CN216981128U - Laser debugging mechanism - Google Patents

Abstract

The utility model provides a laser debugging mechanism, and belongs to the technical field of debugging structures. The laser debugging mechanism comprises a mounting component and a debugging component. The installation component includes the box, the slide, first slider, first retaining member, a slide rail, the second slider, the guide arm, the second retaining member, connecting plate and sealing door, during the use, the rotation of second motor output shaft drives the chain drive spare and rotates, the rotation of chain drive spare drives the connecting axle and rotates, the rotation of connecting axle drives the gear and rotates, the arc rotates under the combined action of gear and internal tooth, adjust the angle between laser instrument body and the box promptly, can be accurate debug the laser instrument body under the combined action of first motor and second motor, this debugging mechanism is convenient for adjust the installation according to the position in the hole of seting up on the coupling mechanism, it is low to the precision of seting up the hole on coupling mechanism, the installation effectiveness to this debugging mechanism has been improved.

Description

Laser debugging mechanism

Technical Field

The utility model relates to the field of debugging structures, in particular to a laser debugging mechanism.

Background

A device in which the laser can emit laser light. According to the working medium, the laser can be divided into four categories, namely gas laser, solid laser, semiconductor laser and dye laser. Free electron lasers have also been developed recently, with high power lasers typically being pulsed outputs.

At present, the existing laser debugging mechanism is inconvenient to adjust according to the position of a hole formed in a connecting mechanism, the precision of the hole formed in the connecting mechanism is high, and the installation efficiency of the debugging mechanism is reduced.

SUMMERY OF THE UTILITY MODEL

In order to make up for the above deficiencies, the utility model provides a laser debugging mechanism, aiming at solving the problems that the adjustment is inconvenient according to the position of a hole formed on a connecting mechanism, the precision of the hole formed on the connecting mechanism is high, and the installation efficiency of the debugging mechanism is reduced.

The utility model is realized by the following steps:

the utility model provides a laser debugging mechanism which comprises a mounting assembly and a debugging assembly.

The installation component includes box, slide, first slider, first retaining member, slide rail, second slider, guide arm, second retaining member, connecting plate and sealing door, the slide is fixed the box is in appearance, first slider slides in the slide, first retaining member screw thread is in the first slider, first retaining member runs through the slide, the slide rail is fixed in the first slider, the second slider slides on the slide rail, the guide arm slides and runs through first slider, the outer wall of guide arm with the outer wall of second slider is fixed together, second retaining member screw thread runs through first slider, the second retaining member with the corresponding setting of guide arm, the end fixing of guide arm is in on the outer wall of connecting plate, sealing door fixes through the hinge page on the box.

The debugging subassembly includes T type post, diaphragm, first fixed block, second fixed block, arc, internal tooth, first motor, laser instrument body, connecting axle, gear, chain drive spare and second motor, T type post is fixed in the inner wall of box, first fixed block with the second fixed block is all fixed on the lower surface of diaphragm, the upper end of T type post is rotated and is set up in first fixed block, the one end of arc is rotated and is set up on the second fixed block, the internal tooth is fixed in the arc, the tip of connecting axle is rotated and is set up in the inner wall of box, the gear is fixed on the outer wall of connecting axle, gear and internal tooth meshing, the second motor is fixed on the outer wall of T type post, the output shaft of second motor with the connecting axle passes through the chain drive spare transmission links together, the first motor is fixed on the upper surface of the transverse plate, and the upper end of an output shaft of the first motor is fixed on the lower surface of the laser body.

In an embodiment of the present invention, the first slider has a threaded groove, and the first locking member is threaded in the threaded groove.

In an embodiment of the present invention, the sliding plate has a through hole, and the first locking member penetrates through the through hole.

In an embodiment of the present invention, at least three second sliding blocks are disposed on the sliding rail, and the second sliding blocks are disposed on the sliding rail at equal intervals.

In an embodiment of the present invention, a groove is formed on the first sliding block, and the sliding rail is fixed in the groove.

