CN214621119U - I-shaped wheel flatness detection device - Google Patents

Abstract

The utility model discloses a spool plane degree detection device, including testing platform, testing platform on be provided with the frame, the last drive assembly that is provided with of testing platform, two pterygoid lamina settings of spool are rotatory on drive assembly and by the drive assembly drive, the outside center of two pterygoid laminas of spool offsets with first follow-up disc and second follow-up disc respectively, the rotation axis activity of first follow-up disc is connected with the flexible end in the tight cylinder in top, the tight cylinder in top sets up in the frame, the rotation axis activity of second follow-up disc sets up in the frame, the top card of the pterygoid lamina of spool is established on testing assembly. The flatness of the wing plate of the spool can be accurately detected, and the detection efficiency is high; the method can be suitable for detecting the flatness of wing plates of I-shaped wheels with different diameters and different widths; the labor intensity of workers is low, and the operation is simple and labor-saving.

Description

I-shaped wheel flatness detection device

Technical Field

The utility model relates to a flatness detects technical field, especially relates to a I-shaped wheel flatness detection device.

Background

After the tire bead steel wire is produced, the tire bead steel wire is wound on the spool, the spool is used as a carrier to be stored and transported, and after the tire bead steel wire is used, the spool needs to be returned to a factory to be used for winding the steel wire again. The spool is easy to deform in the turnover use process from a manufacturer to a client and then to the manufacturer, so that the normal use of the spool is influenced. Therefore, the flatness of the wing plate of the spool needs to be detected after the spool is returned to the factory.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a I-shaped wheel plane degree detection device to the above-mentioned problem that prior art exists. The problem of the flatness of I-shaped wheel pterygoid lamina detect is solved.

In order to achieve the above object, the utility model adopts the following technical means:

the utility model provides a spool plane degree detection device, includes testing platform, testing platform on be provided with the frame, testing platform is last to be provided with drive assembly, two pterygoid laminas of spool set up on drive assembly and rotatory by drive assembly drive, the outside center of two pterygoid laminas of spool offsets with first follow-up disc and second follow-up disc respectively, the rotation axis activity of first follow-up disc is connected with the flexible end of the tight cylinder in top, the tight cylinder in top sets up in the frame, the rotation axis activity of second follow-up disc sets up in the frame, the top card of the pterygoid lamina of spool is established on testing assembly.

The driving assembly comprises a follow-up roller, a driving motor and a driving roller, the driving roller and the follow-up roller are arranged in parallel, a rotating shaft of the driving roller is connected with a rotating shaft of the driving motor, and the bottoms of two wing plates of the spool are erected on the driving roller and the follow-up roller.

The detection assembly comprises a guide rail, a sliding block and a detection unit, the guide rail is arranged on the rack, the sliding block is in adaptive connection with the guide rail, the detection unit is connected with the sliding block, the detection unit comprises a support, a follow-up spool and a proximity switch, the support is connected with the sliding block, a rotating shaft of the follow-up spool is movably arranged on the support, the top of a wing plate of the spool is clamped on the follow-up spool, the proximity switch is located on two sides of a trigger bulge on the support, and the proximity switch is arranged on the guide rail.

Compared with the prior art, the utility model, following beneficial effect has:

1. the flatness of the wing plate of the spool can be accurately detected, and the detection efficiency is high;

2. the method can be suitable for detecting the flatness of wing plates of I-shaped wheels with different diameters and different widths;

3. the mounting height of the detection platform is parallel and level with the ground, the labor intensity of workers is low, and the operation is simple and labor-saving.

Drawings

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

FIG. 2 is a second schematic view of the overall structure of the present invention;

fig. 3 is a front view schematically illustrating the present invention;

FIG. 4 is a schematic structural diagram of a driving assembly;

FIG. 5 is a schematic structural view of the tightening assembly;

fig. 6 is a schematic structural diagram of the detection assembly.

In the figure: 1-a drive assembly; 2-a jacking assembly; 3-a detection component; 4-a frame; 5-spool; 6-detection platform.

