CN215240405U - Water-cooling high-power laser alignment fixture for experiments - Google Patents

Abstract

The utility model discloses a water-cooling high power laser alignment anchor clamps for experiments, it relates to laser alignment anchor clamps technical field. The laser beam collimator is characterized in that a collimator used for collimating and turning input laser is arranged in the fixture body, a reflecting device is arranged on the fixture body on one side of a laser input end of the collimator in a sliding mode, an extinction device and a driving device are arranged on two sides of the reflecting device relatively, and a light path calibration module used for calibrating a light path when the collimator is installed is further arranged on the fixture body. After the technical scheme is adopted, the utility model discloses an this beneficial effect does: through the drive of cylinder, drive reciprocating of mirror seat, realize passing through and the reflection of the light path of input laser, avoided manually operation, avoid producing danger because the too high manually operation of laser power, through setting up water-cooling control temperature, safer and automatic, the output direction of light path can be adjusted, calibrates the adjustment through light path calibration module, more accuracy.

Description

Water-cooling high-power laser alignment fixture for experiments

Technical Field

The utility model relates to a laser alignment anchor clamps technical field, concretely relates to experiment water-cooling high power laser alignment anchor clamps.

Background

Laser is another important invention of human beings after nuclear power, computers and semiconductors in 20 th century, and is called as "fastest knife", "best-line ruler" and "brightest light". The english name light amplification by modulated Emission of Radiation means "light amplification by Stimulated Emission". The english full name of the laser has fully expressed the main process of making the laser. The principle of laser light was discovered by the famous jewish physicist einstein as early as 1916.

The atoms are stimulated to emit light, hence the name "laser": when the electrons in the atoms absorb energy and then jump from a low energy level to a high energy level and then fall back from the high energy level to the low energy level, the released energy is released in the form of photons. The induced (excited) photon beam (laser) has highly uniform photon optical characteristics. Therefore, compared with a common light source, the laser has good monochromaticity and directivity and higher brightness.

The laser is widely applied, and comprises laser marking, laser welding, laser cutting, optical fiber communication, laser ranging, laser radar, laser weapons, laser records, laser correction of vision, laser cosmetology, laser scanning, laser mosquito killer, LIF nondestructive testing technology and the like. Laser systems can be divided into continuous wave lasers and pulsed lasers.

In the experimental process, the laser is generally required to be subjected to collimation and turning, when the high-power laser is reflected for 90 degrees, certain danger exists in manual operation due to high laser power, certain danger exists in the conventional experiment through manual operation, a clamp capable of avoiding manual operation is required,

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to prior art's defect and not enough, provide a water-cooling high power laser alignment anchor clamps for experiments, can be through the drive of cylinder, drive reciprocating of microscope base, realize passing through and the reflection of the light path of input laser, avoided manual operation, avoid producing danger because the too high manual operation of laser power, through setting up water-cooling control temperature, it is safer and automatic more, the output direction of light path can be adjusted, calibrate the adjustment through light path calibration module, more accuracy.

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

the utility model provides a water-cooling high power laser collimation anchor clamps for experiments, it includes the anchor clamps main part, be provided with in the anchor clamps main part and be used for carrying out the collimative collimator of turning to input laser, be located it is provided with reflect meter to slide on the anchor clamps main part of collimator laser input one side, reflect meter's both sides are provided with extinction ware, drive arrangement relatively, drive arrangement is used for providing gliding power for reflect meter, absorb in will inputting laser reflection to the extinction ware when reflect meter is located the initial position, input laser jets into the collimator when reflect meter is located the operating position, still be provided with the light path calibration module that is used for the collimator calibration light path when installing in the anchor clamps main part.

The further improvement is that: the reflecting device comprises a mirror base, wherein a first reflecting lens and a second reflecting lens are arranged on the mirror base; the first reflection lens is used for reflecting the input laser into the optical extinction device when the lens base is located at the initial position; the second reflector is used for reflecting the laser emitted by the light path calibration module to the collimator for calibration

The further improvement is that: the driving device is an air cylinder which is fixedly arranged at the upper end of the clamp main body, the telescopic end at the lower end of the air cylinder is connected with the microscope base, the extinction device is arranged on the clamp main body below the microscope base, and the collimator is arranged on the clamp main body at the front end of the microscope base; the light path calibration module is arranged on the outer side wall of the clamp body on the right side of the microscope base.

The further improvement is that: the fixture main body comprises a bottom plate and a support frame vertically arranged on the upper surface of the bottom plate in the vertical direction, the support frame comprises a first vertical support plate and a second vertical support plate, and the first vertical support plate and the second vertical support plate are perpendicular to each other.

