CN219096326U

CN219096326U - UV printer capable of adapting to ultra-wide thickness range

Info

Publication number: CN219096326U
Application number: CN202223610948.8U
Authority: CN
Inventors: 程学文; 程智豪
Original assignee: Shenzhen Andesheng Printing Equipment Co ltd
Current assignee: Shenzhen Andesheng Printing Equipment Co ltd
Priority date: 2022-12-30
Filing date: 2022-12-30
Publication date: 2023-05-30
Anticipated expiration: 2032-12-30

Abstract

The utility model discloses a UV printing device which can adapt to an ultra-wide thickness range, comprising: frame, Y axle actuating mechanism, Z axle actuating mechanism, crossbeam, X axle actuating mechanism and aircraft nose subassembly, Y axle actuating mechanism sets up in the frame, and Z axle actuating mechanism includes: the X-axis lifting mechanism comprises a first lifting mechanism and a second lifting mechanism, wherein the X-axis driving mechanism is arranged on a cross beam, the first lifting mechanism comprises two first lifting units which are respectively arranged at two ends of the cross beam, the first lifting mechanism is arranged on a Y-axis driving mechanism, the cross beam is arranged on the first lifting mechanism, the second lifting mechanism is arranged on the X-axis driving mechanism, and the machine head assembly is arranged on the second lifting mechanism. The utility model has the beneficial effects that: the double lifting mechanism is adopted, so that the printing of objects with wider thickness can be adapted, the height of a machine head can be conveniently and accurately adjusted, and the printing effect is improved; the whole driving mechanism is simple and stable, and is convenient to use and adjust.

Description

UV printer capable of adapting to ultra-wide thickness range

Technical Field

The utility model relates to the technical field of UV printers, in particular to a UV printer which can adapt to an ultra-wide thickness range.

Background

The UV printer can be applicable to the printing of timber, metal material, glass, pottery, ya keli board cloth etc. article, and at the during operation, place the article on the print platform of printer, make the aircraft nose remove for the article again, carry out the inkjet through the inkjet head on the aircraft nose to the article and carry out the UV solidification again to realize printing. In order to obtain a good printing effect, an ink jet head of the printer needs to move at a certain range of height relative to the surface of a printed article, and the thickness of the printed article is different, so that a lifting mechanism of a machine head and a moving mechanism of an X axis and a Y axis are required to be driven in the UV printer; while part of upgrade mechanisms of the UV printers can realize lifting movement with a large stroke, the control of the upgrade mechanisms has the problem of insufficient precision, and the use experience is affected.

Accordingly, the prior art has drawbacks and needs improvement.

Disclosure of Invention

The utility model aims to overcome the defects of the prior art and provides a UV printer which can adapt to an ultra-wide thickness range.

The technical scheme of the utility model is as follows: the utility model provides a UV printer which can adapt to an ultra-wide thickness range, comprising: frame, Y axle actuating mechanism, Z axle actuating mechanism, crossbeam, X axle actuating mechanism and aircraft nose subassembly, Y axle actuating mechanism sets up in the frame, Z axle actuating mechanism includes: the X-axis driving mechanism is arranged on the cross beam, the first lifting mechanism comprises two first lifting units which are respectively positioned at two ends of the cross beam, the first lifting mechanism is arranged on the Y-axis driving mechanism, the cross beam is arranged on the first lifting mechanism, the second lifting mechanism is arranged on the X-axis driving mechanism, and the machine head assembly is arranged on the second lifting mechanism;

the first lifting unit includes: the device comprises a first motor, a synchronous wheel, a synchronous belt, a vertical plate, two first sliding rails and a first screw rod, wherein the first motor is arranged on the vertical plate, the first motor is connected with the synchronous wheel through the synchronous belt, the synchronous wheel is coaxially connected with the screw rod, the first sliding rails are arranged on the vertical plate, sliding blocks on the first sliding rails and nuts of the first screw rod are fixed on a first sliding block supporting plate, the first sliding block supporting plate is connected with a frame, and the vertical plate is connected with a cross beam;

the second elevating mechanism includes: the machine head comprises a machine head mounting plate, a first motor, a first screw rod, two first sliding rails and a machine head mounting plate, wherein the first motor is fixed on the machine head mounting plate, the output end of the first motor is connected with the first screw rod, the first sliding rails are arranged on the machine head mounting plate, a sliding block on the first sliding rails and nuts of the first screw rod are fixed on a first sliding block supporting plate, and the first sliding block supporting plate is connected with a cross beam;

