CN216116675U - Laser detection device - Google Patents

Abstract

The application discloses a laser detection device which comprises a support, a laser power meter probe and an output optical cable adjusting structure, wherein the laser power meter probe is arranged on the support; the output optical cable adjusting structure comprises an adjusting component and an output optical cable joint, the output optical cable joint is opposite to the laser power meter probe, the adjusting component is installed on the support and connected with the output optical cable joint so as to adjust the position of the output optical cable joint. This application embodiment adjusts the position of structure in order to adjust output optical cable joint through setting up output optical cable on the support, after the output optical cable with the laser and output optical cable articulate, adjust the position of output optical cable joint through adjusting part, can adjust the position of the output optical cable of laser to make accurate the shining of laser that the laser produced laser to laser power meter probe, avoid laser to shine the edge of laser power meter probe, cause the problem of laser damage.

Description

Laser detection device

Technical Field

The application relates to the technical field of laser, in particular to a laser detection device.

Background

In the prior art, the power of the fiber laser needs to be tested by a laser detection device in the production process and the final debugging link. The existing laser power testing mode mainly depends on manual work to place the output optical cable of a laser on a laser detection device fixing seat, so that the output optical cable of the laser faces to an optical power probe of the laser detection device, and the optical power probe is convenient to detect the power of the laser.

However, when the output optical cable of the laser is placed on the laser detection device holder, the position of the output optical cable of the laser may be deviated, and the laser generated by the laser is emitted from the output optical cable and easily irradiates the edge of the power meter probe, thereby damaging the laser.

SUMMERY OF THE UTILITY MODEL

The embodiment of the application provides a laser instrument detection device, and the output optical cable that aims at solving the laser instrument probably has the deviation when placing on the laser instrument detection device fixing base, leads to the edge of laser that the laser instrument produced shines the dynamometer probe easily after the output optical cable jets out, causes the problem of the damage of laser instrument.

The embodiment of the application provides a laser instrument detection device, includes:

a support;

the laser power meter probe is arranged on the bracket;

the output optical cable adjusting structure comprises an adjusting component and an output optical cable joint, wherein the output optical cable joint is opposite to the laser power meter probe, the adjusting component is installed on the support and connected with the output optical cable joint so as to adjust the position of the output optical cable joint.

In some embodiments, the adjustment assembly includes a first slide rail coupled to the bracket and a first mount slidably mounted on the first slide rail, the output cable joint coupled to the first mount.

In some embodiments, the adjustment assembly further includes a first driving mechanism, and the first driving mechanism is connected to the first mounting base to drive the first mounting base to slide along the first slide rail.

In some embodiments, the first driving mechanism includes a first driving motor, a lead screw and a lead screw nut, the first driving motor is connected to the bracket, the lead screw is rotatably connected to the bracket, a length direction of the lead screw coincides with an extending direction of the first slide rail, the lead screw nut is sleeved on the lead screw, the lead screw nut is connected to the first mounting seat, and the first driving motor is connected to the lead screw to drive the lead screw to rotate.

In some embodiments, the adjustment assembly further comprises a baffle positioned above and extending along a length of the lead screw.

In some embodiments, the first slide extends along the laser power meter probe in a direction toward the output cable joint; or an included angle is formed between the extending direction of the first sliding rail and the direction of the laser power meter probe facing the output optical cable connector.

In some embodiments, the adjusting assembly further includes a second slide rail and a second mounting seat, the second slide rail is mounted on the first mounting seat, an extending direction of the second slide rail forms an included angle with an extending direction of the first slide rail, and the output optical cable connector is connected to the second mounting seat.

In some embodiments, the adjusting assembly further includes a second driving mechanism, and the second driving mechanism is connected to the second mounting base to drive the second mounting base to slide along the second slide rail.

