CN219301567U - Novel special crossbeam of calibrator scanning device - Google Patents

Abstract

The utility model discloses a novel special cross beam for a thickness meter scanning device, which comprises a climbing frame, a transmission assembly, a vacuum chuck, a climbing plate, a cross beam, a driving assembly, a sliding rail and a sliding block, wherein the climbing frame is fixedly connected with the cross beam, the transmission assembly is fixedly connected with the climbing frame, the climbing plate is hinged with the transmission assembly, the vacuum chuck is fixedly connected with the climbing plate, the sliding block is fixedly arranged on the cross beam, the sliding block can be slidably clamped in the sliding rail, and the driving assembly is fixedly connected with the sliding block. The utility model belongs to the field of film production, and particularly relates to a novel special beam for a thickness meter scanning device, which has an automatic climbing function and can rapidly realize the installation of a thickness meter without professional hoisting equipment.

Description

Novel special crossbeam of calibrator scanning device

Technical Field

The utility model belongs to the field of film production, and particularly relates to a novel beam special for a thickness meter scanning device.

Background

The laser thickness gauge is generally composed of two laser displacement sensors which are opposite to each other up and down, the upper surface position and the lower surface position of the measured object are measured by the upper sensor and the lower sensor respectively, and the thickness of the measured object is obtained through calculation. In some film production processes, a thickness gauge is required to measure the film thickness in real time to adjust and monitor the production process and the production quality. While some film production requires lifting the film to a height above 4 meters, the thickness gauge needs to be mounted above 4 meters from the ground.

Patent number CN217329318U discloses a laser thickness meter scanning frame fixing device, and the device is when in actual use, through installing the thickness meter on bearing the weight of the subassembly, realizes stable installation, under the slide mechanism effect of sideslip subassembly for the thickness meter is convenient for dismouting, in addition, through the effect of fine setting mechanism for the thickness meter when fine setting, fine setting mechanism is with fine change self-adaptation, makes the difficult shake of thickness meter, also possesses sensitivity when making it possess stability. The technical problem that this scheme had is that the thickness gauge weight is heavier, consequently needs professional lifting device just can hoist and install on laser thickness gauge scanning frame fixing device, and often some film production factory does not have sufficient place, and professional lifting device does not get into for on-the-spot thickness gauge installation difficulty.

Therefore, a special beam for a novel thickness meter scanning device, which has an automatic climbing function and can realize the installation of the thickness meter without professional lifting equipment, is required to be designed to solve the problems in the prior art.

Disclosure of Invention

In order to solve the problems, the utility model provides the novel special beam for the thickness meter scanning device, which has an automatic climbing function and can quickly realize the installation of the thickness meter without professional hoisting equipment.

In order to realize the functions, the technical scheme adopted by the utility model is as follows: the utility model provides a novel special crossbeam of calibrator scanning device, includes climbing frame, drive assembly, vacuum chuck, climbs board, crossbeam, drive assembly, slide rail and slider, it links to each other with the crossbeam is fixed, drive assembly links to each other with climbing frame is fixed, it is articulated with drive assembly to climb the board, vacuum chuck links to each other with climbing board is fixed, the fixed slider that is equipped with on the crossbeam, slider slidable joint is located in the slide rail, drive assembly links to each other with the slider is fixed, installs the calibrator to the slider bottom, and drive assembly drives the slider and removes, realizes the position control of calibrator, will climb the frame and adsorb on the wall through vacuum chuck, and drive assembly drives to climb the board motion, makes the device climb along the wall, need not professional lifting device and can realize the calibrator installation fast.

Further, the driving assembly comprises a first driving motor, a first motor placing box, a first driving sprocket, a driving chain and a driven sprocket, the first motor placing box is fixedly connected with the cross beam, the first driving motor is fixedly arranged in the first motor placing box, the output end of the first driving motor rotatably penetrates through the first motor placing box and is fixedly connected with the driving sprocket, the driven sprocket is hinged with the cross beam, the driving chain is in an open loop arrangement, two ends of the driving chain are fixedly connected with the sliding block respectively, the driving chain winds the outer sides of the driving sprocket and the driven sprocket, the driving motor drives the driving sprocket to rotate, and the sliding block is driven to slide along the sliding rail through the transmission effect of the driving chain and the driven sprocket.

