CN210703126U - Laser marking machine - Google Patents

Laser marking machine Download PDF

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Publication number
CN210703126U
CN210703126U CN201921750773.6U CN201921750773U CN210703126U CN 210703126 U CN210703126 U CN 210703126U CN 201921750773 U CN201921750773 U CN 201921750773U CN 210703126 U CN210703126 U CN 210703126U
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CN
China
Prior art keywords
control
radial
axial
rotating
button
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Expired - Fee Related
Application number
CN201921750773.6U
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Chinese (zh)
Inventor
杨海东
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Dandong Huarui Fluid Machinery Manufacturing Co Ltd
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Dandong Huarui Fluid Machinery Manufacturing Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
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Application filed by Dandong Huarui Fluid Machinery Manufacturing Co Ltd filed Critical Dandong Huarui Fluid Machinery Manufacturing Co Ltd
Priority to CN201921750773.6U priority Critical patent/CN210703126U/en
Application granted granted Critical
Publication of CN210703126U publication Critical patent/CN210703126U/en
Expired - Fee Related legal-status Critical Current
Anticipated expiration legal-status Critical

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Abstract

The utility model discloses a laser marking machine, rotate processing carrier device, telescopic laser marking device, support including the biax and observe to enclose fender device and control and bear the mechanism, support to observe to enclose the fender device and locate on the control bears the mechanism, the biax rotates processing carrier device and locates on the control bears the mechanism and locate to support to observe to enclose in the fender device, telescopic laser marking device is located to support to observe to enclose on the fender device top inner wall. The utility model belongs to the technical field of laser marking, specifically indicate a can adapt to different planar processing parts, adopt multiaxis reflection control focus, realized carrying out the operation of laser marking to the arc face, saved unnecessary manual adjustment machined part position, the step of adjustment focus, increased the efficiency of laser marking, easy operation, laser marking machine that production efficiency is high.