In some embodiments, the adjusting assembly further includes a third slide rail and a third mounting seat, the third slide rail is mounted on the second mounting seat, an extending direction of the third slide rail forms an included angle with an extending direction of the first slide rail and an extending direction of the second slide rail, respectively, and the output optical cable connector is connected to the third mounting seat.

In some embodiments, the adjusting assembly further includes a third driving mechanism, and the third driving mechanism is connected to the third mounting seat to drive the third mounting seat to slide along the third sliding rail.

The laser detection device that this application embodiment provided adjusts the structure through set up output optical cable on the support, makes output optical cable adjust the output optical cable joint of structure relative with laser power meter probe to adjust output optical cable and adjust the adjusting part of structure and be connected with output optical cable joint, with the position of adjusting output optical cable joint. After the output optical cable of the laser is connected with the output optical cable joint, the position of the output optical cable joint is adjusted through the adjusting assembly, and then the position of the output optical cable of the laser can be adjusted, so that laser generated by the laser can accurately irradiate the probe of the laser power meter, and the problem that the laser is damaged due to the fact that the laser irradiates the edge of the probe of the laser power meter is solved.

Drawings

The technical solution and other advantages of the present application will become apparent from the detailed description of the embodiments of the present application with reference to the accompanying drawings.

Fig. 1 is a schematic internal structural diagram of an embodiment of a laser detection apparatus provided in an embodiment of the present application;

fig. 2 is a schematic structural diagram of an embodiment of an output optical cable adjusting structure provided in an embodiment of the present application.

A laser detection device 100; a support 110; a laser power meter probe 120; an output cable conditioning structure 130; an adjustment assembly 131; a first slide 1311; a first mount 1312; a base 1313; a fixed seat 1314; a through hole 1315; a first drive mechanism 1316; a first drive motor 1317; a first lead screw 1318; a first lead screw nut 1319; a baffle 1320; a second slide rail 1321; a second mounting seat 1322; a second drive mechanism 1323; a second drive motor 1324; a second lead screw 1325; a third skid 1326; a third mount 1327; a third drive mechanism 1328; a third drive motor 1329; an output cable joint 140.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application. It is to be understood that the embodiments described are only a few embodiments of the present application and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

In the description of the present application, it is to be understood that the terms "center," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," and the like are used in the orientations and positional relationships indicated in the drawings for convenience in describing the present application and for simplicity in description, and are not intended to indicate or imply that the referenced devices or elements must have a particular orientation, be constructed in a particular orientation, and be operated in a particular manner, and are not to be construed as limiting the present application. Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, features defined as "first", "second", may explicitly or implicitly include one or more of the described features. In the description of the present application, "a plurality" means two or more unless specifically limited otherwise.

In the description of the present application, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; may be mechanically connected, may be electrically connected or may be in communication with each other; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art as appropriate.

In this application, unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may comprise direct contact of the first and second features, or may comprise contact of the first and second features not directly but through another feature in between. Also, the first feature being "on," "above" and "over" the second feature includes the first feature being directly on and obliquely above the second feature, or merely indicating that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly under and obliquely below the second feature, or simply meaning that the first feature is at a lesser elevation than the second feature.

The following disclosure provides many different embodiments or examples for implementing different features of the application. In order to simplify the disclosure of the present application, specific example components and arrangements are described below. Of course, they are merely examples and are not intended to limit the present application. Moreover, the present application may repeat reference numerals and/or letters in the various examples, such repetition is for the purpose of simplicity and clarity and does not in itself dictate a relationship between the various embodiments and/or configurations discussed. In addition, examples of various specific processes and materials are provided herein, but one of ordinary skill in the art may recognize applications of other processes and/or use of other materials.

The embodiment of the application provides a laser detection device. The following are detailed below.

Fig. 1 is a schematic internal structural diagram of an embodiment of a laser detection apparatus according to an embodiment of the present disclosure. As shown in fig. 1, the laser inspection apparatus 100 includes a support 110 and a laser power meter probe 120, the laser power meter probe 120 being disposed on the support 110. When the laser power detection device 100 is used to detect the laser power, the laser power of the laser can be detected by the laser power meter probe 120 by irradiating the laser beam generated by the laser to the laser power meter probe 120.