In an embodiment of the present invention, the mounting assembly further includes a guide sleeve, the guide sleeve is fixed in the first sliding block, and the guide rod slidably penetrates through the guide sleeve.

In an embodiment of the present invention, the connecting plate includes a connecting plate body, and the connecting plate body is provided with a mounting hole.

In one embodiment of the present invention, the sealing door includes a sealing door body fixed to the box body by a hinge, and a first handle fixed to an outer wall of the sealing door body.

In an embodiment of the present invention, the chain transmission member includes a driven wheel, a chain, and a driving wheel, the driven wheel is fixed on the connecting shaft, the driving wheel is fixed on the output shaft of the second motor, and the driven wheel and the driving wheel are connected together through the chain transmission.

In one embodiment of the utility model, the mounting assembly further comprises a second hand-held portion fixed to an outer wall of the housing.

The utility model has the beneficial effects that: the utility model obtains a laser debugging mechanism through the design, when in use, the first slide block is moved according to the position of a hole arranged on a connecting mechanism connected with the debugging mechanism, the position of the first slide block in the slide plate is controlled, namely, the position of the connecting plate is adjusted, the first slide block is held, the first locking piece is rotated, the neck of the first locking piece extrudes the outer wall of the slide plate to ensure that the first slide block is fixed in the slide plate, then the guide rod is pulled to control the position of the end part of the guide rod in the first slide block, the guide rod is held, the second locking piece is rotated, the end part of the second locking piece extrudes the outer wall of the guide rod to ensure that the guide rod is fixed in the first slide block, thus the transverse position of the connecting plate can be adjusted, the hole on the connecting plate is matched with the hole on the connecting mechanism under the adjustment of the steps, finally, the connecting plate is fixed with the connecting mechanism by utilizing a bolt, when needs debug the laser body, the rotation of first motor output shaft drives the laser body and rotates, the rotation of second motor output shaft drives the chain drive spare and rotates, the rotation of chain drive spare drives the connecting axle and rotates, the rotation of connecting axle drives the gear and rotates, the arc rotates under the combined action of gear and internal tooth, adjust the angle between laser body and the box promptly, can be accurate debug the laser body under the combined action of first motor and second motor, this debugging mechanism is convenient for adjust the installation according to the position in the hole of seting up on the coupling mechanism, the precision to the hole of seting up on the coupling mechanism is low, the installation effectiveness to this debugging mechanism has been improved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

Fig. 1 is a schematic structural diagram of a laser debugging mechanism according to an embodiment of the present invention;

fig. 2 is a schematic cross-sectional structure diagram of a laser debugging mechanism according to an embodiment of the present invention;

FIG. 3 is a schematic cross-sectional view of a mounting assembly according to an embodiment of the present invention;

FIG. 4 is an enlarged view of area A of FIG. 3 according to an embodiment of the present invention;

FIG. 5 is a schematic cross-sectional view of a debugging component according to an embodiment of the present invention;

fig. 6 is an enlarged view of the area B in fig. 5 according to an embodiment of the present invention.

In the figure: 100-mounting the assembly; 110-a box body; 120-a slide plate; 130-a first slider; 140-thread groove; 150-a first locking member; 160-a via; 170-a slide rail; 180-a second slider; 190-guide bar; 191-a groove; 192-a second locking member; 193-guide sleeve; 194-connecting plate; 1941-a web body; 1942-mounting holes; 195-a sealing door; 1951-sealing the door body; 1952-first handle; 196-a second handle; 200-debugging the component; 210-T shaped column; 220-a transverse plate; 230-a first fixed block; 240-second fixed block; 250-arc plate; 260-internal teeth; 270-a first motor; 280-a laser body; 290-a connecting shaft; 291-gear; 292-a chain drive; 2921-driven wheel; 2922-chain; 2923-driving wheel; 293-second electric machine.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present invention. All other embodiments, which can be obtained by a person skilled in the art without inventive efforts based on the embodiments of the present invention, are within the scope of protection of the present invention.