Description

Laser marking machine
Technical Field
The utility model belongs to the technical field of laser marking, specifically indicate a laser marking machine.
Background
The laser marking machine is a photoelectric integrated equipment based on laser focusing technology, can mark on the surface of various mechanical parts, electronic components and integrated circuit modules, the laser marking technology is developed rapidly nowadays, various new laser marking machines are developed, the laser marking principle is that a laser instrument emits laser rays, the laser beams are focused on the surface of a processing part after being reflected by a focusing lens, and an ideal marking effect can be achieved only when the surface of the processing part is consistent with the focal position of the laser beams, so most of the marking machines on the market are plane marking, the marking focal point of the marking machine is required to be changed, the prior art method is to manually focus the marking machine, the method is complex in operation, labor-consuming and large in error, only the height of the marking plane can be changed, the arc surface cannot be marked, and the marking focal distance adjustment operation is needed to be simple and rapid, can carry out the laser marking machine of processing to the arc face.
SUMMERY OF THE UTILITY MODEL
For solving the above-mentioned current difficult problem, the utility model provides a laser marking machine adopts the mode of all-round rotation machined part to realize beating the effect of beating the mark to the arc face, and easy operation is swift, labour saving and time saving.
The utility model adopts the following technical scheme: the utility model relates to a laser marking machine, including biax rotation processing carrier device, telescopic laser marking device, support and observe enclosing and keep off device and control bearing mechanism, support and observe enclosing and keep off the device and locate on the control bearing mechanism, biax rotation processing carrier device locates on the control bearing mechanism and locates and support and observe enclosing and keep off in the device, telescopic laser marking device locates and supports and observe enclosing and keep off on the inner wall of device top; the double-shaft rotating processing carrier device comprises an axial rotating motor, an axial rotating control plate, a radial rotating motor, a radial rotating control shaft, a radial rotating control plate, a processing platform and a support plate, wherein the support plate is arranged at the top of the control bearing mechanism, the axial rotating motor is arranged on the inner side wall of the supporting and observing enclosure device, the axial rotating control plate is rotatably arranged on the support plate, the support plate plays a supporting and limiting role on the axial rotating control plate, one end of the axial rotating control plate is connected with an output shaft of the axial rotating motor, the axial rotating motor plays a driving role on the axial rotating control plate, the axial rotating control plate is of a square-shaped structure and is internally provided with a radial rotating groove, the radial rotating motor is arranged on the outer side wall of the axial rotating control plate, the radial rotating control shaft is rotatably arranged in the axial rotating control plate in a, the radial rotation control shaft is connected with an output shaft of the radial rotation motor, the radial rotation motor drives the radial rotation control shaft, the radial rotation control plate can be rotatably arranged in a radial rotation groove and connected with the radial rotation control shaft, the radial rotation control shaft drives the radial rotation control plate to support, the axial rotation control plate supports the radial rotation control plate to limit, the processing platform is arranged on the radial rotation control plate, and the processing platform realizes different angle deflection of the processed workpiece under the driving of the radial rotation control plate and the axial rotation control plate.
Furthermore, the telescopic double-reflection laser marking device comprises a telescopic positioning piece, a laser resonator, a focusing lens and a light-emitting control resonator box, wherein the telescopic positioning piece is arranged on the inner wall of the top of the supporting and observing enclosure device, the laser resonator is arranged on the telescopic positioning piece, the telescopic positioning piece supports and drives the laser resonator, the light-emitting control resonator box is arranged on the laser resonator and is arranged right below the laser resonator, the laser resonator supports the light-emitting control resonator box, and the focusing lens is arranged on the light-emitting control resonator box and is arranged at a light-emitting opening of the laser resonator; the light-emitting control vibrating mirror box comprises a vibrating mirror supporting box body, an axial reflection control motor, a radial reflection control motor, an axial reflection control shaft, a radial reflection control shaft, an axial rotation lens, a radial rotation lens and a light-emitting mirror, the vibrating mirror supporting box body is arranged on the laser resonator, a light inlet is formed in the vibrating mirror supporting box body, the focus lens is arranged in the light inlet, the axial reflection control motor is arranged on the inner side wall of the vibrating mirror supporting box body, the radial reflection control motor is arranged on the side wall in the vibrating mirror supporting box body, which is vertical to the side wall where the axial reflection control motor is arranged, the axial reflection control shaft is connected with the output shaft of the axial reflection control motor, the radial reflection control shaft is connected with the output shaft of the radial reflection control motor, the axial reflection control shaft is vertical to the radial reflection control shaft, and the axial rotation lens is arranged on the axial reflection control, radial rotating lens is located on the radial reflection control axle, and axial reflection control motor plays the drive effect to axial rotating lens, and radial reflection control motor plays the drive effect to radial rotating lens, the mirror support bottom half that shakes is located to the light-emitting mirror.