In order to avoid the laser generated by the laser from irradiating the laser power meter probe 120, the laser irradiates the edge of the laser power meter probe 120, and the laser is damaged.

In the embodiment of the present application, as shown in fig. 1 and fig. 2, the laser detection apparatus 100 further includes an output cable adjusting structure 130, where the output cable adjusting structure 130 is used to fix an output cable of the laser and adjust a position of the output cable, so that laser generated by the laser can accurately irradiate the laser power meter probe 120.

As shown in fig. 2, the output cable adjusting structure 130 includes an adjusting assembly 131 and an output cable joint 140, the output cable joint 140 being opposite to the laser power meter probe 120. The output cable connector 140 is used to secure the output cable of the laser so that the output cable of the laser is emitted toward the laser power meter probe 120. An adjustment assembly 131 is mounted on the bracket 110 and the adjustment assembly 131 is connected to the output cable joint 140 to adjust the position of the output cable joint 140.

Therefore, after the output optical cable of the laser is connected with the output optical cable joint 140, the position of the output optical cable of the laser can be adjusted by adjusting the position of the output optical cable joint 140 through the adjusting component 131, so that laser generated by the laser can accurately irradiate the laser power meter probe 120, and the problem that the laser is damaged due to the fact that the laser irradiates the edge of the laser power meter probe 120 is solved.

It should be noted that the adjusting component 131 may adjust the position of the output cable joint 140 along the direction from the laser power meter probe 120 to the output cable joint 140, and may also adjust the position of the output cable joint 140 along the direction from the output cable joint 140 to the laser power meter probe 120 to adjust the distance between the output cable of the laser and the laser power meter probe 120, so as to adjust the area of the spot formed on the laser power meter probe 120 by the laser output from the output cable.

Alternatively, the adjusting component 131 may adjust the position of the output cable joint 140 in a direction crossing the direction of the laser power meter probe 120 toward the output cable joint 140 to adjust the coincidence degree of the center of the spot formed on the laser power meter probe 120 by the laser output by the output cable and the center of the detection surface of the laser power meter probe 120. The direction crossing the direction of the laser power meter probe 120 toward the output cable joint 140 may be specifically an up-down direction or a left-right direction, and is not limited herein.

Of course, the adjustment assembly 131 may adjust the position of the output cable joint 140 in the direction of the laser power meter probe 120 toward the output cable joint 140 and in a direction crossing the direction of the laser power meter probe 120 toward the output cable joint 140, so that the adjustment assembly 131 has a better adjustment effect on the output cable.

As shown in fig. 2, adjustment assembly 131 includes a first slide 1311 and a first mount 1312, first slide 1311 being coupled to bracket 110, first mount 1312 being slidably mounted on first slide 1311, and output cable joint 140 being coupled to first mount 1312. By controlling the first mounting block 1312 to slide along the first slide rail 1311, the output cable joint 140 connected to the first mounting block 1312 can slide along the first slide rail 1311, so as to adjust the position of the output cable on the output cable joint 140 along the extending direction of the first slide rail 1311.

It should be noted that, the connection between the output optical cable connector 140 and the first mounting seat 1312 may be that the output optical cable connector 140 is directly connected to the first mounting seat 1312, or the output optical cable connector 140 is indirectly connected to the first mounting seat 1312 through another structure, and only when the first mounting seat 1312 slides along the first sliding rail 1311, the output optical cable connector 140 can be driven to slide along the first sliding rail 1311.

Wherein, the adjusting assembly 131 further comprises a first driving mechanism 1316, and the first driving mechanism 1316 is connected with the first mounting seat 1312 to drive the first mounting seat 1312 to slide along the first sliding rail 1311. Therefore, the first mounting seat 1312 can be driven by the first driving mechanism 1316 to automatically slide along the first sliding rail 1311, so that the adjusting efficiency of the adjusting assembly 131 on the output optical cable is improved.

