CN215296203U - Single-shaft multi-belt movement structure for O-shaped thickness measuring scanner - Google Patents

Abstract

The utility model discloses a single-shaft multi-belt motion structure for an O-shaped thickness measuring scanner, which comprises a base, a first side plate and a second side plate, wherein the first side plate and the second side plate are arranged in pairs, a first crossbeam and a second crossbeam are arranged between the first side plate and the second side plate, the second crossbeam is positioned below the first crossbeam, one side of the second side plate, which is far away from the first crossbeam, is provided with a synchronizing shaft, the surface of the synchronizing shaft is fixed with a first synchronizing wheel and a second synchronizing wheel, the first synchronizing wheel and the second synchronizing wheel are coaxial and have the same diameter teeth number, the surface of the first synchronizing wheel is connected with a first driving belt, the surface of the second synchronizing wheel is connected with a second driving belt, when the device runs, the synchronizing shaft can be opened, the synchronizing shaft can drive the first synchronizing wheel to rotate with the second synchronizing wheel, and because the first synchronizing wheel and the second synchronizing wheel are coaxial and have the same diameter teeth number, the first driving belt and the second driving belt can be respectively rotated with the second synchronizing wheel, and the relative moving amplitude of the first transmission belt and the second transmission belt is consistent, so that the synchronization rate of the device can be improved.

Description

Single-shaft multi-belt movement structure for O-shaped thickness measuring scanner

Technical Field

The utility model relates to a calibrator technical field specifically is a O type thickness measurement is unipolar multiband motion structure for scanner.

Background

The O-shaped side rear scanner is used for clamping a product to be detected by the detection heads and then reading the distance between the detection heads, so that the thickness of the product is measured by the O-shaped side rear scanner.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a O type thickness measuring scanner is with many areas of unipolar motion structure to solve the problem that proposes among the above-mentioned background art.

In order to solve the technical problem, the utility model provides a following technical scheme: a single-shaft multi-belt movement structure for an O-shaped thickness measuring scanner comprises a base, a first side plate and a second side plate, wherein the first side plate and the second side plate are arranged in pairs, a first cross beam and a second cross beam are arranged between the first side plate and the second side plate, the second cross beam is positioned below the first cross beam, a synchronizing shaft is arranged on one side, far away from the first cross beam, of the second side plate, a first synchronizing wheel and a second synchronizing wheel are fixed on the surface of the synchronizing shaft, the first synchronizing wheel is positioned on any side of the first cross beam, the second synchronizing wheel is positioned on any side of the second cross beam, the first synchronizing wheel and the second synchronizing wheel are coaxial, the diameter and the number of teeth are equal, a first driving belt is connected on the surface of the first synchronizing wheel, a second driving belt is connected on the surface of the second synchronizing wheel, the synchronizing shaft can be opened when a device runs, the synchronizing shaft can drive the first synchronizing wheel and the second synchronizing wheel to rotate, and the first synchronizing wheel and the second synchronizing wheel are coaxial, the diameter and the number of teeth are equal, therefore, the first transmission belt and the second transmission belt are respectively driven to rotate, and the relative moving amplitude of the first transmission belt and the second transmission belt is consistent, so that the synchronization rate of the device can be improved.

According to the technical scheme, the mounting plate is installed on one side of the original cross beam I of the side plate II, the motor is installed at one end of the mounting plate, the driving wheel is installed on the surface of the synchronizing shaft, and the driving belt is connected between the driving wheel and the output shaft of the motor.

According to the technical scheme, one side of the first side plate, which is far away from the first cross beam, is provided with the first synchronous box and the second synchronous box, the first synchronous box is internally provided with the first driven shaft, the first driven shaft is arranged on the surface of the first driven shaft, the first driving belt is in transmission connection with the driven wheel, the second synchronous box is internally provided with the second driven shaft, the surface of the second driven shaft is provided with the second driven wheel, the second driving belt is in transmission connection with the second driven wheel, and the diameter and the number of teeth of the first driven wheel and the second driven wheel are equal.

