CN213423523U - Automatic debugging equipment for optical fiber collimator - Google Patents

Abstract

The utility model relates to the technical field of optical fiber equipment, in particular to an automatic debugging device of an optical fiber collimator, which comprises an L-shaped mounting seat, a facula monitor, a first support frame, a second support frame, a lifting mechanism, a controller, a display, a distance sensor, a collimator clamping mechanism, a camera, an optical fiber, a clamping component and a laser generator; when the device is used, the collimator clamping mechanism automatically clamps the optical fiber collimator to be detected, the controller controls the lifting mechanism to drive the second support frame to slide downwards, the second support frame slides downwards to drive the optical fiber to be inserted into the optical fiber collimator to be detected, meanwhile, the controller continuously shoots the projection condition on the light spot monitor through the camera, when the controller judges that the light spot value shot by the camera is qualified, the lifting mechanism stops sliding downwards, the distance sensor detects the sliding height of the second support frame, and the controller calculates the sliding distance of the second support frame according to the detection result of the distance sensor; the utility model discloses can debug the reading, whole process convenient operation, the simple operation in full-automatic.

Description

Automatic debugging equipment for optical fiber collimator

Technical Field

The utility model relates to an optical fiber equipment technical field specifically is an optical collimator automatic debugging equipment.

Background

The optical fiber collimator is formed by accurately positioning the tail fiber and the self-focusing lens, can convert transmission light in the optical fiber into collimated light (parallel light), or couple external parallel light (approximate parallel) into a single-mode optical fiber, needs to be debugged in the production process, needs to be debugged manually in the traditional method, is low in debugging speed, high in staff training difficulty, needs to depend on the experience of staff, and is difficult to ensure the debugging precision.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to foretell not enough, provide one kind and can debug the reading full-automatically, whole process convenient operation, simple operation's automatic debugging equipment of optical collimator.

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

an automatic debugging device for an optical fiber collimator comprises an L-shaped mounting seat, a light spot monitor arranged at the transverse part of the L-shaped mounting seat, a first support frame fixedly connected to the vertical part of the L-shaped mounting seat, a second support frame slidably connected to the vertical part of the L-shaped mounting seat and a lifting mechanism for driving the second support frame to slide, wherein the second support frame is arranged right above the first support frame;

be provided with collimator clamping mechanism and camera on the first support frame, be provided with optic fibre on the second support frame and be used for pressing from both sides tight the clamping component that optic fibre adopted, clamping component upper portion is provided with laser generator, the input of optic fibre is connected laser generator's output, the output of optic fibre just to set up in directly over collimator clamping mechanism, collimator clamping mechanism set up in directly over the facula monitor, the shooting end orientation of camera the facula monitor sets up, equal electric connection of facula monitor, elevating system, display, distance sensor, collimator clamping mechanism, camera and laser generator the controller.

Further, a slide rail is arranged at the vertical part of the L-shaped mounting seat, and a sliding groove is arranged on the second supporting frame and is opposite to the slide rail; the lifting mechanism is an electric telescopic rod, the electric telescopic rod is fixedly connected with the vertical part of the L-shaped mounting seat, the rod head of the electric telescopic rod is connected with the second supporting frame in a driving mode, and the sliding groove is used for being connected with the sliding rail in a sliding mode.

Further, collimator clamping mechanism includes the fixing base, just to set up in the fixed block of fixing base one side and press from both sides tight piece, fixed block fixed connection be in on the fixing base, be provided with in the fixed block and press from both sides tight motor, press from both sides tight motor output shaft drive and connect the lead screw, just on the fixed block be provided with the internal thread to the lead screw, the lead screw passes through internal thread drive connects the fixed block, all be provided with the arc wall on the face to face of fixed block and the tight piece of clamp.

Further, clamping component includes the retainer plate, the inboard symmetry of retainer plate is provided with two sets of springs, the inboard of spring is provided with the arc clamping piece.

Further, the laser generator is detachably connected to the top of the fixing ring.