Examples

Referring to fig. 1-6, the present invention provides a technical solution: a laser commissioning mechanism includes a mounting assembly 100 and a commissioning assembly 200. The debugging component 200 is fixed on the mounting component 100, the debugging mechanism is convenient to adjust and mount according to the position of the hole formed in the connecting mechanism, the precision of the hole formed in the connecting mechanism is low, and the mounting efficiency of the debugging mechanism is improved.

Referring to fig. 1-4, the mounting assembly 100 includes a box body 110, a sliding plate 120, a first sliding block 130, a first locking member 150, a sliding rail 170, a second sliding block 180, a guide rod 190, a second locking member 192, a connecting plate 194, and a sealing door 195, the sliding plate 120 is fixed on the outer surface of the box body 110 by bolts, the first sliding block 130 slides in the sliding plate 120, the first locking member 150 is threaded in the first sliding block 130, a threaded groove 140 is formed in the first sliding block 130, the first locking member 150 is threaded in the threaded groove 140, the threaded groove 140 facilitates the first locking member 150 to be threaded in the first sliding block 130, the first locking member 150 penetrates through the sliding plate 120, a through hole 160 is formed in the sliding plate 120, the first locking member 150 penetrates through the through hole 160, the through hole 160 facilitates the first locking member 150 to move on the sliding plate 120, and both the first locking member 150 and the second locking member 192 in this embodiment are bolts.

The sliding rail 170 is fixed in the first sliding block 130 through a bolt, the first sliding block 130 is provided with a groove 191, the sliding rail 170 is fixed in the groove 191 through a bolt, the groove 191 facilitates installation and fixation of the sliding rail 170 in the first sliding block 130, the second sliding block 180 slides on the sliding rail 170, the guide rod 190 slides and penetrates through the first sliding block 130, the installation assembly 100 further comprises guide sleeves 193, the guide sleeves 193 are welded in the first sliding block 130, the guide rods 190 slide and penetrate through the guide sleeves 193, the guide sleeves 193 are convenient for insertion of the guide rods 190 into the first sliding block 130, the outer walls of the guide rods 190 and the outer walls of the second sliding block 180 are fixed together through a bolt, at least three second sliding blocks 180 are arranged on the sliding rail 170, the second sliding blocks 180 are arranged on the sliding rail 170 at equal intervals, the guide rods 190 can be more stably moved in the first sliding block 130 through the plurality of second sliding blocks 180, the second locking member 192 penetrates through the first sliding block 130, the second locking member 192 and the guide rods 190 are correspondingly arranged, the end of the guide rod 190 is fixed on the outer wall of the connecting plate 194 through the bolt, the connecting plate 194 comprises a connecting plate body 1941, a mounting hole 1942 is formed in the connecting plate body 1941, and the mounting hole 1942 is convenient for mounting and fixing the connecting plate body 1941.

The sealing door 195 is fixed on the box body 110 through hinges, the sealing door 195 comprises a sealing door body 1951 and a first handheld portion 1952, the sealing door body 1951 is fixed on the box body 110 through hinges, the first handheld portion 1952 is fixed on the outer wall of the sealing door body 1951 through bolts, the first handheld portion 1952 facilitates installation and fixation of the sealing door body 1951, the first handheld portion 1952 in the embodiment is a door handle, the installation assembly 100 further comprises a second handheld portion 196, the second handheld portion 196 is fixed on the outer wall of the box body 110 through bolts, the second handheld portion 196 facilitates carrying of the debugging mechanism, and the second handheld portion 196 in the embodiment is a handle.

Referring to fig. 2, 5 and 6, the debugging assembly 200 includes a T-shaped pillar 210, a transverse plate 220, a first fixing block 230, a second fixing block 240, an arc plate 250, internal teeth 260, a first motor 270, a laser body 280, a connecting shaft 290, a gear 291, a chain transmission member 292 and a second motor 293, the T-shaped pillar 210 is fixed in the inner wall of the box body 110 by bolts, the first fixing block 230 and the second fixing block 240 are both fixed on the lower surface of the transverse plate 220 by bolts, the upper end of the T-shaped pillar 210 is rotatably disposed in the first fixing block 230, one end of the arc plate 250 is rotatably disposed on the second fixing block 240, the internal teeth 260 are welded in the arc plate 250, the end of the connecting shaft 290 is rotatably disposed in the inner wall of the box body 110, and the gear 291 is welded on the outer wall of the connecting shaft 290.