the Y-axis driving mechanism comprises: the Y-axis driving unit is arranged on the frame, two sides of the frame are respectively provided with a Y-axis screw rod unit and a Y-axis sliding rail unit, the Y-axis driving unit is connected with the two Y-axis screw rod units through a transmission belt, and nuts of the Y-axis screw rod units are connected with sliding blocks of the corresponding Y-axis sliding rail units;

the X-axis driving mechanism includes: the X-axis synchronous belt device comprises an X-axis driving unit, an X-axis synchronous belt unit and an X-axis sliding rail unit, wherein the X-axis driving unit is arranged on the cross beam, the X-axis driving unit is in transmission connection with a synchronous belt in the X-axis synchronous belt unit, and a sliding block of the X-axis sliding rail unit is connected with a clamping part for clamping the synchronous belt in the X-axis synchronous belt unit.

Further, the first lifting unit further comprises an upper limiter and a lower limiter, the upper limiter and the lower limiter are both arranged on the vertical plate, the upper limiter is close to the upper end of the first sliding rail, and the lower limiter is close to the lower end of the first sliding rail.

Further, the head assembly includes a plurality of inkjet heads.

Further, a mill storage box for storing ink is arranged on the frame.

Further, the UV printing apparatus further includes a drag chain assembly disposed on the cross beam.

By adopting the scheme, the utility model has the beneficial effects that: the double lifting mechanism is adopted, so that the printing of objects with wider thickness can be adapted, the height of a machine head can be conveniently and accurately adjusted, and the printing effect is improved; the whole driving mechanism is simple and stable, and is convenient to use and adjust.

Drawings

Fig. 1 is a schematic structural view of the present utility model.

Fig. 2 is a schematic structural view of the Z-axis driving mechanism of the present utility model.

Fig. 3 is a schematic structural diagram of a first lifting mechanism of the present utility model.

Fig. 4 is a schematic structural view of a second lifting mechanism of the present utility model.

Fig. 5 is a schematic structural view of the Y-axis driving mechanism of the present utility model.

Fig. 6 is a schematic structural view of the X-axis driving mechanism of the present utility model.

Detailed Description

The utility model will be described in detail below with reference to the drawings and the specific embodiments.

Referring to fig. 1 to 6, in the present embodiment, the present utility model provides a UV printing apparatus capable of adapting to an ultra-wide thickness range, comprising: frame 400, Y axle actuating mechanism 500, Z axle actuating mechanism, crossbeam 200, X axle actuating mechanism 600 and aircraft nose subassembly 700, Y axle actuating mechanism 500 sets up on the frame 400, Z axle actuating mechanism includes: the X-axis driving mechanism 600 is arranged on the cross beam 200, the first lifting mechanism 100 comprises two first lifting units respectively arranged at two ends of the cross beam 200, the first lifting mechanism 100 is arranged on the Y-axis driving mechanism 500, the cross beam 200 is arranged on the first lifting mechanism 100, the second lifting mechanism 300 is arranged on a sliding block of the X-axis driving mechanism 600, and the machine head assembly 700 is arranged on the second lifting mechanism 300.

Specifically, the first lifting mechanism 100 includes two first lifting units respectively located at two ends of the beam 200, and the first lifting units include: the device comprises a first motor 101, a synchronous wheel 102, a synchronous belt 103, a vertical plate 104, two first sliding rails 105 and a first screw rod 106, wherein the first motor 101 is arranged on the vertical plate 104, the first motor 101 is connected with the synchronous wheel 102 through the synchronous belt 103, the synchronous wheel 102 is coaxially connected with the screw rod, the first sliding rails 105 are arranged on the vertical plate 104, sliding blocks on the first sliding rails 105 and nuts of the first screw rod 106 are fixed on a first sliding block supporting plate 107, the first sliding block supporting plate 107 is connected with a Y-axis driving mechanism, and the vertical plate 104 is connected with a cross beam 200.

The second elevating mechanism 300 includes: the machine head comprises a second motor 301, a second screw rod 302, two second sliding rails 303 and a machine head mounting plate 304, wherein the second motor 301 is fixed on the machine head mounting plate 304, the output end of the second motor 301 is connected with the second screw rod 302, the second sliding rails 303 are arranged on the machine head mounting plate 304, a sliding block on the second sliding rails 303 and a nut of the second screw rod 302 are both fixed on a second sliding block supporting plate 305, and the second sliding block supporting plate 305 is connected with an X-axis driving mechanism 600.