The utility model has the advantages that:

in practical application, the optical fiber collimator to be detected is automatically clamped through the collimator clamping mechanism, the controller controls the lifting mechanism to drive the second support frame to slide downwards, the optical fiber is driven to be inserted into the optical fiber collimator to be detected through the sliding of the second support frame, meanwhile, the controller continuously shoots the projection condition on the light spot monitor through the camera, when the controller judges that the light spot value shot by the camera is qualified, the lifting mechanism stops sliding downwards, the distance sensor detects the sliding height of the second support frame, the controller calculates the sliding distance of the second support frame according to the detection result of the distance sensor, and the calculation result is displayed through the display; the utility model discloses can debug the reading, whole process convenient operation, the simple operation in full-automatic.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention;

fig. 2 is a cross-sectional view of the present invention;

FIG. 3 is a schematic diagram of a collimator clamping mechanism according to the present invention;

fig. 4 is a schematic structural view of a clamping assembly according to the present invention;

reference numerals: an L-shaped mounting base 1; a first support frame 11; a second support frame 12; a light spot monitor 2; a lifting mechanism 3; a controller 4; a distance sensor 5; a collimator clamping mechanism 6; a fixed base 61; a fixed block 62; a clamping block 63; a clamp motor 64; an arc-shaped slot 65; a camera 7; an optical fiber 8; a clamping assembly 9; a fixing ring 91; a spring 92; an arc-shaped clamping piece 93; a laser generator 10.

Detailed Description

As shown in fig. 1, 2, 3 and 4, an automatic debugging device for an optical fiber collimator comprises an L-shaped mounting base 1, a light spot monitor 2 arranged at a transverse part of the L-shaped mounting base 1, a first support frame 11 fixedly connected to a vertical part of the L-shaped mounting base 1, a second support frame 12 slidably connected to the vertical part of the L-shaped mounting base 1, and a lifting mechanism 3 for driving the second support frame 12 to slide, wherein the second support frame 12 is arranged right above the first support frame 11, a controller 4 and a display are arranged at one side of the L-shaped mounting base 1, a mounting block is arranged at the top of the vertical part of the L-shaped mounting base 1, and a distance sensor 5 is arranged right above the second support frame 12 at the bottom of the mounting block; be provided with collimator clamping mechanism 6 and camera 7 on the first support frame 11, be provided with optic fibre 8 on the second support frame 12 and be used for pressing from both sides tight the clamping component 9 that optic fibre 8 adopted, clamping component 9 upper portion is provided with laser generator 10, the input of optic fibre 8 is connected laser generator 10's output, optic fibre 8's output just to set up in directly over collimator clamping mechanism 6, collimator clamping mechanism 6 set up in directly over facula monitor 2, the shooting end orientation of camera 7 facula monitor 2 sets up, facula monitor 2, elevating system 3, display, distance sensor 5, collimator clamping mechanism 6, camera 7 and the equal electric connection of laser generator 10 controller 4.

When the optical fiber collimator works, the optical fiber collimator to be detected is automatically clamped through the collimator clamping mechanism 6, the optical fiber 8 is clamped through the clamping assembly 9, the controller 4 controls the lifting mechanism 3 to drive the second support frame 12 to slide downwards, the optical fiber 8 is driven to be inserted into the optical fiber collimator to be detected to slide downwards through the second support frame 12, meanwhile, the controller 4 continuously shoots the projection condition on the light spot monitor 2 through the camera 7, when the controller 4 judges that the light spot value shot by the camera 7 is qualified, the lifting mechanism 3 stops sliding downwards, the distance sensor 5 detects the sliding height of the second support frame 12, the controller 4 calculates the sliding distance of the second support frame 12 according to the detection result of the distance sensor 5, and the calculation result is displayed through the display; the utility model discloses can debug the reading, whole process convenient operation, the simple operation in full-automatic.

As shown in fig. 1, 2, 3 and 4, a slide rail 13 is arranged at a vertical portion of the L-shaped mounting seat 1, and a sliding groove is arranged on the second supporting frame 12 opposite to the slide rail 13; the lifting mechanism 3 is an electric telescopic rod which is fixedly connected to the vertical part of the L-shaped mounting seat 1, a rod head of the electric telescopic rod is in driving connection with the second support frame 12, and the sliding groove is used for being in sliding connection with the sliding rail 13; in this embodiment, the rod head of the electric telescopic rod stretches and retracts to drive the second support frame 12 to slide along the sliding groove.