Specifically, the first driving mechanism 1316 includes a first driving motor 1317, a first lead screw 1318 and a first lead screw 1319, the first driving motor 1317 is connected to the bracket 110, the first lead screw 1318 is rotatably connected to the bracket 110, a length direction of the first lead screw 1318 is consistent with an extending direction of the first slide rail 1311, the first lead screw 1319 is sleeved on the first lead screw 1318, the first lead screw 1319 is connected to the first mounting seat 1312, and the first driving motor 1317 is connected to the first lead screw 1318 to drive the first lead screw 1318 to rotate. When the first driving motor 1317 drives the first lead screw 1318 to rotate, the first lead screw 1318 drives the first mounting seat 1312 to slide along the first sliding rail 1311, so that the output optical cable joint 140 connected to the first mounting seat 1312 slides along the first sliding rail 1311.

It should be noted that the first lead screw 1318 and the first lead screw nut 1319 may be connected by a ball to form a ball screw, or the first lead screw 1318 and the first lead screw nut 1319 may be directly screwed, and only when the first lead screw 1318 rotates, the first lead screw nut 1319 may move along the length direction of the first lead screw 1318.

Wherein, the adjusting assembly 131 further comprises a baffle 1320, and the baffle 1320 is located above the first lead screw 1318 and extends along the length direction of the first lead screw 1318. Therefore, the baffle 1320 can shield the first lead screw 1318 from above, and dust, impurities and the like are prevented from falling onto the first lead screw 1318 and affecting the working stability of the first lead screw 1318.

A through hole 1315 is formed in the first mounting seat 1312, and the baffle 1320 penetrates through the through hole 1315. Thus, when first mount 1312 slides along first slide rail 1311, first mount 1312 does not collide with baffle 1320. Specifically, the first mounting seat 1312 includes a base 1313 slidably connected to the first sliding rail 1311, and a fixing seat 1314 mounted above the base 1313, and the output cable joint 140 is directly or indirectly connected to the fixing seat 1314. The fixing seat 1314 is detachably connected with the base 1313, and a through hole 1315 is formed between the fixing seat 1314 and the base 1313 in an enclosing manner.

In other embodiments, the first driving mechanism 1316 includes a telescopic driving structure such as an electric cylinder, a pneumatic cylinder, a hydraulic cylinder, etc., one end of the telescopic driving structure is connected to the bracket 110, and the other end of the telescopic driving structure is connected to the first mounting seat 1312, so that the telescopic driving structure is controlled to extend and retract, and the first mounting seat 1312 can be driven to slide along the first sliding rail 1311.

In other embodiments, adjustment assembly 131 may not include first drive mechanism 1316, but rather may slide along first sliding rail 1311 by manually pushing first mount 1312.

As shown in fig. 1 and 2, the first slide 1311 extends along the laser power meter probe 120 in a direction toward the output cable joint 140. The distance between the output cable joint 140 and the laser power meter probe 120 can be adjusted when the first mount 1312 is controlled to slide along the first slide rail 1311.

In other embodiments, the first slide 1311 extends at an angle to the direction of the laser power meter probe 120 toward the output cable joint 140. When the first mounting seat 1312 is controlled to slide along the first sliding rail 1311, the coincidence degree of the spot center formed on the laser power meter probe 120 by the laser output by the output optical cable and the detection surface center of the laser power meter probe 120 can be adjusted.

The extending direction of the first sliding rail 1311 is parallel to the vertical direction, or the extending direction of the first sliding rail 1311 is parallel to the horizontal direction. Of course, the extending direction of the first sliding rail 1311 may also form an angle with the vertical direction and the horizontal direction.