The further improvement is that: the microscope base slides on the second vertical support plate from top to bottom through the sliding assembly, the sliding assembly comprises a connecting plate, a sliding block and a sliding rail, the left end face lower part of the connecting plate is being fixedly connected to the right end face of the microscope base, the telescopic end of the cylinder is being fixedly connected to the upper part of the connecting plate, the sliding block is being connected to the right end face of the connecting plate, the sliding rail is fixed on the second vertical support plate, and the sliding block is arranged on the sliding rail in a sliding mode.

The further improvement is that: the collimator is a water-cooling collimator; the delusters are water-cooling delusters.

The further improvement is that: and a reinforcing plate is connected between the first vertical supporting plate and the second vertical supporting plate.

The further improvement is that: and the first vertical supporting plate is provided with a through hole corresponding to the laser input end of the collimator.

The further improvement is that: the cylinder is controlled by a solenoid valve.

After adopting above-mentioned technical scheme, compare in prior art and have following beneficial effect: through the drive of cylinder, drive reciprocating of mirror seat, realize passing through and the reflection of the light path of input laser, avoided manually operation, avoid producing danger because the too high manually operation of laser power, through setting up water-cooling control temperature, safer and automatic, the output direction of light path can be adjusted, calibrates the adjustment through light path calibration module, more accuracy.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without inventive exercise.

Fig. 1 is a schematic structural diagram of the present invention;

fig. 2 is a schematic diagram of the position structure of the middle collimator 1, the optical path calibration module 3, and the lens holder 4 of the present invention.

Description of reference numerals: the device comprises a collimator 1, an extinction device 2, a light path calibration module 3, a reflecting device 4, a driving device 5, a bottom plate 6, a supporting frame 7, a connecting plate 41, a sliding block 42, a sliding rail 43, a first vertical supporting plate 71, a second vertical supporting plate 72, a through hole 73 and a reinforcing plate 74.

Detailed Description

Referring to fig. 1 to 2, the technical solution adopted by the present embodiment is: the utility model provides a water-cooling high power laser collimation anchor clamps for experiments, it includes the anchor clamps main part, be provided with in the anchor clamps main part and be used for carrying out the collimative collimator 1 that turns to the input laser, be located it is provided with reflect meter 4 to slide in the anchor clamps main part of 1 laser input end one side of collimator, reflect meter 4's both sides are provided with extinction ware 2, drive arrangement 5 relatively, drive arrangement 5 is used for providing gliding power for reflect meter 4, reflect meter 2 in with the input laser when reflect meter 4 is located the initial position and absorb, input laser jets into collimator 1 when reflect meter 4 is located the operating position, still be provided with the light path calibration module 3 that is used for calibration light path when collimator 1 installs in the anchor clamps main part.

The reflecting device 4 comprises a mirror base, and a first reflecting mirror and a second reflecting mirror are arranged on the mirror base; the first reflection lens is used for reflecting the input laser into the optical extinction device 2 when the lens base is located at the initial position; the second reflector is used for reflecting the laser emitted by the light path calibration module 3 to the collimator 1 for calibration

The driving device 5 is an air cylinder which is fixedly arranged at the upper end of the clamp main body, the telescopic end of the lower end of the air cylinder is connected with the microscope base, the light eliminator 2 is arranged on the clamp main body below the microscope base, and the collimator 1 is arranged on the clamp main body at the front end of the microscope base; and the light path calibration module 3 is arranged on the outer side wall of the clamp body on the right side of the microscope base.

The clamp body comprises a bottom plate 6 and a support frame 7 vertically arranged on the upper surface of the bottom plate 6 in the vertical direction, wherein the support frame 7 comprises a first vertical support plate 71 and a second vertical support plate 72, and the first vertical support plate 71 and the second vertical support plate 72 are arranged perpendicular to each other.

The microscope base slides up and down on the second vertical support plate 72 through the sliding assembly, the sliding assembly comprises a connecting plate 41, a sliding block 42 and a sliding rail 43, the right end face of the microscope base is fixedly connected with the lower portion of the left end face of the connecting plate 41, the upper portion of the connecting plate 41 is fixedly connected with the telescopic end of the air cylinder, the right end face of the connecting plate 41 is connected with the sliding block 42, the sliding rail 43 is fixed on the second vertical support plate 72, and the sliding block 42 is arranged on the sliding rail 43 in a sliding mode.

Wherein, the collimator 1 is a water-cooling collimator; the delusters 2 are water-cooling delusters. The water-cooled collimator and the water-cooled deluster can control the temperature under high-power laser, and are safer.

Wherein a reinforcing plate 74 is connected between the first vertical support plate 71 and the second vertical support plate 72. The reinforcing plate 74 is provided to form a triangle between the first vertical support plate 71 and the second vertical support plate 72, because the triangle has stability, the support frame 7 of the whole clamp body is more stable.

Wherein, the first vertical support plate 71 is provided with a through hole 73 corresponding to the laser input end.

