CN217621077U - Duplex position hole milling device - Google Patents

Abstract

The utility model discloses a double-station hole milling device, which comprises a base, two Y-axis transmission mechanisms, two X-axis transmission mechanisms, two Z-axis transmission mechanisms and two hole milling mechanisms; the two Y-axis transmission mechanisms are arranged on the base and are distributed along the Y-axis direction, and the two Y-axis transmission mechanisms can be movably arranged back and forth along the Y-axis direction; the two X-axis transmission mechanisms are respectively arranged on the two Y-axis transmission mechanisms and move back and forth along with the corresponding Y-axis transmission mechanisms; the two Z-axis transmission mechanisms are respectively arranged on the two X-axis transmission mechanisms and are driven by the corresponding X-axis transmission mechanisms to move back and forth along the X-axis direction. The hole milling device is composed of the base, the two Y-axis transmission mechanisms, the two X-axis transmission mechanisms, the two Z-axis transmission mechanisms and the two hole milling mechanisms, the hole milling device is compact in structure and small in occupied space, the whole volume of hole milling equipment can be reduced, hole milling operation can be performed on two plates at a time, production efficiency is effectively improved, and the use requirement is met.

Description

Double-station hole milling device

Technical Field

The utility model belongs to the technical field of wood working machinery and specifically relates to indicate a duplex position hole milling device.

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.

The hole milling equipment is a common type in wood working machinery, is specially used for carrying out hole milling operation on plates, at present, a hole milling device used for the hole milling equipment is generally a simplex position, only one hole milling mechanism is arranged on the hole milling device, the hole milling operation can be carried out on one plate at a time, the efficiency is low, the use requirement cannot be met, and when the double-station operation is needed, the two hole milling devices are required to be spliced, the occupied space is large, and the whole volume of the hole milling equipment is large. Therefore, there is a need to develop a solution to the above problems.

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 duplex position hole milling device, and its compact structure can carry out the hole milling operation to two panels once, has effectively improved production efficiency.

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

a double-station hole milling device comprises a base, two Y-axis transmission mechanisms, two X-axis transmission mechanisms, two Z-axis transmission mechanisms and two hole milling mechanisms; the two Y-axis transmission mechanisms are arranged on the base and are arranged along the Y-axis direction, and the two Y-axis transmission mechanisms can be movably arranged back and forth along the Y-axis direction; the two X-axis transmission mechanisms are respectively arranged on the two Y-axis transmission mechanisms and move back and forth along with the corresponding Y-axis transmission mechanisms; the two Z-axis transmission mechanisms are respectively arranged on the two X-axis transmission mechanisms and driven by the corresponding X-axis transmission mechanisms to move back and forth along the X-axis direction; the two hole milling mechanisms are respectively arranged on the two Z-axis transmission mechanisms and driven by the corresponding Z-axis transmission mechanisms to move back and forth along the Z-axis direction.

As a preferable scheme, a Y-axis guide rail and a rack are arranged on the base, and the rack and the Y-axis guide rail are parallel to each other and extend along the Y-axis direction; the Y-axis transmission mechanism comprises a Y-axis sliding seat, a speed reducer mounting plate, a speed reducer, a Y-axis servo motor and a gear, wherein the Y-axis sliding seat is slidably mounted on a Y-axis guide rail through a Y-axis sliding block, the speed reducer mounting plate is fixed on the Y-axis sliding seat, the speed reducer is mounted on the speed reducer mounting plate, the Y-axis servo motor is arranged on the speed reducer and drives the speed reducer to operate, and the gear is fixed on an output shaft of the speed reducer and is meshed with a rack.

As a preferable scheme, an X-axis guide rail is arranged on the Y-axis sliding base, and the X-axis guide rail extends along the X-axis direction; the X-axis transmission mechanism comprises an X-axis sliding seat, an X-axis lead screw, an X-axis nut, an X-axis motor base and an X-axis servo motor; the X-axis sliding seat is slidably mounted on an X-axis guide rail through an X-axis sliding block, the Z-axis transmission mechanism is fixed on the X-axis sliding seat, the X-axis lead screw can be arranged on the Y-axis sliding seat in a back-and-forth rotating mode and extends along the X-axis direction, the X-axis nut is screwed with the X-axis lead screw and fixedly connected with the X-axis sliding seat, the X-axis motor seat is fixed on the Y-axis sliding seat, the X-axis servo motor is fixed on the X-axis motor seat, and the output shaft of the X-axis servo motor is fixedly connected with the X-axis lead screw through an X-axis coupler.