As shown in fig. 2, the adjusting assembly 131 further includes a second sliding rail 1321 and a second mounting seat 1322, the second sliding rail 1321 is mounted on the first mounting seat 1312, an extending direction of the second sliding rail 1321 forms an angle with an extending direction of the first sliding rail 1311, and the output cable connector 140 is connected to the second mounting seat 1322.

When the first mounting seat 1312 is controlled to slide along the first sliding rail 1311, the second sliding rail 1321, the second mounting seat 1322 and the output cable joint 140 can be driven to slide along the first sliding rail 1311 together, so as to adjust the position of the output cable joint 140 in the extending direction of the first sliding rail 1311. When the second mounting seat 1322 is controlled to slide along the second slide rail 1321, the output cable connectors 140 on the second mounting seat 1322 can be driven to slide along the second slide rail 1321, so as to adjust the positions of the output cable connectors 140 in the extending direction of the second slide rail 1321.

Therefore, the adjusting component 131 can adjust the position of the output optical cable joint 140 in two directions forming an included angle with each other, and the position of the output optical cable joint 140 can be adjusted more flexibly. In particular, when the first sliding rail 1311 extends along the laser power meter probe 120 toward the output cable joint 140, the distance between the output cable joint 140 and the laser power meter probe 120 and the coincidence degree of the center of the spot formed on the laser power meter probe 120 by the laser output from the output cable and the center of the detection surface of the laser power meter probe 120 can be adjusted at the same time.

As shown in fig. 2, the adjusting assembly 131 further includes a second driving mechanism 1323, and the second driving mechanism 1323 is connected to the second mounting seat 1322 to drive the second mounting seat 1322 to slide along the second slide rail 1321. Therefore, the second driving mechanism 1323 can drive the second mounting seat 1322 to automatically slide along the second slide rail 1321, and the adjusting efficiency of the adjusting assembly 131 on the output optical cable is further improved.

Specifically, the second driving mechanism 1323 includes a second driving motor 1324, a second lead screw 1325 and a second lead screw nut (not shown), the second driving motor 1324 is connected to the first mounting seat 1312, the second lead screw 1325 is rotatably connected to the first mounting seat 1312, a length direction of the second lead screw 1325 is consistent with an extending direction of the second slide rail 1321, the second lead screw nut is sleeved on the second lead screw 1325, the second lead screw nut is connected to the second mounting seat 1322, and the second driving motor 1324 is connected to the second lead screw 1325 to drive the second lead screw 1325 to rotate. When the second driving motor 1324 drives the second screw 1325 to rotate, the second screw 1325 drives the second mounting seat 1322 to slide along the second slide rail 1321, so that the output optical cable connector 140 connected to the second mounting seat 1322 slides along the second slide rail 1321.

It should be noted that the second lead screw 1325 and the second lead screw nut may be connected by a ball to form a ball screw, or the second lead screw 1325 and the second lead screw nut may be directly screwed, and the second lead screw nut may be moved along the length direction of the second lead screw 1325 only by rotating the second lead screw 1325.

In other embodiments, the second driving mechanism 1323 includes a telescopic driving structure such as an electric cylinder, a pneumatic cylinder, a hydraulic cylinder, etc., one end of the telescopic driving structure is connected to the first mounting seat 1312, and the other end of the telescopic driving structure is connected to the second mounting seat 1322, so that the telescopic driving structure is controlled to stretch and retract, so as to drive the second mounting seat 1322 to slide along the second slide rail 1321.

In other embodiments, the adjusting assembly 131 may not include the second driving mechanism 1323, but slide along the second slide rail 1321 by manually pushing the second mounting seat 1322.

As shown in fig. 2, the adjusting assembly 131 further includes a third slide rail 1326 and a third mounting seat 1327, the third slide rail 1326 is mounted on the second mounting seat 1322, an extending direction of the third slide rail 1326 forms an angle with an extending direction of the first slide rail 1311 and an extending direction of the second slide rail 1321, respectively, and the output cable connector 140 is connected to the third mounting seat 1327.