Further, the control bears the mechanism including bearing workstation, control cabinet, truckle and quick-witted case radiator fan, the control cabinet diapire is located to the truckle, and the truckle plays the removal effect to the control cabinet, on bearing workstation located the control cabinet, bearing workstation rotated processing carrier device, telescopic laser marking device and support to the biax and observed to enclose fender device and play the supporting role, quick-witted case radiator fan locates on the control cabinet lateral wall, and quick-witted case radiator fan can cool down to control cabinet inside.
Further, support to observe and enclose fender device and include baffle and perspective board, the baffle is located and is born the weight of on the workstation, the perspective board is located on the baffle and is located baffle dead ahead, and the perspective board material can be plastics, coloured glass, and preferably, the perspective board chooses coloured glass for use as the material, and preferably coloured glass colour is brown, and the perspective board can let the worker observe the inside operating condition of baffle.
Further, a power button, an emission button, a stop button, a descending button, an ascending button, a shaft rotation button, a radial rotation button, a shaft reflection button and a radial reflection button are arranged on the bearing workbench, the power button, the emission button, the stop button, the descending button, the ascending button, the shaft rotation button, the radial rotation button, the shaft reflection button and the radial reflection button are electrically connected with the control cabinet, the control cabinet is electrically connected with the axial rotation motor, the radial rotation motor, the axial reflection control motor, the radial reflection control motor, the telescopic positioning piece and the laser resonator, the power button controls the power switch of the whole machine, the emission button and the stop button control the working state of the laser resonator, the descending button and the ascending button control the working state of the telescopic positioning piece, the shaft rotation button controls the working state of the axial rotation motor, and the radial rotation button controls the working state of the radial rotation motor, the shaft reflection button controls the working state of the axial reflection control motor, and the radial reflection button controls the working state of the radial reflection control motor.
Further, the control cabinet control system can adopt a PLC controller, a CPU and a single chip microcomputer, and preferably, the control cabinet control system adopts the PLC controller.
Adopt above-mentioned structure the utility model discloses the beneficial effect who gains as follows: this scheme laser marking machine has overcome the shortcoming that laser marking machine can not work to the arc face on the market, adopts the mode of multiaxis joint operation to realize the laser focusing to the arc face, can mark the processing to the mark machined part of beating of different shapes, uses general degree of usefulness height, need not manual fixed burnt and adjustment work piece position, has saved numerous and diverse operating procedure, has saved the adjustment time, has improved machining efficiency.
Drawings
FIG. 1 is a schematic view of the overall structure of a laser marking machine of the present invention;
FIG. 2 is an enlarged view of a portion A of FIG. 1;
FIG. 3 is a front view of a laser marking machine of the present invention;
fig. 4 is a schematic structural view of the mirror box for controlling light-emitting of the laser marking machine.
Wherein, 1, a double-shaft rotation processing carrier device, 2, a telescopic double-reflection laser marking device, 3, a supporting observation enclosure device, 4, a control bearing mechanism, 5, an axial rotating motor, 6, an axial rotating control plate, 7, a radial rotating motor, 8, a radial rotating control shaft, 9, a radial rotating control plate, 10, a processing platform, 11, a support plate, 12, a radial rotating groove, 13, a telescopic positioning piece, 14, a laser resonator, 15, a focusing lens, 16, a light-emitting control vibrating mirror box, 17, a vibrating mirror supporting box body, 18, an axial reflection control motor, 19, a radial reflection control motor, 20, an axial reflection control shaft, 21, a radial reflection control shaft, 22, an axial rotating lens, 23, a radial rotating lens, 24, a light-emitting mirror, 25, a light-in port, 26, a bearing workbench, 27, a control cabinet, 28, a truckle, 29 and a cabinet heat-radiating fan, 30. apron board 31, perspective board 32, power button 33, launch button 34, stop button 35, down button 36, up button 37, axis turn button 38, radial turn button 39, axis reflection button 40, radial reflection button.
Detailed Description
The technical solution of the present invention will be described in further detail with reference to specific embodiments, and all the parts of the present invention not described in detail in the technical features or the connection relation are the prior art.
The present invention will be described in further detail with reference to the accompanying drawings.
As shown in fig. 1-4, the utility model relates to a laser marking machine, which comprises a double-shaft rotating processing carrier device 1, a telescopic double-reflection laser marking device 2, a supporting and observing enclosure device 3 and a control bearing mechanism 4, wherein the supporting and observing enclosure device 3 is arranged on the control bearing mechanism 4, the double-shaft rotating processing carrier device 1 is arranged on the control bearing mechanism 4 and is arranged in the supporting and observing enclosure device 3, and the telescopic double-reflection laser marking device 2 is arranged on the inner wall of the top of the supporting and observing enclosure device 3; the double-shaft rotating processing carrier device 1 comprises an axial rotating motor 5, an axial rotating control plate 6, a radial rotating motor 7, a radial rotating control shaft 8, a radial rotating control plate 9, a processing platform 10 and a support plate 11, wherein the support plate 11 is arranged at the top of a control bearing mechanism 4, the axial rotating motor 5 is arranged on the inner side wall of a supporting observation enclosure device 3, the axial rotating control plate 6 is rotatably arranged on the support plate 11, one end of the axial rotating control plate 6 is connected with an output shaft of the axial rotating motor 5, the axial rotating control plate 6 is of a square-shaped structure and is internally provided with a radial rotating groove 12, the radial rotating motor 7 is arranged on the outer side wall of the axial rotating control plate 6, the radial rotating control shaft 8 is rotatably arranged in the axial rotating control plate 6 in a penetrating way, and the radial rotating control shaft 8 is connected with, the radial rotating control plate 9 can be rotatably arranged in the radial rotating groove 12 and is connected with the radial rotating control shaft 8, and the processing platform 10 is arranged on the radial rotating control plate 9.