Wherein the cylinder is controlled by a solenoid valve.

Wherein, the collimator 1 is a 90-degree laser collimation deflector.

The collimator 1 is a conventional laser collimation deflector capable of adjusting the laser deflection direction up, down, left and right.

The utility model discloses a theory of operation: before use, a proper collimator is installed, a beam of laser is emitted to the mirror base through the light path calibration module during installation, the laser is reflected to the collimator through the mirror base, and then the collimator is calibrated and adjusted; when the laser extinction device is used, input laser is emitted from the through hole, the air cylinder is controlled by the electromagnetic valve, when the air cylinder is at an initial position, the mirror base is positioned at the through hole, the input laser is reflected to the extinction device by the mirror base, and the laser reflected by the mirror base is absorbed; when the electromagnetic valve controls the cylinder to move, the cylinder drives the lens base to move downwards, the lens base moves to the lower part of the through hole, the lens base is positioned below the central point of the input laser, and the laser irradiates the collimator to perform collimation turning; through the motion of solenoid valve control cylinder, drive reciprocating of microscope base, realize the light path of input laser and pass through and the reflection, avoided manually operation, avoid producing danger because the too high manually operation of laser power, through setting up water-cooling control temperature, the output direction of light path can be adjusted, only needs the position of adjustment collimator to rethread light path calibration module calibrates the adjustment, more accuracy.

Having shown and described the basic principles and essential features of the invention and its advantages, it will be understood by those skilled in the art that the present invention is not limited by the embodiments described above, which are merely illustrative of the principles of the invention, but is susceptible to various changes and modifications without departing from the spirit and scope of the invention, all of which are intended to be covered by the appended claims and their equivalents. The details of the present invention are well known to those skilled in the art.

Claims (9)

1. The utility model provides a water-cooling high power laser alignment anchor clamps for experiments, it includes the anchor clamps main part, its characterized in that: be provided with in the anchor clamps main part and be used for carrying out the collineation collimator of turning to input laser, be located it is provided with reflect meter to slide on the anchor clamps main part of collimator laser input one side, reflect meter's both sides are provided with extinction ware, drive arrangement relatively, drive arrangement is used for providing gliding power for reflect meter, absorb in reflecting meter with input laser reflection when being located initial position, input laser jets into the collimator when reflect meter is located operating position, still be provided with the light path calibration module that is used for the collimator installation time calibration light path in the anchor clamps main part.

2. The experimental water-cooling high-power laser alignment fixture of claim 1, wherein: the reflecting device comprises a mirror base, wherein a first reflecting lens and a second reflecting lens are arranged on the mirror base; the first reflection lens is used for reflecting the input laser into the optical extinction device when the lens base is located at the initial position; the second reflector is used for reflecting the laser emitted by the light path calibration module to the collimator for calibration.

3. The experimental water-cooling high-power laser alignment fixture of claim 2, wherein: the driving device is an air cylinder which is fixedly arranged at the upper end of the clamp main body, the telescopic end at the lower end of the air cylinder is connected with the microscope base, the extinction device is arranged on the clamp main body below the microscope base, and the collimator is arranged on the clamp main body at the front end of the microscope base; the light path calibration module is arranged on the outer side wall of the clamp body on the right side of the microscope base.

4. The experimental water-cooling high-power laser alignment fixture of claim 3, wherein: the fixture main body comprises a bottom plate and a support frame vertically arranged on the upper surface of the bottom plate in the vertical direction, the support frame comprises a first vertical support plate and a second vertical support plate, and the first vertical support plate and the second vertical support plate are perpendicular to each other.

5. The experimental water-cooling high-power laser alignment fixture of claim 4, wherein: the microscope base slides on the second vertical support plate from top to bottom through the sliding assembly, the sliding assembly comprises a connecting plate, a sliding block and a sliding rail, the left end face lower part of the connecting plate is being fixedly connected to the right end face of the microscope base, the telescopic end of the cylinder is being fixedly connected to the upper part of the connecting plate, the sliding block is being connected to the right end face of the connecting plate, the sliding rail is fixed on the second vertical support plate, and the sliding block is arranged on the sliding rail in a sliding mode.

6. The experimental water-cooling high-power laser alignment fixture of claim 1, wherein: the collimator is a water-cooling collimator; the delusters are water-cooling delusters.

7. The experimental water-cooling high-power laser alignment fixture of claim 4, wherein: and a reinforcing plate is connected between the first vertical supporting plate and the second vertical supporting plate.

8. The experimental water-cooling high-power laser alignment fixture of claim 4, wherein: and the first vertical supporting plate is provided with a through hole corresponding to the laser input end.

9. The experimental water-cooling high-power laser alignment fixture of claim 3, wherein: the cylinder is controlled by a solenoid valve.

Images