According to the technical scheme, the first sliding block is connected to the surface of the first cross beam in a sliding mode, the first sliding block is fixed to one side, close to the motor, of the first transmission belt, a first sliding hole is formed in one side, away from the motor, of the first sliding block, the second sliding block is connected to the surface of the second cross beam in a sliding mode, the second sliding block is fixed to one side, close to the motor, of the second transmission belt, and a second sliding hole is formed in one side, away from the motor, of the second sliding block.

According to the technical scheme, the first detection head is installed at one end, close to the second sliding block, of the first sliding block, the second detection head is installed at one end, close to the first sliding block, of the second sliding block, and the first detection head and the second detection head are aligned with each other.

According to the technical scheme, the first support is arranged on one side, close to the motor, of the first side plate and the second side plate, the second support is arranged on one side, away from the motor, of the first side plate and the second side plate, the first conveying shaft is arranged between the first supports, and the second conveying shaft is arranged between the second supports.

Compared with the prior art, the utility model discloses the beneficial effect who reaches is: the synchronous shaft is arranged, when the device runs, the synchronous shaft can be opened, the synchronous shaft can drive the first synchronous wheel and the second synchronous wheel to rotate, the first synchronous wheel and the second synchronous wheel are coaxial, the diameters and the number of teeth are equal, the first synchronous wheel and the second synchronous wheel can respectively drive the first transmission belt and the second transmission belt to rotate, and the relative moving amplitude of the first transmission belt and the second transmission belt is consistent, so that the synchronization rate of the device can be improved.

Drawings

The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention, and together with the description serve to explain the invention and not to limit the invention. In the drawings:

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

FIG. 2 is a schematic view of the enlarged structure of the area A of the present invention;

in the figure: 1. a base; 2. a first side plate; 3. a second side plate; 4. detecting a first probe; 5. a second detection head; 6. a first bracket; 7. a second bracket; 8. a second transmission shaft; 9. a first cross beam; 10. a second cross beam; 11. a first sliding block; 12. a second sliding block; 13. a first sliding hole; 14. a second sliding hole; 15. a first transmission belt; 16. a second transmission belt; 17. mounting a plate; 18. a motor; 19. a drive wheel; 20. a drive belt; 21. a synchronizing shaft; 22. a first synchronizing wheel; 23. a second synchronizing wheel; 24. a second synchronization box; 25. a first synchronization box; 26. a first driven shaft; 27. a driven wheel I; 28. and a first transmission shaft.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-2, the present invention provides a technical solution: the utility model provides a O type thickness measuring scanner is with many area motion of unipolar structure, the on-line screen storage device comprises a base 1, curb plate one 2 and curb plate two 3 are for setting up in pairs, install crossbeam one 9 and crossbeam two 10 between curb plate one 2 and the curb plate two 3, crossbeam two 10 is located the below of crossbeam one 9, one side that crossbeam one 9 was kept away from to curb plate two 3 is provided with synchronizing shaft 21, synchronizing shaft 21's fixed surface has synchronizing wheel one 22 and synchronizing wheel two 23, synchronizing wheel one 22 is located the arbitrary one side of crossbeam one 9, synchronizing wheel two 23 is located arbitrary one side of crossbeam two 10, synchronizing wheel one 22 is coaxial and the diameter number of teeth equals with synchronizing wheel two 23, synchronizing wheel one 22's surface is connected with drive belt one 15, synchronizing wheel two 23's surface is connected with drive belt two 16.

First detection head 4 is installed to the one end that second sliding block 12 is close to of first sliding block 11, and second detection head 5 is installed to the one end that second sliding block 12 is close to of first sliding block 11, and first detection head 4 aligns each other with second detection head 5.

