CN211966305U - Secondary element microscopic identification and welding integrated machine - Google Patents

Abstract

The utility model discloses a quadratic element microscopic identification welding all-in-one, including frame and laser welding mechanism, the frame top is provided with laser welding mechanism still includes micro-mechanism and slewing mechanism, micro-mechanism sets up the laser welding mechanism outside, slewing mechanism drives laser welding mechanism with micro-mechanism rotates simultaneously. The utility model discloses laser welding mechanism, micro-mechanism and slewing mechanism's setting can guarantee when rotating laser welder head, and the reflector then rotates, has guaranteed the fixed of microscope position, has made things convenient for staff's observation, and the setting of sliding display screen can be according to staff's visual acuity adjusting sliding display screen's position, has reduced the tired degree of staff's glasses, and the setting of treater and sliding display screen, preliminary location that can be quick, convenient observation.

Description

Secondary element microscopic identification and welding integrated machine

Technical Field

The utility model relates to a jewelry processing field especially relates to quadratic element micro-appraisal welding all-in-one.

Background

Laser welding machines, also commonly called laser welding machines and laser welding machines, are machines for processing laser materials, and are divided into laser die welding machines, automatic laser welding machines, laser spot welding machines and optical fiber transmission laser welding machines according to working modes.

In order to solve the problem of reducing the burning risk of the glasses of an operator, the existing Chinese patent with the application publication number of CN110193666.A discloses a laser welding machine, and relates to the technical field of laser welding. The liquid crystal grating microscope is characterized by comprising a rack, a laser transmitter horizontally fixed on the upper side of the rack, a barrel vertically and fixedly arranged at one end of a laser transmitting port of the laser transmitter, and a microscope arranged on the upper side of the barrel, wherein a liquid crystal grating assembly is horizontally arranged in a light source cavity between a reflector and the microscope in the barrel, and the liquid crystal grating assembly is electrically connected with a grating control circuit; the grating control circuit is coupled to a starting switch of the laser transmitter and drives the liquid crystal grating assembly to block light when the starting switch is turned on; when the starting switch is turned off, the liquid crystal grating assembly is driven to conduct light. However, the belt device cannot ensure observation under a stationary condition of the microscope, and requires movement of the eyes of the worker with the movement of the microscope, which tends to cause not only eye fatigue but also physical fatigue of the worker.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a quadratic element microscopic identification welding all-in-one machine for solving the problems.

The utility model discloses a following technical scheme realizes above-mentioned purpose:

the two-dimensional microscopic identification and welding integrated machine comprises a rack and a laser welding mechanism, wherein the laser welding mechanism is arranged above the rack, the two-dimensional microscopic identification and welding integrated machine further comprises a microscopic mechanism and a rotating mechanism, the microscopic mechanism is arranged on the outer side of the laser welding mechanism, and the rotating mechanism drives the laser welding mechanism and the microscopic mechanism to rotate simultaneously.

Preferably, the laser welding mechanism comprises the laser transmitter and a laser welding head, the laser transmitter is connected above the rack through a bolt, the upper part of the laser transmitter is connected with the microscope mechanism, the rotating mechanism is arranged in front of the laser transmitter, and the laser welding head is fixed below the rotating mechanism.

Preferably, the rotating mechanism comprises a rotating seat, a fixed frame, a first gear, a second gear, a rotating shaft, a third gear, a fourth gear, a servo motor and a connecting box, the connecting box is connected in the front of the rack through bolts, one side of the connecting box is connected with the servo motor through bolts, the output end of the servo motor is welded with the rotating shaft, the rotating shaft is connected in the connecting box through a bearing, the outer side of the rotating shaft is connected with the third gear and the fourth gear through keys, the third gear is positioned between the fourth gear, the first gear is meshed with the front lower part of the fourth gear, the second gear is meshed with the front lower part of the third gear, the first gear is fixed on the fixed frame, the second gear is fixed between the rotating seats, and the inner side of the rotating seat is rotatably connected with two fixed frames, the fixed frame is located the second gear outside, the through-hole has been seted up on the fixed frame, it connects to rotate the seat inside the connecting box, the connecting box is connected laser welding mechanism with the micro-mechanism.