Preferably, the Z-axis transmission mechanism includes a Z-axis fixing plate, a Z-axis sliding plate, a Z-axis lead screw, a Z-axis nut, a Z-axis motor base and a Z-axis servo motor, the Z-axis fixing plate is fixed on the X-axis sliding seat, a Z-axis guide rail is arranged on the Z-axis fixing plate, the Z-axis guide rail extends along the Z-axis direction, the Z-axis sliding plate is slidably mounted on the Z-axis guide rail through a Z-axis slider, the hole milling mechanism is fixed on the Z-axis sliding plate, the Z-axis lead screw is rotatably mounted on the Z-axis fixing plate back and forth, the Z-axis lead screw extends along the Z-axis direction, the Z-axis nut is screwed with the Z-axis lead screw and is fixedly connected with the Z-axis sliding plate, the Z-axis motor base is fixed on the Z-axis fixing plate, the Z-axis servo motor is fixed on the Z-axis motor base, and an output shaft of the Z-axis servo motor is fixedly connected with the Z-axis lead screw through a Z-axis coupler.

As a preferred scheme, the hole milling mechanism comprises a motor mounting plate, a spindle motor and a milling cutter; the motor mounting plate is fixed on the Z-axis sliding plate, the spindle motor is fixed on the motor mounting plate and extends vertically, and the milling cutter is fixed on an output shaft of the spindle motor and extends upwards.

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

the hole milling device is composed of the base, the two Y-axis transmission mechanisms, the two X-axis transmission mechanisms, the two Z-axis transmission mechanisms and the two hole milling mechanisms, the hole milling device is compact in structure and small in occupied space, the whole volume of hole milling equipment can be reduced, hole milling operation can be performed on two plates at a time, production efficiency is effectively improved, and the use requirement is met.

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 an exploded view of a preferred embodiment of the present invention;

FIG. 2 is an exploded view of another preferred embodiment of the present invention;

FIG. 3 is an exploded view of the base portion of the preferred embodiment of the present invention;

FIG. 4 is an exploded view of the X-axis transmission mechanism in accordance with the preferred embodiment of the present invention;

FIG. 5 is a partially exploded view of the Y-axis transmission mechanism in accordance with the preferred embodiment of the present invention;

fig. 6 is an exploded view of the Z-axis transmission mechanism in the preferred embodiment of the present invention.

The attached drawings indicate the following:

10. base 11, Y-axis guide rail

12. Rack 20 and Y-axis transmission mechanism

21. Y-axis slide carriage 22 and speed reducer mounting plate

23. Speed reducer 24, Y-axis servo motor

25. Gear 26, Y-axis slider

27. X-axis guide rail 30 and X-axis transmission mechanism

31. X-axis slide carriage 32 and X-axis lead screw

33. X-axis nut 34 and X-axis motor base

35. X-axis servo motor 36 and X-axis sliding block

37. X-axis coupler 40 and Z-axis transmission mechanism

41. Z-axis fixing plate 42 and Z-axis sliding plate

43. Z-axis lead screw 44 and Z-axis nut

45. Z-axis motor base 46 and Z-axis servo motor

47. Z-axis guide rail 48 and Z-axis sliding block

49. Z-axis coupler 50 and hole milling mechanism

51. Motor mounting plate 52 and spindle motor

53. Provided is a milling cutter.

Detailed Description

Referring to fig. 1 to 6, a specific structure of a preferred embodiment of the present invention is shown, which includes a base 10, two Y-axis transmission mechanisms 20, two X-axis transmission mechanisms 30, two Z-axis transmission mechanisms 40, and two hole milling mechanisms 50.

The two Y-axis transmission mechanisms 20 are both disposed on the base 10 and arranged along the Y-axis direction, and the two Y-axis transmission mechanisms 20 are both movably disposed along the Y-axis direction. In the embodiment, the base 10 is provided with a Y-axis guide rail 11 and two racks 12, the racks 12 and the Y-axis guide rail 11 are parallel to each other and extend along the Y-axis direction, and the racks 12 are located between the two Y-axis guide rails 11; specifically, the Y-axis transmission mechanism 20 includes a Y-axis sliding base 21, a speed reducer mounting plate 22, a speed reducer 23, a Y-axis servo motor 24, and a gear 25, the Y-axis sliding base 21 is slidably mounted on the Y-axis guide rail 11 through a Y-axis slider 26, the speed reducer mounting plate 22 is fixed on the Y-axis sliding base 21, the speed reducer 23 is mounted on the speed reducer mounting plate 22, the Y-axis servo motor 24 is disposed on the speed reducer 23 and drives the speed reducer 23 to operate, and the gear 25 is fixed on an output shaft of the speed reducer 23 and is engaged with the rack 12.