The telescopic double-reflection laser marking device 2 comprises a telescopic positioning piece 13, a laser resonator 14, a focusing lens 15 and a light-emitting control vibration mirror box 16, wherein the telescopic positioning piece 13 is arranged on the inner wall of the top of the supporting and observing enclosure device 3, the laser resonator 14 is arranged on the telescopic positioning piece 13, the light-emitting control vibration mirror box 16 is arranged on the laser resonator 14 and is arranged right below the laser resonator 14, and the focusing lens 15 is arranged on the light-emitting control vibration mirror box 16 and is arranged at a light-emitting port of the laser resonator 14; the light-emitting control vibration mirror box 16 comprises a vibration mirror supporting box body 17, an axial reflection control motor 18, a radial reflection control motor 19, an axial reflection control shaft 20, a radial reflection control shaft 21, an axial rotation lens 22, a radial rotation lens 23 and a light-emitting mirror 24, the vibration mirror supporting box body 17 is arranged below the laser resonator 14, the vibration mirror supporting box body 17 is provided with a light inlet 25, the focus lens 15 is arranged in the light inlet 25, the axial reflection control motor 18 is arranged on the inner side wall of the vibration mirror supporting box body 17, the radial reflection control motor 19 is arranged on the side wall vertical to the side wall where the axial reflection control motor 18 is arranged in the vibration mirror supporting box body 17, the axial reflection control shaft 20 is connected with the output shaft of the axial reflection control motor 18, the radial reflection control shaft 21 is connected with the output shaft of the radial reflection control motor 19, the axial reflection control shaft 20 is vertical to the radial reflection control shaft 21, the axial rotating lens 22 is arranged on the axial reflection control shaft 20, the radial rotating lens 23 is arranged on the radial reflection control shaft 21, and the light-emitting lens 24 is arranged at the bottom of the galvanometer supporting box 17.
The control bearing mechanism 4 comprises a bearing workbench 26, a control cabinet 27, casters 28 and a case cooling fan 29, wherein the casters 28 are arranged on the bottom wall of the control cabinet 27, the bearing workbench 26 is arranged on the control cabinet 27, and the case cooling fan 29 is arranged on the side wall of the control cabinet 27.
The supporting observation enclosure device 3 comprises an enclosure plate 30 and a perspective plate 31, the enclosure plate 30 is arranged on the bearing workbench 26, the perspective plate 31 is arranged on the enclosure plate 30 and is arranged right in front of the enclosure plate 30, and the perspective plate 31 is made of brown colored glass.
The bearing workbench 26 is provided with a power button 32, an emission button 33, a stop button 34, a descending button 35, an ascending button 36, a shaft rotating button 37, a radial rotating button 38, a shaft reflecting button 39 and a radial reflecting button 40, the power button 32, the emission button 33, the stop button 34, the descending button 35, the ascending button 36, the shaft rotating button 37, the radial rotating button 38, the shaft reflecting button 39 and the radial reflecting button 40 are electrically connected with the control cabinet 27, and the control cabinet 27 is electrically connected with the axial rotating motor 5, the radial rotating motor 7, the axial reflecting control motor 18, the radial reflecting control motor 19, the telescopic positioning piece 13 and the laser resonator 14; the control system of the control cabinet 27 adopts a PLC controller.
When the device is used specifically, a workpiece is fixed on a processing platform 10, a power supply button 32 is pressed, the laser marking machine is powered on and started, a transmitting button 33 is pressed, a light beam emitted by a laser resonator 14 is refracted by a focusing lens 15 to become a focused light beam, the focused light beam obliquely emits into an exit light control vibration mirror box 16 from a light inlet 25, the focused light beam is reflected by an angle of an axial rotating lens 22 and a radial rotating lens 23 and then acts on the surface of the workpiece through an exit light mirror 24, a descending button 35, an ascending button 36, a shaft rotating button 37, a radial rotating button 38, a shaft reflecting button 39 and a radial reflecting button 40 can be controlled according to the shape of the workpiece to control a telescopic positioning piece 13, an axial rotating motor 5, a radial rotating motor 7, an axial reflecting control motor 18 and a radial reflecting control motor 19, so that the focused light beam can accurately act on the surface of the workpiece, after the processing is finished, the stop button 34 is pressed, the laser resonator 14 stops emitting the light beam, the processed workpiece is taken out from the processing platform 10, the power button 32 is pressed again, and the laser marking machine is turned off.
The present invention and the embodiments thereof have been described above, but the description is not limited thereto, and the embodiment shown in the drawings is only one of the embodiments of the present invention, and the actual structure is not limited thereto. In summary, those skilled in the art should understand that they should not be limited to the embodiments described above, and that they can design the similar structure and embodiments without departing from the spirit of the invention.