Preferably, the first gear is connected with the fixed frame through a pin shaft and a key, the second gear is connected with the rotating seat through a pin shaft and a key, the tooth number of the third gear is the same as that of the fourth gear, and the tooth number of the second gear is half of that of the first gear.

Preferably, the microscopic mechanism comprises a connecting plate, a condenser, a connecting pipe, a reflector, a microscope, a liquid crystal grating assembly, a processor, a sliding display screen and a sliding rail, the connecting plate is connected to the outer side of a laser welding head in the laser welding mechanism through screws, round holes are also arranged at two sides of the connecting plate, the condenser lens is fixed in the round hole, the connecting pipe is welded above the connecting plate, the rotating seat is welded above the connecting pipe, the reflector is fixed in a through hole formed in the fixed frame, the microscope is connected in front of the connecting box through a bolt, the processor is connected in front of the connecting box through a bolt, and is located microscope one side, the treater is connected the slip display screen, slip display screen sliding connection be in the slide rail top, the slide rail passes through bolted connection and is in the laser welding mechanism top.

Preferably, the microscope corresponds to one of the sets of mirrors, and the processor corresponds to the other set of mirrors.

Preferably, the microscope is internally provided with an objective lens with a large microscope, the processor is internally provided with an objective lens with a small microscope, and the microscope is internally provided with the liquid crystal grating assembly.

Has the advantages that: laser welding mechanism, micro-mechanism and slewing mechanism's setting can guarantee when rotating laser welder head, and the reflector then rotates, has guaranteed the fixed of microscope position, has made things convenient for staff's observation, and the setting of sliding display screen can be according to staff's visual adjustment sliding display screen's position, has reduced the tired degree of staff's glasses, and the setting of treater and sliding display screen, preliminary location that can be quick, the convenient observation.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

FIG. 1 is a schematic structural view of the two-dimensional microscopic identification and welding integrated machine of the present invention;

FIG. 2 is a front view of the two-dimensional microscopic identification and welding integrated machine of the present invention;

FIG. 3 is a right side view of the two-dimensional microscopic identification and welding integrated machine of the present invention;

FIG. 4 is a cross-sectional view A-A of the two-dimensional microscopic identification and welding integrated machine of the present invention;

FIG. 5 is a B-B sectional view of the two-dimensional microscopic identification and welding integrated machine of the present invention;

FIG. 6 is the schematic diagram of the internal structure of the connecting box in the quadratic element micro-identification welding all-in-one machine of the present invention.

The reference numerals are explained below:

1. a frame; 2. a laser welding mechanism; 3. a microscopic mechanism; 4. a rotating mechanism; 201. a laser transmitter; 202. a laser welding head; 301. a connecting plate; 302. a condenser lens; 303. a connecting pipe; 304. a reflective mirror; 305. a microscope; 306. a liquid crystal grating assembly; 307. a processor; 308. sliding the display screen; 309. a slide rail; 401. a rotating seat; 402. a fixing frame; 403. a first gear; 404. a second gear; 405. a rotating shaft; 406. a third gear; 407. a fourth gear; 408. a servo motor; 409. and a connecting box.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "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 only for convenience of description and 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.

As shown in fig. 1-6, the two-dimensional microscopic identification and welding integrated machine comprises a machine frame 1 and a laser welding mechanism 2, wherein the laser welding mechanism 2 is arranged above the machine frame 1, the machine frame further comprises a microscopic mechanism 3 and a rotating mechanism 4, the microscopic mechanism 3 is arranged outside the laser welding mechanism 2, and the rotating mechanism 4 drives the laser welding mechanism 2 and the microscopic mechanism 3 to rotate simultaneously.