The two X-axis transmission mechanisms 30 are respectively disposed on the two Y-axis transmission mechanisms 20 and move back and forth along with the corresponding Y-axis transmission mechanisms 20. In the present embodiment, the Y-axis slide 21 is provided with an X-axis guide rail 27, and the X-axis guide rail 27 extends in the X-axis direction; specifically, the X-axis transmission mechanism 30 includes an X-axis slide 31, an X-axis lead screw 32, an X-axis nut 33, an X-axis motor base 34, and an X-axis servo motor 35; the X-axis slide carriage 31 is slidably mounted on the X-axis guide rail 27 through an X-axis slider 36, the X-axis lead screw 32 is rotatably disposed on the Y-axis slide carriage 21 back and forth and extends along the X-axis direction, the X-axis nut 33 is screwed with the X-axis lead screw 32 and is fixedly connected with the X-axis slide carriage 31, the X-axis motor base 34 is fixed on the Y-axis slide carriage 21, the X-axis servomotor 35 is fixed on the X-axis motor base 34, and an output shaft of the X-axis servomotor 35 is fixedly connected with the X-axis lead screw 32 through an X-axis coupler 37.

The two Z-axis transmission mechanisms 40 are respectively disposed on the two X-axis transmission mechanisms 30 and driven by the corresponding X-axis transmission mechanisms 30 to move back and forth along the X-axis direction. In the present embodiment, the Z-axis transmission mechanism 40 is fixed on the X-axis slide 31, specifically, the Z-axis transmission mechanism 40 includes a Z-axis fixing plate 41, a Z-axis sliding plate 42, a Z-axis lead screw 43, a Z-axis nut 44, a Z-axis motor mount 45 and a Z-axis servo motor 46, the Z-axis fixing plate 41 is fixed on the X-axis slide 31, the Z-axis fixing plate 41 is provided with a Z-axis guide rail 47, the Z-axis guide rail 47 extends along the Z-axis direction, the Z-axis sliding plate 42 is slidably mounted on the Z-axis guide rail 47 through a Z-axis slider 48, the Z-axis lead screw 43 is rotatably mounted on the Z-axis fixing plate 41 back and forth, the Z-axis lead screw 43 extends along the Z-axis direction, the Z-axis nut 44 is screwed with the Z-axis lead screw 43 and is fixedly connected with the Z-axis sliding plate 42, the Z-axis motor mount 45 is fixed on the Z-axis fixing plate 41, the Z-axis servo motor 46 is fixed on the Z-axis motor mount 45, and an output shaft of the Z-axis servo motor 46 is fixedly connected with the Z-axis lead screw 43 through a Z-axis coupler 49.

The two hole milling mechanisms 50 are respectively arranged on the two Z-axis transmission mechanisms 40 and driven by the corresponding Z-axis transmission mechanisms 40 to move back and forth along the Z-axis direction. In the present embodiment, the hole milling mechanism 50 is fixed on the Z-axis sliding plate 42, and specifically, the hole milling mechanism 50 includes a motor mounting plate 51, a spindle motor 52 and a milling cutter 53; the motor mounting plate 51 is fixed to the Z-axis slide 42, the spindle motor 52 is fixed to the motor mounting plate 51 and extends vertically, and the milling cutter 53 is fixed to an output shaft of the spindle motor 52 and extends upward.

The working principle of the embodiment is detailed as follows:

when the two-axis X-axis hole milling machine works, firstly, the two Y-axis transmission mechanisms 20 drive the two X-axis transmission mechanisms 30 to move to the appointed positions along the Y-axis direction, then, the two X-axis transmission mechanisms 30 respectively drive the two Z-axis transmission mechanisms 40 to move to the appointed positions along the X-axis direction, then, the two Z-axis transmission mechanisms 40 respectively drive the two hole milling mechanisms 50 to move along the Z-axis direction, meanwhile, the two hole milling mechanisms 50 are started to mill holes on plates, the hole milling operation can be carried out on the two plates at one time, and the production efficiency is effectively improved.