One side of the first side plate 2 and one side of the second side plate 3 close to the motor 18 are provided with a first support 6, one side of the first side plate 2 and one side of the second side plate 3 far away from the motor 18 are provided with a second support 7, a first conveying shaft 28 is installed between the two first supports 6, and a second conveying shaft 8 is installed between the two second supports 7.

The side plate II 3 is provided with an installation plate 17 on one side of the original cross beam I9, one end of the installation plate 17 is provided with a motor 18, the surface of a synchronizing shaft 21 is provided with a driving wheel 19, and a driving belt 20 is connected between the driving wheel 19 and an output shaft of the motor 18.

One side of the first side plate 2, which is far away from the first cross beam 9, is provided with a first synchronous box 25 and a second synchronous box 24, the first synchronous box 25 is internally provided with a first driven shaft 26, the surface of the first driven shaft 26 is provided with a first driven wheel 27, the first driving belt 15 is in transmission connection with the first driven wheel 27, the second synchronous box 24 is internally provided with a second driven shaft, the surface of the second driven shaft is provided with a second driven wheel, the second driving belt 16 is in transmission connection with the second driven wheel, and the first driven wheel 27 and the second driven wheel have the same diameter and tooth number.

The surface of the first cross beam 9 is connected with a first sliding block 11 in a sliding mode, the first sliding block 11 is fixed to one side, close to the motor 18, of the first transmission belt 15, a first sliding hole 13 is formed in one side, away from the motor 18, of the first sliding block 11, the surface of the second cross beam 10 is connected with a second sliding block 12 in a sliding mode, the second sliding block 12 is fixed to one side, close to the motor 18, of the second transmission belt 16, and a second sliding hole 14 is formed in one side, away from the motor 18, of the second sliding block 12.

The working principle is as follows: when the thickness of a product needs to be detected, the product can be placed on the first conveying shaft 28 and the second conveying shaft 8, the product can be conveyed forwards by the first conveying shaft 28 and the second conveying shaft 8, the product stops after being conveyed to an area needing to be detected, then the motor 18 can be started, the output shaft of the motor 18 can drive the driving belt 20 to rotate, the driving belt 20 can drive the driving wheel 19 to rotate, the driving wheel 19 can drive the synchronizing shaft 21 to rotate, the first synchronizing wheel 22 and the second synchronizing wheel 23 on the surface of the synchronizing shaft 21 can rotate along with the same, and at the moment, the first synchronizing wheel 22 and the second synchronizing wheel 23 are coaxial and have the same diameter and tooth number, so that the rotating amplitudes of the first synchronizing wheel 22 and the second synchronizing wheel 23 are consistent.

Meanwhile, the first synchronous wheel 22 drives the first transmission belt 15 to rotate around the first driven wheel 27, the second synchronous wheel 23 drives the second transmission belt 16 to rotate around the second driven wheel, and the relative moving amplitude of the first transmission belt 15 between the first synchronous wheel 22 and the first driven wheel 27 is consistent with the relative moving amplitude of the second transmission belt 16 between the second synchronous wheel 23 and the second driven wheel as the number of the diameter teeth of the first driven wheel 27 is equal to that of the second driven wheel.

When the first transmission belt 15 rotates, the first transmission belt can pull the first sliding block 11 to move towards the second side plate 3, meanwhile, the second transmission belt 16 can synchronously pull the second sliding block 12 to move towards the second side plate 3, at the moment, the first detection head 4 below the first sliding block 11 and the second detection head 5 above the second sliding block 12 can move towards the second side plate 3 together, the thickness of a product crossing the surface of the whole conveying shaft can be detected, the synchronous rate between the first detection head 4 and the second detection head 5 is high, and the condition that detection data are inaccurate due to different moving speeds between the first detection head 4 and the second detection head 5 can be reduced.