Preferably, the laser welding mechanism 2 comprises a laser transmitter 201 and a laser welding head 202, the laser transmitter 201 is connected above the rack 1 through bolts, the upper part of the laser transmitter 201 is connected with the microscope mechanism 3, a rotating mechanism 4 is arranged in front of the laser transmitter 201, the laser welding head 202 is fixed below the rotating mechanism 4, the laser welding head 202 can be arranged in such a way, materials can be subjected to laser welding through the laser welding head 202, the rotating mechanism 4 comprises a rotating seat 401, a fixing frame 402, a first gear 403, a second gear 404, a rotating shaft 405, a third gear 406, a fourth gear 407, a servo motor 408 and a connecting box 409, the connecting box 409 is connected in front of the rack 1 through bolts, one side of the connecting box 409 is connected with the servo motor 408 through bolts, the output end of the servo motor 408 is welded with a rotating shaft 405, the rotating shaft 405 is connected inside the connecting box 409 through bearings, the third gear 406 is positioned between the fourth gears 407, the first gear 403 is engaged with the front lower part of the fourth gear 407, the second gear 404 is engaged with the front lower part of the third gear 406, the first gear 403 is fixed on the fixed frame 402, the second gear 404 is fixed between the rotating bases 401, two fixed frames 402 are rotatably connected with the inner side of the rotating bases 401, the fixed frame 402 is positioned at the outer side of the second gear 404, a through hole is formed on the fixed frame 402, the rotating bases 401 are rotatably connected with the inner part of the connecting box 409, the connecting box 409 is connected with the laser welding mechanism 2 and the microscope mechanism 3, the first gear 403 is connected with the fixed frame 402 through a pin shaft and a key, the second gear 404 is connected with the rotating bases 401 through a pin shaft and a key, the number of teeth of the third gear 406 is the same as that of the fourth gear 407, the number of teeth of the second gear 404 is half of that of the first gear 403, so as to set, and then drive the third gear 406 and the fourth gear 407 to rotate, the rotation of the second gear 404 and the first gear 403 is realized, and the angular velocity of the rotation of the first gear 403 is twice as high as the angular velocity of the rotation of the second gear 404, and the angular velocity of the rotation of the fixed frame 402 is half of the angular velocity of the rotation of the rotating base 401, the microscope mechanism 3 includes a connection board 301, a condenser lens 302, a connection pipe 303, a reflective mirror 304, a microscope 305, a liquid crystal grating assembly 306, a processor 307, a sliding display screen 308, and a slide rail 309, the connection board 301 is connected to the outer side of a laser welding head 202 in the laser welding mechanism 2 by screws, round holes are further arranged on both sides of the connection board 301, the condenser lens 302 is fixed in the round holes, the connection pipe 303 is welded on the connection board 301, the rotating base 401 is welded on the connection pipe 303, the reflective mirror 304 is fixed in a through hole formed, the processor 307 is connected in front of the connecting box 409 through a bolt and is positioned on one side of the microscope 305, the processor 307 is connected with the sliding display screen 308, the sliding display screen 308 is connected above the sliding rail 309 in a sliding mode, the sliding rail 309 is connected above the laser welding mechanism 2 through a bolt, the arrangement is carried out in such a way, the situation that the microscope 305 is fixed in position can be guaranteed, each welding position of materials can be seen, the microscope 305 corresponds to one group of reflectors 304, the processor 307 corresponds to the other group of reflectors 304, an objective lens with a large lens is installed in the microscope 305, an objective lens with a small lens is installed in the processor 307, the liquid crystal grating assembly 306 is further installed in the microscope 305, and rapid positioning can be carried out by the.

In the structure, when in use, firstly, materials are placed on the workbench of the machine frame 1, then the laser welding head 202 performs welding on the materials through the work of the laser emitter 201, in the process, an object image can pass through the connecting pipe 303 through the condenser lens 302 and then enters the belt processor 307 through the reflection of the reflector 304, and a smaller magnification factor is projected through the sliding display screen 308, the object image with the larger magnification factor enters the eyes of workers through the microscope 305 and the liquid crystal grating assembly 306 in the microscope 305, when the welding position is adjusted, the servo motor 408 drives the rotating shaft 405 to rotate, further drives the third gear 406 and the fourth gear 407 to rotate, the rotation of the second gear 404 and the first gear 403 is realized through rotation, the angular speed of the second gear 404 is ensured to be twice of the angular speed of the rotation of the first gear 403, and the angular speed of the fixed frame 402 is ensured to be half of the angular speed of the rotation of the rotating base 401, it is realized that observation can be performed without moving the microscope 305.