When the first mounting seat 1312 is controlled to slide along the first sliding rail 1311, the second sliding rail 1321, the second mounting seat 1322, the third sliding rail 1326, the third mounting seat 1327 and the output optical cable connector 140 can be driven to slide along the first sliding rail 1311, so as to adjust the position of the output optical cable connector 140 in the extending direction of the first sliding rail 1311.

When the second mounting seat 1322 is controlled to slide along the second slide rail 1321, the third slide rail 1326, the third mounting seat 1327 and the output cable connector 140 on the second mounting seat 1322 can be driven to slide along the second slide rail 1321, so as to adjust the position of the output cable connector 140 in the extending direction of the second slide rail 1321.

When the third mounting seat 1327 is controlled to slide along the third slide rail 1326, the output cable connectors 140 on the third mounting seat 1327 can be driven to slide along the second slide rail 1321, so as to adjust the positions of the output cable connectors 140 in the extending direction of the third slide rail 1326.

Thus, the adjustment assembly 131 can adjust the position of the output cable joint 140 in three different directions, which enables the position adjustment of the output cable joint 140 to be more comprehensive, to ensure that the output cable of the laser can be adjusted to a position aligned with the laser power meter probe 120, and to maintain a suitable distance between the output cable joint 140 and the laser power meter probe 120.

The adjustment assembly 131 further includes a third driving mechanism 1328, and the third driving mechanism 1328 is connected to the third mounting seat 1327 to drive the third mounting seat 1327 to slide along the third slide rail 1326. Therefore, the third driving mechanism 1328 can drive the third mounting seat 1327 to automatically slide along the third slide rail 1326, and the adjusting efficiency of the adjusting assembly 131 on the output optical cable is further improved.

Specifically, the third driving mechanism 1328 includes a third driving motor 1329, a third lead screw (not shown) and a third lead screw nut (not shown), the third driving motor 1329 is connected to the second mounting seat 1322, the third lead screw is rotatably connected to the second mounting seat 1322, a length direction of the third lead screw is consistent with an extending direction of the third slide rail 1326, the third lead screw nut is sleeved on the third lead screw, the third lead screw nut is connected to the third mounting seat 1327, and the third driving motor 1329 is connected to the third lead screw to drive the third lead screw to rotate. When the third driving motor 1329 drives the third screw rod to rotate, the third screw rod drives the third mounting seat 1327 to slide along the third slide rail 1326, so that the output optical cable connector 140 connected to the third mounting seat 1327 slides along the third slide rail 1326.

It should be noted that the third screw rod and the third screw rod nut may be connected by a ball to form a ball screw, or the third screw rod and the third screw rod nut may also be directly connected by a screw thread, and only when the third screw rod rotates, the third screw rod nut may move along the length direction of the third screw rod.

In other embodiments, the adjustment assembly 131 may not include the third driving mechanism 1328, but may slide along the third slide rail 1326 by manually pushing the third mounting seat 1327.

Specifically, the first slide rail 1311 extends in a direction (front-rear direction in fig. 2) in which the laser power meter probe 120 faces the output cable joint 140, the second slide rail 1321 extends in the left-right direction, and the third slide rail 1326 extends in the up-down direction. Thus, by controlling the first mount 1312 to slide along the first slide rail 1311, the distance between the output cable joint 140 and the laser power meter probe 120 can be adjusted. On this basis, the position of the output optical cable joint 140 in the left-right direction can be adjusted by controlling the second mounting seat 1322 to slide along the second slide rail 1321, and the position of the output optical cable joint 140 in the up-down direction can be adjusted by controlling the third mounting seat 1327 to slide along the third slide rail 1326, so that the adjustment of the overlap ratio between the center of the spot formed on the laser power meter probe 120 by the laser output by the output optical cable and the center of the detection surface of the laser power meter probe 120 is completed.