After the data detection of the area is finished, the motor 18 can be closed, then each conveying shaft is opened, the product is conveyed to the next area to be detected, the motor 18 is opened again in the reverse direction, at the moment, each driving belt rotates in the reverse direction, the first detection head 4 and the second detection head 5 are pulled towards the first side plate 2, and therefore the cyclic use effect can be achieved.

Meanwhile, when the width of the product to be detected is small, the first detection head 4 and the second detection head 5 can be moved to the product, then the first conveying shaft 28 and the second conveying shaft 8 are started, and the product continuously passes through the detection area between the first detection head 4 and the second detection head 5, so that the thickness data of the product can be continuously detected.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described in the foregoing embodiments, or equivalents may be substituted for elements thereof. 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 (6)

1. The utility model provides a O type thickness measurement is unipolar many areas motion structure for scanner, includes base (1), curb plate one (2) and curb plate two (3), its characterized in that: curb plate (2) and curb plate two (3) are set up in pairs, install crossbeam (9) and crossbeam two (10) between curb plate (2) and the curb plate two (3), crossbeam two (10) are located the below of crossbeam (9), one side that crossbeam (9) were kept away from in curb plate two (3) is provided with synchronizing shaft (21), the fixed surface of synchronizing shaft (21) has synchronizing wheel (22) and synchronizing wheel two (23), synchronizing wheel (22) are located arbitrary one side of crossbeam (9), synchronizing wheel two (23) are located arbitrary one side of crossbeam two (10), synchronizing wheel (22) are coaxial and the diameter number of teeth equals with synchronizing wheel two (23), the surface of synchronizing wheel (22) is connected with drive belt (15), the surface of synchronizing wheel two (23) is connected with drive belt two (16).

2. The single-axis multi-band motion structure for the O-type thickness measuring scanner according to claim 1, wherein: mounting panel (17) are installed to one side of curb plate two (3) original crossbeam one (9), motor (18) are installed to the one end of mounting panel (17), the surface mounting of synchronizing shaft (21) has drive wheel (19), be connected with driving band (20) between the output shaft of drive wheel (19) and motor (18).

3. The single-axis multi-band motion structure for the O-type thickness measuring scanner according to claim 1, wherein: one side that crossbeam (9) was kept away from in curb plate one (2) is installed synchronous case (25) and synchronous case two (24), the internally mounted of synchronous case (25) has driven shaft one (26), the surface mounting of driven shaft one (26) has from driving wheel one (27), drive belt one (15) are connected with from driving wheel one (27) transmission, the internally mounted of synchronous case two (24) has driven shaft two, the surface mounting of driven shaft two has from driving wheel two, drive belt two (16) are connected with from driving wheel two transmissions, from driving wheel one (27) and from driving wheel two diameter teeth number equal.

4. The single-axis multi-band motion structure for the O-type thickness measuring scanner according to claim 1, wherein: the surface sliding connection of crossbeam one (9) has sliding block one (11), sliding block one (11) is fixed with one side that drive belt one (15) is close to motor (18), sliding hole one (13) have been seted up to one side that motor (18) were kept away from in sliding block one (11), the surface sliding connection of crossbeam two (10) has sliding block two (12), sliding block two (12) are fixed with one side that drive belt two (16) are close to motor (18), sliding hole two (14) have been seted up to one side that motor (18) were kept away from in sliding block two (12).

5. The single-axis multi-band motion structure for the O-type thickness measuring scanner according to claim 4, wherein: first (4) are installed to the one end that sliding block one (11) are close to sliding block two (12), sliding block two (12) are close to the one end of sliding block one (11) and are installed and detect first two (5), detect first (4) and detect first two (5) and align each other.

6. The single-axis multi-band motion structure for the O-type thickness measuring scanner according to claim 5, wherein: one side that curb plate (2) and curb plate two (3) are close to motor (18) all is provided with support (6), one side that motor (18) were kept away from in curb plate (2) and curb plate two (3) all is provided with support two (7), two install conveying axle one (28), two between support (6) install conveying axle two (8) between support two (7).

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