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the foregoing embodiments and descriptions are provided only to illustrate the principles of the present invention without departing from the spirit and scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (7)

1. Quadratic element micro-appraises welding all-in-one, including frame (1) and laser welding mechanism (2), frame (1) top is provided with laser welding mechanism (2), its characterized in that: still include micro-mechanism (3) and slewing mechanism (4), micro-mechanism (3) set up the laser welding mechanism (2) outside, slewing mechanism (4) drive laser welding mechanism (2) with micro-mechanism (3) rotate simultaneously.

2. The two-dimensional microscopic identification and welding all-in-one machine according to claim 1, characterized in that: the laser welding mechanism (2) comprises a laser transmitter (201) and a laser welding head (202), the laser transmitter (201) is connected to the upper portion of the rack (1) through a bolt, the upper portion of the laser transmitter (201) is connected with the microscope mechanism (3), the rotating mechanism (4) is arranged in front of the laser transmitter (201), and the laser welding head (202) is fixed to the lower portion of the rotating mechanism (4).

3. The two-dimensional microscopic identification and welding all-in-one machine according to claim 2, characterized in that: the rotating mechanism (4) comprises a rotating seat (401), a fixed frame (402), a first gear (403), a second gear (404), a rotating shaft (405), a third gear (406), a fourth gear (407), a servo motor (408) and a connecting box (409), wherein the connecting box (409) is connected to the front of the frame (1) through bolts, one side of the connecting box (409) is connected with the servo motor (408) through bolts, the rotating shaft (405) is welded at the output end of the servo motor (408), the rotating shaft (405) is connected to the inside of the connecting box (409) through a bearing, the third gear (406) and the fourth gear (407) are connected to the outer side key of the rotating shaft (405), the third gear (406) is located between the fourth gears (407), and the first gear (403) is meshed with the front lower part of the fourth gear (407), third gear (406) front lower place meshing has second gear (404), first gear (403) are fixed on fixed frame (402), second gear (404) are fixed rotate between seat (401), it is connected with two to rotate seat (401) inboard rotation fixed frame (402), fixed frame (402) are located the second gear (404) outside, the through-hole has been seted up on fixed frame (402), it connects to rotate seat (401) rotation inside junction box (409), junction box (409) are connected laser welding mechanism (2) with micro-mechanism (3).

4. The two-dimensional microscopic identification and welding all-in-one machine according to claim 3, characterized in that: the first gear (403) is connected with the fixed frame (402) through a pin shaft and a key, the second gear (404) is connected with the rotating seat (401) through a pin shaft and a key, the number of teeth of the third gear (406) is the same as that of teeth of the fourth gear (407), and the number of teeth of the second gear (404) is half of that of the first gear (403).

5. The two-dimensional microscopic identification and welding all-in-one machine according to claim 3, characterized in that: the microscope mechanism (3) comprises a connecting plate (301), a condenser (302), a connecting pipe (303), a reflector (304), a microscope (305), a liquid crystal grating assembly (306), a processor (307), a sliding display screen (308) and a sliding rail (309), wherein the connecting plate (301) is connected to the outer side of a laser welding head (202) in the laser welding mechanism (2) through screws, round holes are further formed in two sides of the connecting plate (301), the condenser (302) is fixed in the round holes, the connecting pipe (303) is welded above the connecting plate (301), the rotating seat (401) is welded above the connecting pipe (303), the reflector (304) is fixed in a through hole formed in the fixing frame (402), the microscope (305) is connected in front of the connecting box (409) through bolts, and the processor (307) is connected in front of the connecting box (409) through bolts, and is located microscope (305) one side, processor (307) connect sliding display screen (308), sliding display screen (308) sliding connection in slide rail (309) top, slide rail (309) pass through bolted connection in laser welding mechanism (2) top.

6. The two-dimensional microscopic identification and welding all-in-one machine according to claim 5, characterized in that: the microscope (305) corresponds to one of the sets of mirrors (304) and the processor (307) corresponds to the other set of mirrors (304).

7. The two-dimensional microscopic identification and welding all-in-one machine according to claim 5, characterized in that: an objective lens with a large lens is arranged in the microscope (305), an objective lens with a small lens is arranged in the processor (307), and the liquid crystal grating assembly (306) is further arranged in the microscope (305).

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