1.1-a follow-up roller; 1.2-driving the motor; 1.3-driving roller;

2.1-a first follower disk; 2.2-tightly pushing the cylinder; 2.3-a second follower disk;

3.1-guide rail; 3.2-sliding block; 3.3-a detection unit; 3.31-scaffold; 3.32-follow-up spool; 3.33-proximity switch; 3.34-trigger bump.

Detailed Description

To facilitate understanding and practice of the invention by those of ordinary skill in the art, the following detailed description of the invention is provided in connection with the examples, and it is to be understood that the examples described herein are for purposes of illustration and explanation only and are not intended to limit the invention.

The utility model provides a spool plane degree detection device, includes testing platform 6, testing platform 6 on be provided with frame 4, testing platform 6 is last to be provided with drive assembly 1, two pterygoid laminas of spool 5 set up on drive assembly 1 and by drive assembly 1 drive rotation, the outside center of two pterygoid laminas of spool 5 offsets with first follow-up disc 2.1 and second follow-up disc 2.3 respectively, the rotation axis activity of first follow-up disc 2.1 is connected with the flexible end of tight cylinder 2.2 in top, the tight cylinder 2.2 in top sets up on frame 4, the rotation axis activity of second follow-up disc 2.3 sets up on frame 4, the top card of the pterygoid lamina of spool 5 is established on testing assembly 3.

When the device works, a worker pushes the spool 5 onto the driving assembly 1, the spool 5 is driven to rotate by friction force of two wing plates of the spool 5 and the driving assembly 1, the rotating shaft of the first follow-up disc 2.1 is movably connected with the telescopic end of the jacking cylinder 2.2, the first follow-up disc 2.1 can rotate by taking the rotating shaft as a rotating center, when the first follow-up disc 2.1 is pressed and abutted to the outer center of the wing plates, the first follow-up disc can be driven to rotate by the rotating wing plates, the rotating shaft of the second follow-up disc 2.3 is movably arranged on the rack 4, similarly, the second follow-up disc 2.3 can rotate by taking the rotating shaft as the rotating center, and when the second follow-up disc 2.3 is pressed and abutted to the outer center of the wing plates, the second follow-up disc can be driven to rotate by the rotating wing plates. Through the flexible end of control top tight cylinder 2.2, spacing spool 5 between first follow-up disc 2.1 and second follow-up disc 2.3, the top tight power that the flexible end of top tight cylinder 2.2 provided sets up lessly, only plays restriction spool 5 and removes about, can not lead to the spool 5 because frictional force between first follow-up disc 2.1, second follow-up disc 2.3 and the pterygoid lamina is too big, and it is overhead by first follow-up disc 2.1 and second follow-up disc 2.3 to lead to the spool 5 because frictional force. The top of the wing plate of the spool 5 is clamped on the detection component 3, and the detection component 3 detects the flatness of the wing plate.

The driving assembly 1 comprises a follow-up roller 1.1, a driving motor 1.2 and a driving roller 1.3, the driving roller 1.3 and the follow-up roller 1.1 are arranged in parallel, a rotating shaft of the driving roller 1.3 is connected with a rotating shaft of the driving motor 1.2, and the bottoms of two wing plates of the I-shaped wheel 5 are erected on the driving roller 1.3 and the follow-up roller 1.1.

The driving motor 1.2 drives the driving roller 1.3 to rotate, two wing plates of the spool 5 are erected on the driving roller 1.3 and the following roller 1.1 and are perpendicular to the central shafts of the driving roller 1.3 and the following roller 1.1, the driving roller 1.3 drives the two wing plates of the spool 5 to rotate through friction force, the two wing plates of the spool 5 drives the following roller 1.1 to rotate through friction force,

the detection assembly 3 comprises a guide rail 3.1, a sliding block 3.2 and a detection unit 3.3, the guide rail 3.1 is arranged on the rack 4, the sliding block 3.2 is in adaptive connection with the guide rail 3.1, the detection unit 3.3 is connected with the sliding block 3.2, the detection unit 3.3 comprises a support 3.31, a follow-up spool 3.32 and a proximity switch 3.33, the support 3.31 is connected with the sliding block 3.2, a rotating shaft of the follow-up spool 3.32 is movably arranged on the support 3.31, the top of a wing plate of the spool 5 is clamped on the follow-up spool 3.32, the proximity switch 3.33 is positioned on two sides of a trigger bulge 3.34 on the support 3.31, and the proximity switch 3.33 is arranged on the guide rail 3.1.