As shown in fig. 1, 2, 3 and 4, the collimator clamping mechanism 6 includes a fixed seat 61, a fixed block 62 and a clamping block 63 opposite to one side of the fixed seat 61, the fixed block 62 is fixedly connected to the fixed seat 61, a clamping motor 64 is disposed in the fixed block 62, an output shaft of the clamping motor 64 is in driving connection with a lead screw, an internal thread is disposed on the fixed block 62 opposite to the lead screw, the lead screw is in driving connection with the fixed block 62 through the internal thread, and arc-shaped grooves 65 are disposed on opposite surfaces of the fixed block 62 and the clamping block 63; in this embodiment, the lead screw is driven to rotate by the clamping motor 64, and the lead screw drives the clamping block 63 to move, so as to automatically clamp the optical fiber collimator to be tested in the arc-shaped groove 65.

As shown in fig. 1, 2, 3 and 4, the clamping assembly 9 includes a fixing ring 91, two sets of springs 92 are symmetrically disposed on the inner side of the fixing ring 91, and arc-shaped clamping pieces 93 are disposed on the inner sides of the springs 92; in this embodiment, the optical fiber 8 is clamped in the arc-shaped clamping piece 93, so that the optical fiber is convenient to take.

As shown in fig. 1, 2, 3 and 4, the laser generator 10 is detachably connected to the top of the fixing ring 91; in this embodiment, through dismantling down laser generator 10 and can replace optic fibre, simple structure, it is convenient to detect.

The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications, additions and substitutions for the specific embodiments described herein will be apparent to those skilled in the art without departing from the scope and spirit of the invention as defined in the accompanying claims.

Claims (5)

1. The utility model provides an automatic debugging equipment of fiber collimator which characterized in that: the device comprises an L-shaped mounting seat (1), a light spot monitor (2) arranged at the transverse part of the L-shaped mounting seat (1), a first support frame (11) fixedly connected with the vertical part of the L-shaped mounting seat (1), a second support frame (12) slidably connected with the vertical part of the L-shaped mounting seat (1) and a lifting mechanism (3) used for driving the second support frame (12) to slide, wherein the second support frame (12) is just arranged right above the first support frame (11), one side of the L-shaped mounting seat (1) is provided with a controller (4) and a display, the top of the vertical part of the L-shaped mounting seat (1) is provided with a mounting block, and the bottom of the mounting block is just opposite to the second support frame (12) and is provided with a distance sensor (5);

be provided with collimator clamping mechanism (6) and camera (7) on first support frame (11), be provided with optic fibre (8) on second support frame (12) and be used for pressing from both sides tight clamping component (9) that optic fibre (8) adopted, clamping component (9) upper portion is provided with laser generator (10), the input of optic fibre (8) is connected the output of laser generator (10), the output of optic fibre (8) just to set up in directly over collimator clamping mechanism (6), collimator clamping mechanism (6) set up in directly over facula monitor (2), the shooting end orientation of camera (7) facula monitor (2) sets up, facula monitor (2), elevating system (3), display, distance sensor (5), collimator clamping mechanism (6), The camera (7) and the laser generator (10) are both electrically connected with the controller (4).

2. The automatic debugging device for the optical fiber collimator according to claim 1, characterized in that: a sliding rail (13) is arranged at the vertical part of the L-shaped mounting seat (1), and a sliding groove is arranged on the second supporting frame (12) and is opposite to the sliding rail (13); elevating system (3) are electric telescopic handle, electric telescopic handle fixed connection in the vertical portion of L shape mount pad (1), electric telescopic handle's pole head drive is connected second support frame (12), the spout is used for sliding connection slide rail (13).

3. The automatic debugging device for the optical fiber collimator according to claim 1, characterized in that: collimator clamping mechanism (6) include fixing base (61), just set up in fixed block (62) and the tight piece (63) of clamp of fixing base (61) one side, fixed block (62) fixed connection be in on fixing base (61), be provided with in fixed block (62) and press from both sides tight motor (64), press from both sides tight motor (64) output shaft drive and connect the lead screw, it is just right on fixed block (62) the lead screw is provided with the internal thread, the lead screw passes through internal thread drive connects fixed block (62), all be provided with arc wall (65) on the face-to-face of fixed block (62) and the tight piece (63) of clamp.

4. The automatic debugging device for the optical fiber collimator according to claim 1, characterized in that: the clamping assembly (9) comprises a fixing ring (91), two groups of springs (92) are symmetrically arranged on the inner side of the fixing ring (91), and arc-shaped clamping pieces (93) are arranged on the inner side of the springs (92).

5. The automatic debugging device for the optical fiber collimator according to claim 4, characterized in that: the laser generator (10) is detachably connected to the top of the fixing ring (91).

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