Claims (6)

1. The utility model provides a laser marking machine which characterized in that: the double-shaft rotating processing carrier device is arranged on the control bearing mechanism and is arranged in the supporting observation enclosure device, and the telescopic double-reflection laser marking device is arranged on the inner wall of the top of the supporting observation enclosure device; the double-shaft rotating processing carrier device comprises an axial rotating motor, an axial rotating control plate, a radial rotating motor, a radial rotating control shaft, a radial rotating control plate, a processing platform and a support plate, wherein the support plate is arranged at the top of the control bearing mechanism, the axial rotating motor is arranged on the inner side wall of the supporting and observing enclosure device, the axial rotating control plate is rotatably arranged on the support plate, one end of the axial rotating control plate is connected with an output shaft of the axial rotating motor, the axial rotating control plate is of a square-shaped structure and is internally provided with a radial rotating groove, the radial rotating motor is arranged on the outer side wall of the axial rotating control plate, the radial rotating control shaft is rotatably arranged in the axial rotating control plate in a penetrating way, the radial rotating control shaft is connected with the output shaft of the radial rotating motor, the radial rotating control plate is rotatably, the processing platform is arranged on the radial rotating control plate.
2. The laser marking machine according to claim 1, wherein: the telescopic double-reflection laser marking device comprises a telescopic positioning piece, a laser resonator, a focusing lens and a light-emitting control resonator box, wherein the telescopic positioning piece is arranged on the inner wall of the top of the supporting and observing enclosure device, the laser resonator is arranged on the telescopic positioning piece, the light-emitting control resonator box is arranged on the laser resonator and is arranged right below the laser resonator, and the focusing lens is arranged on the light-emitting control resonator box and is arranged at a light-emitting port of the laser resonator; the light-emitting control vibrating mirror box comprises a vibrating mirror supporting box body, an axial reflection control motor, a radial reflection control motor, an axial reflection control shaft, a radial reflection control shaft, an axial rotation lens, a radial rotation lens and a light-emitting mirror, the vibrating mirror supporting box body is arranged below the laser resonator, a light inlet is formed in the vibrating mirror supporting box body, the focus lens is arranged in the light inlet, the axial reflection control motor is arranged on the inner side wall of the vibrating mirror supporting box body, the radial reflection control motor is arranged on the side wall, perpendicular to the side wall where the axial reflection control motor is arranged, in the vibrating mirror supporting box body, the axial reflection control shaft is connected with an output shaft of the axial reflection control motor, the radial reflection control shaft is connected with an output shaft of the radial reflection control motor, the axial reflection control shaft is perpendicular to the radial reflection control shaft, and the axial rotation lens is arranged on the axial reflection control shaft, the radial rotating lens is arranged on the radial reflection control shaft, and the light-emitting mirror is arranged at the bottom of the vibrating mirror supporting box body.
3. The laser marking machine according to claim 2, wherein: the control bearing mechanism comprises a bearing workbench, a control cabinet, trundles and a case cooling fan, wherein the trundles are arranged on the bottom wall of the control cabinet, the bearing workbench is arranged on the control cabinet, and the case cooling fan is arranged on the side wall of the control cabinet.
4. The laser marking machine according to claim 3, wherein: the supporting observation enclosure device comprises an enclosure plate and a perspective plate, the enclosure plate is arranged on the bearing workbench, the perspective plate is arranged on the enclosure plate and is arranged right in front of the enclosure plate, and brown colored glass is selected as a material for the perspective plate.
5. The laser marking machine according to claim 3, wherein: the bearing workbench is provided with a power button, an emission button, a stop button, a descending button, an ascending button, a shaft rotating button, a radial rotating button, a shaft reflecting button and a radial reflecting button, the power button, the emission button, the stop button, the descending button, the ascending button, the shaft rotating button, the radial rotating button, the shaft reflecting button and the radial reflecting button are electrically connected with the control cabinet, and the control cabinet is electrically connected with the axial rotating motor, the radial rotating motor, the axial reflecting control motor, the radial reflecting control motor, the telescopic positioning piece and the laser resonance instrument.
6. The laser marking machine according to claim 3, wherein: and the control system of the control cabinet adopts a PLC controller.
CN201921750773.6U 2019-10-18 2019-10-18 Laser marking machine Expired - Fee Related CN210703126U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN201921750773.6U CN210703126U (en) 2019-10-18 2019-10-18 Laser marking machine

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN201921750773.6U CN210703126U (en) 2019-10-18 2019-10-18 Laser marking machine

Publications (1)

Publication Number Publication Date
CN210703126U true CN210703126U (en) 2020-06-09

Family

ID=70959515

Family Applications (1)

Application Number Title Priority Date Filing Date
CN201921750773.6U Expired - Fee Related CN210703126U (en) 2019-10-18 2019-10-18 Laser marking machine

Country Status (1)

Country Link
CN (1) CN210703126U (en)

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CF01 Termination of patent right due to non-payment of annual fee
CF01 Termination of patent right due to non-payment of annual fee

Granted publication date: 20200609