The number of the sliding blocks 3.2 and the number of the detection units 3.3 can be two, and the two detection units 3.3 are respectively in adaptive connection with the tops of the two wing plates of the spool 5. The rotating shaft of the follow-up spool 3.32 is movably arranged on the support 3.31, the follow-up spool 3.32 can rotate around the rotating shaft, but the follow-up spool 3.32 cannot move relative to the support 3.31 along the axial direction of the rotating shaft of the follow-up spool 3.32, the top of the wing plate of the spool 5 is clamped on the follow-up spool 3.32, when the wing plate is uneven, the follow-up spool 3.32 and the support 3.31 can be driven to integrally move left and right, and when the left and right movement amplitude is larger than a set required amplitude, the trigger bulge 3.34 on the support 3.31 can trigger the proximity switches 3.33 arranged on the left side and the right side, so that an alarm is realized, and the flatness of the wing plate is not up to standard. Preferably, the fixing position of the proximity switch 3.33 on the guide rail 3.1 is adjustable, and the position of the sliding block 3.2 on the guide rail 3.1 is adjusted to adapt to detection of spools with different sizes. The mounting height of the detection platform 6 is flush with the ground, the labor intensity of workers is low, and the operation is simple and labor-saving.

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 may be made by those skilled in the art without departing from the spirit of the invention or exceeding the scope of the invention as defined in the accompanying claims.

Claims (3)

1. The utility model provides a spool plane degree detection device, is including detecting platform (6), a serial communication port, detect platform (6) on be provided with frame (4), be provided with drive assembly (1) on detecting platform (6), two pterygoid lamina settings of spool (5) are rotatory by drive assembly (1) drive on drive assembly (1), the outside center of two pterygoid laminas of spool (5) offsets with first follow-up disc (2.1) and second follow-up disc (2.3) respectively, the rotation axis activity of first follow-up disc (2.1) is connected with the flexible end of tight cylinder (2.2) in top, tight cylinder (2.2) in top sets up on frame (4), the rotation axis activity of second follow-up disc (2.3) sets up on frame (4), the top card of the pterygoid lamina of spool (5) is established on detecting assembly (3).

2. The I-shaped wheel flatness detecting device according to claim 1, characterized in that the driving assembly (1) comprises a following roller (1.1), a driving motor (1.2) and a driving roller (1.3), the driving roller (1.3) and the following roller (1.1) are arranged in parallel, a rotating shaft of the driving roller (1.3) is connected with a rotating shaft of the driving motor (1.2), and bottoms of two wing plates of the I-shaped wheel (5) are erected on the driving roller (1.3) and the following roller (1.1).

3. The spool flatness detection apparatus according to claim 1, wherein the detection assembly (3) includes a guide rail (3.1), a slider (3.2) and a detection unit (3.3), the guide rail (3.1) is disposed on the rack (4), the slider (3.2) is in adaptive connection with the guide rail (3.1), the detection unit (3.3) is connected with the slider (3.2), the detection unit (3.3) includes a bracket (3.31), a follower spool (3.32) and a proximity switch (3.33), the bracket (3.31) is connected with the slider (3.2), a rotation shaft of the follower spool (3.32) is movably disposed on the bracket (3.31), a top of a wing plate of the spool (5) is clamped on the follower spool (3.32), the proximity switch (3.33) is disposed on both sides of a trigger protrusion (3.34) on the bracket (3.31), and the proximity switch (3.33) is disposed on the guide rail (3.1).

Images