The utility model discloses a design focus lies in: the hole milling device is formed by the base, the two Y-axis transmission mechanisms, the two X-axis transmission mechanisms, the two Z-axis transmission mechanisms and the two hole milling mechanisms, the structure is compact, the occupied space is small, the whole volume of hole milling equipment can be reduced, hole milling operation can be performed on two plates at a time, the production efficiency is effectively improved, and the use requirement is met.

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 modification, equivalent change and modification made to the above embodiments according to the technical spirit of the present invention are all within the scope of the technical solution of the present invention.

Claims (5)

1. The utility model provides a duplex position hole milling device which characterized in that: the device comprises a base, two Y-axis transmission mechanisms, two X-axis transmission mechanisms, two Z-axis transmission mechanisms and two hole milling mechanisms; the two Y-axis transmission mechanisms are arranged on the base and are arranged along the Y-axis direction, and the two Y-axis transmission mechanisms can be movably arranged back and forth along the Y-axis direction; the two X-axis transmission mechanisms are respectively arranged on the two Y-axis transmission mechanisms and move back and forth along with the corresponding Y-axis transmission mechanisms; the two Z-axis transmission mechanisms are respectively arranged on the two X-axis transmission mechanisms and driven by the corresponding X-axis transmission mechanisms to move back and forth along the X-axis direction; the two hole milling mechanisms are respectively arranged on the two Z-axis transmission mechanisms and driven by the corresponding Z-axis transmission mechanisms to move back and forth along the Z-axis direction.

2. A double station hole milling apparatus according to claim 1, wherein: the base is provided with a Y-axis guide rail and a rack, and the rack and the Y-axis guide rail are parallel to each other and extend along the Y-axis direction; the Y-axis transmission mechanism comprises a Y-axis sliding seat, a speed reducer mounting plate, a speed reducer, a Y-axis servo motor and a gear, wherein the Y-axis sliding seat is slidably mounted on a Y-axis guide rail through a Y-axis sliding block, the speed reducer mounting plate is fixed on the Y-axis sliding seat, the speed reducer is mounted on the speed reducer mounting plate, the Y-axis servo motor is arranged on the speed reducer and drives the speed reducer to operate, and the gear is fixed on an output shaft of the speed reducer and is meshed with a rack.

3. The double-station hole milling device according to claim 2, characterized in that: an X-axis guide rail is arranged on the Y-axis sliding seat and extends along the X-axis direction; the X-axis transmission mechanism comprises an X-axis sliding seat, an X-axis lead screw, an X-axis nut, an X-axis motor base and an X-axis servo motor; the X-axis sliding seat is slidably mounted on an X-axis guide rail through an X-axis sliding block, the Z-axis transmission mechanism is fixed on the X-axis sliding seat, the X-axis lead screw can be arranged on the Y-axis sliding seat in a back-and-forth rotating mode and extends along the X-axis direction, the X-axis nut is screwed with the X-axis lead screw and fixedly connected with the X-axis sliding seat, the X-axis motor seat is fixed on the Y-axis sliding seat, the X-axis servo motor is fixed on the X-axis motor seat, and the output shaft of the X-axis servo motor is fixedly connected with the X-axis lead screw through an X-axis coupler.

4. A double station hole milling apparatus according to claim 3, wherein: the Z-axis transmission mechanism comprises a Z-axis fixing plate, a Z-axis sliding plate, a Z-axis lead screw, a Z-axis nut, a Z-axis motor base and a Z-axis servo motor, the Z-axis fixing plate is fixed on the X-axis sliding seat, a Z-axis guide rail is arranged on the Z-axis fixing plate and extends along the Z-axis direction, the Z-axis sliding plate is slidably mounted on the Z-axis guide rail through a Z-axis sliding block, the hole milling mechanism is fixed on the Z-axis sliding plate, the Z-axis lead screw is rotatably mounted on the Z-axis fixing plate back and forth, the Z-axis lead screw extends along the Z-axis direction, the Z-axis nut is screwed with the Z-axis lead screw and fixedly connected with the Z-axis sliding plate, the Z-axis motor base is fixed on the Z-axis fixing plate, the Z-axis servo motor is fixed on the Z-axis motor base, and an output shaft of the Z-axis servo motor is fixedly connected with the Z-axis lead screw through a Z-axis coupler.

5. The double-station hole milling device according to claim 4, wherein: the hole milling mechanism comprises a motor mounting plate, a spindle motor and a milling cutter; this motor mounting panel is fixed in on the Z axle slide, and this spindle motor is fixed in on the motor mounting panel and vertical extension, and this milling cutter is fixed in on spindle motor's the output shaft and upwards extends.

Images