The first slide rail 1311 may extend in the left-right direction (or the up-down direction), the second slide rail 1321 may extend in the up-down direction (or the front-back direction), and the third slide rail 1326 may extend in the front-back direction (or the left-right direction), and the extending directions of the first slide rail 1311, the second slide rail 1321, and the third slide rail 1326 may be not parallel to each other.

Alternatively, the output cable connector 140 may be a probe-type contact connector that uses springs to secure the output cable, so that the connection between the output cable connector and the output cable is more convenient and stable.

Optionally, there are a plurality of output cable joints 140, and a plurality of output cable joints 140 are arranged in parallel on the third mounting seat 1327. Wherein each output cable joint 140 has a different model, so that the laser detection apparatus 100 can fix the output cables of different models of lasers.

In the foregoing embodiments, the descriptions of the respective embodiments have respective emphasis, and for parts that are not described in detail in a certain embodiment, reference may be made to related descriptions of other embodiments.

The above detailed description is made on the laser detection device provided in the embodiment of the present application, and a specific example is applied in the detailed description to explain the principle and the implementation of the present application, and the description of the above embodiment is only used to help understanding the technical solution and the core idea of the present application; those of ordinary skill in the art will understand that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; such modifications or substitutions do not depart from the spirit and scope of the present disclosure as defined by the appended claims.

Claims (10)

1. A laser detection device, comprising:

a support;

the laser power meter probe is arranged on the bracket;

the output optical cable adjusting structure comprises an adjusting component and an output optical cable joint, wherein the output optical cable joint is opposite to the laser power meter probe, the adjusting component is installed on the support and connected with the output optical cable joint so as to adjust the position of the output optical cable joint.

2. The laser detection apparatus of claim 1, wherein the adjustment assembly comprises a first slide rail and a first mount, the first slide rail being coupled to the bracket, the first mount being slidably mounted on the first slide rail, the output cable joint being coupled to the first mount.

3. The laser detection device as claimed in claim 2, wherein the adjustment assembly further comprises a first driving mechanism, and the first driving mechanism is connected to the first mounting base to drive the first mounting base to slide along the first slide rail.

4. The laser detecting device as claimed in claim 3, wherein the first driving mechanism includes a first driving motor, a lead screw and a lead screw nut, the first driving motor is connected to the bracket, the lead screw is rotatably connected to the bracket, a length direction of the lead screw coincides with an extending direction of the first slide rail, the lead screw nut is sleeved on the lead screw, the lead screw nut is connected to the first mounting seat, and the first driving motor is connected to the lead screw to drive the lead screw to rotate.

5. The laser detection apparatus of claim 4 wherein the adjustment assembly further comprises a baffle positioned above and extending along the length of the lead screw.

6. The laser detection apparatus of claim 2, wherein the first slide extends along the laser power meter probe in a direction toward the output cable joint; or an included angle is formed between the extending direction of the first sliding rail and the direction of the laser power meter probe facing the output optical cable connector.

7. The laser detection device as claimed in any one of claims 2 to 6, wherein the adjustment assembly further comprises a second slide rail and a second mounting seat, the second slide rail is mounted on the first mounting seat, an extending direction of the second slide rail forms an included angle with an extending direction of the first slide rail, and the output optical cable connector is connected to the second mounting seat.

8. The laser detection device as claimed in claim 7, wherein the adjustment assembly further comprises a second driving mechanism, and the second driving mechanism is connected to the second mounting base to drive the second mounting base to slide along the second slide rail.

9. The laser detection apparatus of claim 7, wherein the adjustment assembly further comprises a third slide rail and a third mounting seat, the third slide rail is mounted on the second mounting seat, an extending direction of the third slide rail forms an included angle with an extending direction of the first slide rail and an extending direction of the second slide rail, respectively, and the output optical cable connector is connected to the third mounting seat.

10. The laser detection apparatus of claim 9, wherein the adjustment assembly further comprises a third driving mechanism, and the third driving mechanism is connected to the third mounting seat to drive the third mounting seat to slide along the third slide rail.

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