The gear 291 is meshed with the internal gear 260, the second motor 293 is fixed on the outer wall of the T-shaped column 210 through a bolt, the output shaft of the second motor 293 is in transmission connection with the connecting shaft 290 through a chain transmission member 292, the chain transmission member 292 comprises a driven wheel 2921, a chain 2922 and a driving wheel 2923, the driven wheel 2921 is welded on the connecting shaft 290, the driving wheel 2923 is welded on the output shaft of the second motor 293, the driven wheel 2921 and the driving wheel 2923 are in transmission connection with each other through the chain 2922, the driven wheel 2921, the chain 2922 and the driving wheel 2923 enable the output shaft of the second motor 293 and the connecting shaft 290 to synchronously rotate, the first motor 270 is fixed on the upper surface of the transverse plate 220 through the bolt, and the upper end of the output shaft of the first motor 270 is fixed on the lower surface of the laser body 280 through the bolt.

Specifically, the working principle of the laser debugging mechanism is as follows: when in use, according to the position of the hole opened on the connecting mechanism connected with the debugging mechanism, the first slider 130 is moved, the position of the first slider 130 in the sliding plate 120 is controlled, namely the position of the connecting plate 194 is adjusted, the first slider 130 is held, the first locking member 150 is rotated, the neck of the first locking member 150 presses the outer wall of the sliding plate 120, so that the first slider 130 is fixed in the sliding plate 120, then the guide rod 190 is pulled, the position of the end part of the guide rod 190 in the first slider 130 is controlled, the guide rod 190 is held, the second locking member 192 is rotated, the end part of the second locking member 192 presses the outer wall of the guide rod 190, so that the guide rod 190 is fixed in the first slider 130, the transverse position of the connecting plate 194 can be adjusted, the hole on the connecting plate 194 corresponds to the hole on the connecting mechanism under the adjustment of the above steps, finally the connecting plate 194 and the connecting mechanism are fixed together by bolts, when the laser body 280 needs to be debugged, the first motor 270, the laser body 280 and the second motor 293 are started, the rotation of the output shaft of the first motor 270 drives the laser body 280 to rotate, the rotation of the output shaft of the second motor 293 drives the chain transmission member 292 to rotate, the rotation of the chain transmission member 292 drives the connecting shaft 290 to rotate, the rotation of the connecting shaft 290 drives the gear 291 to rotate, the arc plate 250 rotates under the combined action of the gear 291 and the inner teeth 260, namely, the angle between the laser body 280 and the box body 110 is adjusted, the laser body 280 can be debugged accurately under the combined action of the first motor 270 and the second motor 293, the debugging mechanism is convenient to adjust and mount according to the position of a hole formed in the connecting mechanism, the accuracy of the hole formed in the connecting mechanism is low, and the mounting efficiency of the debugging mechanism is improved.

It should be noted that the specific model specifications of the first motor 270, the laser body 280, and the second motor 293 need to be determined by type selection according to the actual specification of the device, and the specific type selection calculation method adopts the prior art, so detailed description is omitted.

The power supply of the first motor 270, the laser body 280 and the second motor 293 and the principle thereof will be apparent to those skilled in the art and will not be described in detail herein.