Further, the first lifting unit further comprises an upper limiter 109 and a lower limiter 108, wherein the upper limiter 109 and the lower limiter 108 are used for sensing the position of the sliding block of the first sliding rail 105, the upper limiter 109 and the lower limiter 108 are both arranged on the vertical plate 104, the upper limiter 109 is close to the upper end of the first sliding rail 105, and the lower limiter 108 is close to the lower end of the first sliding rail 105. The first lifting unit further comprises a screw rod installation seat, and two ends of the first screw rod 106 are respectively installed on the vertical plate 104 through the screw rod installation seat. The second motor 301 is mounted on the handpiece mounting plate 304 by a motor mounting plate. The second motor 301 is mounted on the handpiece mounting plate 304 by a motor mounting plate.

The Y-axis driving mechanism 500 includes: the Y-axis driving unit 510, two Y-axis screw rod units 520 and two Y-axis sliding rail units 530, wherein the Y-axis driving unit 510 is arranged on the frame 400, two sides of the frame 400 are respectively provided with one Y-axis screw rod unit 520 and one Y-axis sliding rail unit 530, the Y-axis driving unit 510 is connected with the two Y-axis screw rod units 520 through a transmission belt, and nuts of the Y-axis screw rod units 520 are connected with sliding blocks of the corresponding Y-axis sliding rail units 530;

the X-axis driving mechanism 600 includes: the X-axis driving unit 610, the X-axis synchronous belt unit 620 and the X-axis sliding rail unit 620, wherein the X-axis driving unit 610 is arranged on the cross beam 200, the X-axis driving unit 610 is in transmission connection with the synchronous belt in the X-axis synchronous belt unit 620, and the sliding block of the X-axis sliding rail unit 620 is connected with a clamping component for clamping the synchronous belt in the X-axis synchronous belt unit 620.

Further, the head assembly 700 includes a plurality of ink jet heads.

Further, a mill box for storing ink is provided on the frame 400.

Further, the UV printing apparatus further includes a drag chain assembly disposed on the cross beam 200.

Referring to fig. 1 to 6 in combination, when the present embodiment works, the Y-axis driving mechanism 500 implements the Y-axis motion, the X-axis driving mechanism 600 implements the X-axis motion, and the Z-axis driving mechanism implements the Z-axis motion, so as to implement the X-axis, Y-axis, and Z-axis motions of the head assembly 700, and due to the arrangement of the first lifting mechanism 100 and the second lifting mechanism 300, printing with an ultra-wide thickness range may be implemented, and fine adjustment may also be implemented.

In summary, the beneficial effects of the utility model are as follows: the double lifting mechanism is adopted, so that the printing of objects with wider thickness can be adapted, the height of a machine head can be conveniently and accurately adjusted, and the printing effect is improved; the whole driving mechanism is simple and stable, and is convenient to use and adjust.

The foregoing description of the preferred embodiment of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the utility model.

Claims

1. A UV printer adaptable to an ultra-wide thickness range, comprising: frame, Y axle actuating mechanism, Z axle actuating mechanism, crossbeam, X axle actuating mechanism and aircraft nose subassembly, Y axle actuating mechanism sets up in the frame, Z axle actuating mechanism includes: the X-axis driving mechanism is arranged on the cross beam, the first lifting mechanism comprises two first lifting units which are respectively positioned at two ends of the cross beam, the first lifting mechanism is arranged on the Y-axis driving mechanism, the cross beam is arranged on the first lifting mechanism, the second lifting mechanism is arranged on the X-axis driving mechanism, and the machine head assembly is arranged on the second lifting mechanism;

2. The UV printer of claim 1, wherein the first lifting unit further comprises an upper limiter and a lower limiter, the upper limiter and the lower limiter are disposed on the riser, the upper limiter is disposed near an upper end of the first rail, and the lower limiter is disposed near a lower end of the first rail.

3. The UV printer of claim 1 or 2, wherein the head assembly comprises a plurality of inkjet heads.

4. The UV printer of claim 1 or 2, wherein the frame is further provided with a reservoir for storing ink.

5. The UV printer of claim 1 or 2, further comprising a drag chain assembly disposed on the cross beam.