Further, drive assembly includes that drive frame, swivel mount, driving motor II, motor place case II, spacing and connecting rod, motor place case II and climb the fixed continuous of frame, driving motor II is fixed to be located in the motor places case II, driving motor II's output rotatably runs through motor and places case II and link to each other with the swivel mount is fixed, the drive frame articulates with the swivel mount, spacing both ends are articulated with frame and the drive frame that climbs respectively, the connecting rod links to each other with the drive frame is fixed, the connecting rod articulates with climbing the board, and driving motor II drives the swivel mount rotation, makes climbing the board carry out reciprocating motion through the transmission effect of spacing and drive frame.

Preferably, the transmission assembly is provided with several sets along the climbing plate.

Preferably, the climbing plates are symmetrically arranged in two groups along the climbing frame.

Preferably, the vacuum sucking discs are arranged in a plurality of groups at equal intervals along the climbing plate.

Preferably, the first driving motor is a servo motor.

Preferably, the second driving motor is a servo motor.

The utility model adopts the structure to obtain the beneficial effects as follows: the novel transverse beam special for the thickness meter scanning device is simple to operate, compact in structure and reasonable in design, the climbing frame is adsorbed on the wall through the vacuum chuck, the transmission assembly drives the climbing plate to move, the device climbs along the wall, the driving assembly drives the sliding block to move, the position adjustment of the thickness meter is realized, the installation of the thickness meter can be quickly realized without professional hoisting equipment, and the technical problem that the traditional thickness meter can be hoisted and installed only by the professional hoisting equipment and is difficult to install when the space is narrow is solved.

Drawings

FIG. 1 is a front view of a beam dedicated for a novel thickness gauge scanning device provided by the utility model;

FIG. 2 is a right side view of a beam dedicated for the novel thickness gauge scanning device provided by the utility model;

fig. 3 is a front view of a transmission assembly of a beam special for a novel thickness meter scanning device provided by the utility model.

The climbing frame comprises a climbing frame body 1, a climbing frame body 2, a transmission assembly body 3, a vacuum chuck body 4, a climbing plate body 5, a cross beam, a driving assembly body 6, a driving assembly body 7, a sliding rail 8, a sliding block 9, a driving motor I, a driving motor 10, a motor placing box I, a driving sprocket 11, a driving sprocket 12, a transmission chain 13, a driven sprocket 14, a driving frame 15, a rotating frame 16, a driving motor II, a driving motor 17, a motor placing box II, a limiting frame 18, a limiting frame 19 and a connecting rod.

Detailed Description

The following description of the embodiments of the present utility model will be made apparent and fully in view of the accompanying drawings, in which some, but not all embodiments of the utility model are shown. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

In the description of the present utility model, it should be noted that the directions or positional relationships indicated by the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present utility model and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. The present utility model will be described in further detail with reference to the accompanying drawings.

As shown in fig. 1-2, the special cross beam 5 for the novel thickness meter scanning device provided by the utility model comprises a climbing frame 1, a transmission assembly 2, a vacuum chuck 3, a climbing plate 4, a cross beam 5, a driving assembly 6, a sliding rail 7 and a sliding block 8, wherein the climbing frame 1 is fixedly connected with the cross beam 5, the transmission assembly 2 is fixedly connected with the climbing frame 1, the climbing plate 4 is hinged with the transmission assembly 2, the vacuum chuck 3 is fixedly connected with the climbing plate 4, the sliding block 8 is fixedly arranged on the cross beam 5, the sliding block 8 is slidably clamped in the sliding rail 7, and the driving assembly 6 is fixedly connected with the sliding block 8; the driving assembly 6 comprises a driving motor I9, a motor placing box I10, a driving chain wheel 11, a driving chain 12 and a driven chain wheel 13, wherein the motor placing box I10 is fixedly connected with the cross beam 5, the driving motor I9 is fixedly arranged in the motor placing box I10, the output end of the driving motor I9 rotatably penetrates through the motor placing box I10 and is fixedly connected with the driving chain wheel 11, the driven chain wheel 13 is hinged with the cross beam 5, the driving chain wheel 12 is in an open loop arrangement, two ends of the driving chain 12 are fixedly connected with the sliding block 8 respectively, the driving chain 12 is wound on the outer sides of the driving chain wheel 11 and the driven chain wheel 13, the driving assembly 2 is provided with a plurality of groups along the climbing plate 4, the climbing plate 4 is symmetrically provided with two groups along the climbing frame 1, and the vacuum sucker 3 is provided with a plurality of groups along the climbing plate 4 at equal intervals.