The above is only a preferred embodiment of the present invention, and is not intended to limit the present invention, and various modifications and changes may be made to the present invention by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. A laser debugging mechanism is characterized by comprising

A mounting assembly (100), wherein the mounting assembly (100) comprises a box body (110), a sliding plate (120), a first sliding block (130), a first locking member (150), a sliding rail (170), a second sliding block (180), a guide rod (190), a second locking member (192), a connecting plate (194) and a sealing door (195), the sliding plate (120) is fixed on the outer surface of the box body (110), the first sliding block (130) slides in the sliding plate (120), the first locking member (150) is threaded in the first sliding block (130), the first locking member (150) penetrates through the sliding plate (120), the sliding rail (170) is fixed in the first sliding block (130), the second sliding block (180) slides on the sliding rail (170), the guide rod (190) slides through the first sliding block (130), the outer wall of the guide rod (190) and the outer wall of the second sliding block (180) are fixed together, the second locking piece (192) penetrates through the first sliding block (130) in a threaded mode, the second locking piece (192) and the guide rod (190) are arranged correspondingly, the end portion of the guide rod (190) is fixed to the outer wall of the connecting plate (194), and the sealing door (195) is fixed to the box body (110) through hinges;

the debugging assembly (200) comprises a T-shaped column (210), a transverse plate (220), a first fixed block (230), a second fixed block (240), an arc-shaped plate (250), internal teeth (260), a first motor (270), a laser body (280), a connecting shaft (290), a gear (291), a chain transmission member (292) and a second motor (293), wherein the T-shaped column (210) is fixed in the inner wall of the box body (110), the first fixed block (230) and the second fixed block (240) are both fixed on the lower surface of the transverse plate (220), the upper end of the T-shaped column (210) is rotatably arranged in the first fixed block (230), one end of the arc-shaped plate (250) is rotatably arranged on the second fixed block (240), the internal teeth (260) are fixed in the arc-shaped plate (250), and the end of the connecting shaft (290) is rotatably arranged in the inner wall of the box body (110), the gear (291) is fixed on the outer wall of the connecting shaft (290), the gear (291) is meshed with the internal teeth (260), the second motor (293) is fixed on the outer wall of the T-shaped column (210), the output shaft of the second motor (293) is in transmission connection with the connecting shaft (290) through the chain transmission piece (292), the first motor (270) is fixed on the upper surface of the transverse plate (220), and the upper end of the output shaft of the first motor (270) is fixed on the lower surface of the laser body (280).

2. The laser debugging mechanism according to claim 1, wherein said first slider (130) has a threaded groove (140) formed therein, and said first locking member (150) is threaded into said threaded groove (140).

3. The laser tuning mechanism of claim 1, wherein the slide plate (120) has a through hole (160), and the first locking member (150) extends through the through hole (160).

4. A laser commissioning mechanism according to claim 1 wherein said second sliders (180) are provided in at least three of said sliding rails (170), said second sliders (180) being equidistantly arranged on said sliding rails (170).

5. The laser debugging mechanism according to claim 1, wherein a groove (191) is formed in the first slider (130), and the sliding rail (170) is fixed in the groove (191).

6. A laser tuning mechanism according to claim 1, wherein the mounting assembly (100) further comprises a guide sleeve (193), the guide sleeve (193) being fixed within the first slider (130), the guide rod (190) being slidable through the guide sleeve (193).

7. The laser debugging mechanism of claim 1, wherein the connection plate (194) comprises a connection plate body (1941), and the connection plate body (1941) defines a mounting hole (1942).

8. The laser debugging mechanism according to claim 1, wherein said sealing door (195) comprises a sealing door body (1951) and a first handle (1952), said sealing door body (1951) is fixed to said housing (110) by hinges, and said first handle (1952) is fixed to an outer wall of said sealing door body (1951).

9. The laser debugging mechanism of claim 1, wherein the chain transmission member (292) comprises a driven wheel (2921), a chain (2922) and a driving wheel (2923), the driven wheel (2921) is fixed on the connecting shaft (290), the driving wheel (2923) is fixed on the output shaft of the second motor (293), and the driven wheel (2921) and the driving wheel (2923) are in transmission connection through the chain (2922).

10. A laser commissioning mechanism according to claim 1 wherein said mounting assembly (100) further comprises a second hand-held portion (196), said second hand-held portion (196) being secured to an outer wall of said housing (110).

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