected with the Y-direction driving mechanism 30 and driven by the Y-direction driving mechanism 30 to move back and forth along the Y-axis direction; the drill bag 42 is movably arranged on the drilling saddle 41 back and forth along the Z-axis direction; the Z-direction driving mechanism 43 is disposed on the drilling saddle 41 and drives the drill pack 42 to move back and forth along the Z-axis direction. In this embodiment, the Y-nut seat 33 is fixed to the top of the drill saddle 41.

Specifically, the method comprises the following steps:

the drilling saddle 41 comprises a Z-axis fixing plate 411 and a Y-axis sliding plate 412, wherein the Z-axis fixing plate 411 extends vertically, the Y-axis sliding plate 412 is fixed at the top end of the Z-axis fixing plate 411 and extends forwards horizontally, the Y-direction nut seat 33 is fixed on the top surface of the Y-axis sliding plate 412, the Y-axis sliding plate 412 is installed at the bottom of the base 10 through a Y-direction slider 413, and rib plates 414 are fixed between two sides of the Y-axis sliding plate 412 and two sides of the Z-axis fixing plate 411 to enhance the overall structural strength of the drilling saddle 41.

The drill pack 42 includes a Z-axis slide plate 421, a drill pack mounting plate 422, and a drill pack body 423, wherein the front side surface of the Z-axis fixing plate 411 is provided with a Z-direction guide rail 415, the Z-axis slide plate 421 is slidably mounted on the Z-direction guide rail 415 by a Z-direction slider 424, the drill pack mounting plate 422 is fixed to the front side surface of the Z-axis slide plate 421, and the drill pack body 423 is fixed to the front side surface of the drill pack mounting plate 422.

The Z-direction driving mechanism 43 includes a Z-direction lead screw 431, a Z-direction nut seat 432 and a third servo motor 433, the Z-direction lead screw 431 is rotatably mounted on the front side surface of the Z-axis fixing plate 411, and the Z-direction lead screw 431 extends along the Z-axis direction; the Z-direction nut seat 432 is screwed with the Z-direction lead screw 431 and fixed on the rear side of the Z-axis sliding plate 421; the third servo motor 433 is fixed on the Y-axis sliding plate 412 and drives the Z-axis lead screw 431 to rotate back and forth, and the third servo motor 433 protrudes upward out of the base 10.

Detailed description the working principle of the present embodiment is as follows:

the during operation, the utility model discloses install in the frame of external equipment, according to the drilling position to panel, at first, drive to actuating mechanism 20 work by two X the utility model discloses remove along X axle direction, remove the back that targets in place, then, drive corresponding drilling module 40 along the removal of Y axle direction to actuating mechanism 30 by Y, remove the back that targets in place, drive by Z to actuating mechanism 43 and bore a packet 42 and remove along Z axle direction, remove the back that targets in place, bore a packet 42 work and carry out the drilling operation to panel.

The utility model discloses a design focus lies in: set up two X through the cooperation to actuating mechanism, two Y to actuating mechanism and two drilling modules, make the utility model has the advantages of reasonable design, compactness, it is small, can effectively improve the flexibility of drilling processing to can furthest improve the efficiency of drilling processing operation, facilitate for the production operation.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the technical scope of the present invention, so that any slight modifications, equivalent changes and modifications made by the technical spirit of the present invention to the above embodiments are all within the scope of the technical solution of the present invention.

Claims (6)

1. The utility model provides a compact structure's full numerical control bores row structure which characterized in that: comprises a base, two X-direction driving mechanisms, two Y-direction driving mechanisms and two drilling modules; the base extends along the Y-axis direction; the two X-direction driving mechanisms are symmetrically arranged at the tops of the two ends of the base respectively; the two Y-direction driving mechanisms are symmetrically arranged at the bottoms of the two ends of the base respectively; the two drilling modules are positioned below the base and driven by two Y-direction driving mechanisms to move back and forth along the Y-axis direction respectively, and each drilling module comprises a drilling saddle, a drilling bag and a Z-direction driving mechanism; the drilling saddle is connected with the Y-direction driving mechanism and is driven by the Y-direction driving mechanism to move back and forth along the Y-axis direction; the drill bag can be movably arranged on the drilling saddle back and forth along the Z-axis direction; the Z-direction driving mechanism is arranged on the drilling saddle and drives the drill bag to move back and forth along the Z-axis direction.

2. The fully numerically controlled drill gang structure with a compact structure according to claim 1, characterized in that: the X-direction driving mechanism comprises a first motor base, a speed reducer, a first servo motor and a helical gear; the first motor base is fixed on the base; the speed reducer is fixed on the first motor base through the first mounting plate; the first servo motor is fixed on the speed reducer and drives the speed reducer to operate; the helical gear is mounted on an output shaft of the speed reducer.

3. The fully numerically controlled drill gang structure with a compact structure according to claim 1, characterized in that: the Y-direction driving mechanism comprises a second motor base, a Y-direction screw rod, a Y-direction nut base and a second servo motor; the second motor base is fixed on the bottom surface of the end part of the base; two ends of the Y-direction screw rod are respectively and rotatably arranged on the bottom surface of the base through a fixed seat and a supporting seat, and the Y-direction screw rod extends along the Y-axis direction; the Y-direction nut seat is in threaded connection with the Y-direction screw rod and is fixed at the top of the drilling saddle; the second servo motor is fixed on the second motor base and drives the Y-direction screw rod to rotate back and forth.

4. The fully numerically controlled drill gang structure with a compact structure according to claim 3, characterized in that: the drilling saddle comprises a Z-axis fixing plate and a Y-axis sliding plate, the Z-axis fixing plate vertically extends, the Y-axis sliding plate is fixed at the top end of the Z-axis fixing plate and horizontally extends forwards, the Y-direction nut seat is fixed on the top surface of the Y-axis sliding plate, the Y-axis sliding plate is installed at the bottom of the base through a Y-direction sliding block, and rib plates are fixed between two sides of the Y-axis sliding plate and two sides of the Z-axis fixing plate.

5. The fully numerically controlled drill gang structure with a compact structure according to claim 4, characterized in that: the drill bag comprises a Z-axis sliding plate, a drill bag mounting plate and a drill bag body, wherein a Z-direction guide rail is arranged on the front side surface of the Z-axis fixing plate, the Z-axis sliding plate is slidably mounted on the Z-direction guide rail through a Z-direction sliding block, the drill bag mounting plate is fixed on the front side surface of the Z-axis sliding plate, and the drill bag body is fixed on the front side surface of the drill bag mounting plate.

6. The fully numerically-controlled drill gang structure of claim 5 is compact in structure, characterized in that: the Z-direction driving mechanism comprises a Z-direction screw rod, a Z-direction nut seat and a third servo motor, the Z-direction screw rod is rotatably arranged on the front side surface of the Z-axis fixing plate, and the Z-direction screw rod extends along the Z-axis direction; the Z-direction nut seat is screwed with the Z-direction screw rod and is fixed on the rear side surface of the Z-axis sliding plate; the third servo motor is fixed on the Y-axis sliding plate and drives the Z-direction screw rod to rotate back and forth, and the third servo motor protrudes upwards out of the base.

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