As shown in fig. 3, the transmission assembly 2 includes a driving frame 14, a rotating frame 15, a driving motor two 16, a motor placing box two 17, a limiting frame 18 and a connecting rod 19, wherein the motor placing box two 17 is fixedly connected with the climbing frame 1, the driving motor two 16 is fixedly arranged in the motor placing box two 17, the output end of the driving motor two 16 can rotatably penetrate through the motor placing box two 17 and is fixedly connected with the rotating frame 15, the driving frame 14 is hinged with the rotating frame 15, two ends of the limiting frame 18 are respectively hinged with the climbing frame 1 and the driving frame 14, the connecting rod 19 is fixedly connected with the driving frame 14, and the connecting rod 19 is hinged with the climbing plate 4.

When the thickness gauge is specifically used, the thickness gauge is mounted at the bottom of the sliding block 8, the driving motor I9 drives the driving chain wheel 11 to rotate, the sliding block 8 is driven to slide along the sliding rail 7 through the transmission action of the transmission chain 12 and the driven chain wheel 13, the position adjustment of the thickness gauge is realized, the climbing frame 1 is adsorbed on a wall through the vacuum chuck 3, the driving motor II 16 drives the rotating frame 15 to rotate, the climbing plate 4 is driven to reciprocate through the transmission action of the limiting frame 18 and the driving frame 14, the device climbs along the wall, and the thickness gauge mounting can be rapidly realized without professional hoisting equipment.

The utility model and its embodiments have been described above with no limitation, and the actual construction is not limited to the embodiments of the utility model as shown in the drawings. In summary, if one of ordinary skill in the art is informed by this disclosure, a structural manner and an embodiment similar to the technical solution should not be creatively devised without departing from the gist of the present utility model.

Claims (8)

1. Novel special crossbeam of calibrator scanning device, its characterized in that: the device comprises a climbing frame, a transmission assembly, a vacuum chuck, a climbing plate, a cross beam, a driving assembly, a sliding rail and a sliding block, wherein the climbing frame is fixedly connected with the cross beam, the transmission assembly is fixedly connected with the climbing frame, the climbing plate is hinged to the transmission assembly, the vacuum chuck is fixedly connected with the climbing plate, the sliding block is fixedly arranged on the cross beam, the sliding block is slidably clamped in the sliding rail, and the driving assembly is fixedly connected with the sliding block.

2. The beam special for the novel thickness meter scanning device according to claim 1, wherein: the driving assembly comprises a driving motor I, a motor placing box I, a driving sprocket, a driving chain and a driven sprocket, wherein the motor placing box I is fixedly connected with the cross beam, the driving motor I is fixedly arranged in the motor placing box I, the output end of the driving motor I rotatably penetrates through the motor placing box I and is fixedly connected with the driving sprocket, the driven sprocket is hinged with the cross beam, the driving chain is in an open loop arrangement, two ends of the driving chain are fixedly connected with the sliding block respectively, and the driving chain is wound on the outer sides of the driving sprocket and the driven sprocket.

3. The beam special for the novel thickness meter scanning device according to claim 2, wherein: the transmission assembly comprises a driving frame, a rotating frame, a driving motor II, a motor placing box II, a limiting frame and a connecting rod, wherein the motor placing box II is fixedly connected with the climbing frame, the driving motor II is fixedly arranged in the motor placing box II, the output end of the driving motor II rotatably penetrates through the motor placing box II and is fixedly connected with the rotating frame, the driving frame is hinged with the rotating frame, two ends of the limiting frame are respectively hinged with the climbing frame and the driving frame, the connecting rod is fixedly connected with the driving frame, and the connecting rod is hinged with the climbing plate.

4. A novel thickness gauge scanning device dedicated beam as defined in claim 3, wherein: the transmission assembly is provided with a plurality of groups along the climbing plate.

5. The beam special for the novel thickness meter scanning device according to claim 4, wherein: the climbing plates are symmetrically provided with two groups along the climbing frame.

6. The beam special for the novel thickness meter scanning device according to claim 5, wherein: the vacuum sucking discs are provided with a plurality of groups at equal intervals along the climbing plate.

7. The beam special for the novel thickness meter scanning device according to claim 6, wherein: the first driving motor is a servo motor.

8. The beam special for the novel thickness meter scanning device according to claim 7, wherein: and the second driving motor is a servo motor.

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