KR20130031476A - Apparatus for defect detection of rod shaped body - Google Patents

Abstract

PURPOSE: A device for the defect detection of a rod shaped body is provided to reduce time and effort for measurement by simply measuring straightness, roundness, or surface defects. CONSTITUTION: A device for the defect detection of a rod shaped body comprises a housing(100), a camera(30), laser scanners(40a,40b), and a motor(50). The housing forms a through-hole(20) through which a rod shaped body(10) passes in the rotary shaft of both sides. The camera is mounted inside the housing. The laser scanner is fixed inside the housing. The motor rotates the housing.

Description

Device for measuring defects of rod-shaped body {APPARATUS FOR DEFECT DETECTION OF ROD SHAPED BODY}

The present invention relates to a device for measuring the surface defects and straightness of the rod-shaped body, more specifically, it is possible to easily measure the surface defects, straightness and roundness of the rod-shaped body at a time to measure the time and effort required for the measurement. The present invention relates to a device for measuring defects of a rod-shaped body which can not only significantly reduce but also provide a highly reliable effect on measurement results.

Linear materials such as metal rods or metal steel pipes (hereinafter collectively referred to as rod-shaped bodies) are widely used in various industries. These materials are often required to have high precision straightness in accordance with the intended use, and to be free from various defects on the surface, for example, scratches, digging, protrusions, and the like.

Up to now, the straightness test and the surface defect test method for these rod-shaped bodies have to be carried out by loading each product into each inspection device one by one to measure each individual unit. Performing a full inspection is physically limited.

Therefore, there is a demand for the development of an inspection technology capable of automatically measuring the straightness and roundness with surface defects in real time for linear materials produced in large quantities.

The present invention has been made to solve the problems of the prior art as described above, the object is to easily measure the surface defects, straightness or roundness of the rod-like body at a time and the time required for the measurement The present invention provides a device for measuring defects of a rod-shaped body that not only significantly reduces the effort but also provides a highly reliable effect on the measurement result.

The technical problem of the present invention as described above is achieved by the following means.

(1) a housing 100 having a through hole 20 through which the rod-shaped body 10 penetrates on both sides of the rotation shaft; The rod-shaped body 10 is mounted inside the housing 100 and is fixed to the inside of the housing 100 at an upper portion of the rod-shaped body 10 moving through the through hole 20 while rotating about the rod-shaped body 10. A camera 30 and an illumination 31 for imaging the surface of the camera; A laser scanner 40 fixed to the inside of the housing 100 to measure straightness to roundness while rotating about a rod-shaped body together; And a motor (50) for rotating the housing (100).

(2) The method according to claim 1,

The camera and the light is a defect measuring device of the rod-shaped body, characterized in that installed on each side on the basis of the structure.

(3) The method according to claim 1,

The housing is a defect measuring device of the rod-shaped body, characterized in that the balancing device 200 is connected so that the rotation of both sides at the same time balanced.

(4) The method according to 1,

The camera is a defect measuring apparatus of the rod-shaped body, characterized in that the transfer member 60 is coupled to move back and forth in the direction of the rod-shaped body.

According to the present invention as described above, it is possible to measure the surface defects, straightness, roundness, etc. of the rod-like body at a time simply, significantly reducing the time and effort required for the measurement, as well as the reliability of the measurement results Very high effect.

1 is a perspective view of a rod-shaped body defect measuring apparatus according to the present invention.
2 is a front view of a defect measuring apparatus of a rod-shaped body according to the present invention.
3 is a side view of a defect measuring apparatus of a rod-shaped body according to the present invention.
Figure 4 shows an embodiment of the camera transfer member constituting the defect measuring apparatus of the rod-shaped body according to the present invention.

The present invention is a housing 100 formed with a through hole 20 through which the rod-shaped body 10 penetrates on both sides of the rotation shaft; The rod-shaped body 10 is mounted inside the housing 100 and is fixed to the inside of the housing 100 at an upper portion of the rod-shaped body 10 moving through the through hole 20 while rotating about the rod-shaped body 10. A camera 30 and an illumination 31 for imaging the surface of the camera; A laser scanner 40 fixed to the inside of the housing 100 to measure straightness to roundness while rotating about a rod-shaped body together; And a motor (50) for rotating the housing (100).

Hereinafter, the content of the present invention will be described in more detail with reference to FIGS. 1 to 3.

The defect measuring apparatus of the rod-shaped body according to the present invention is configured to measure the surface defects and straightness to roundness of the rod-shaped body 10 at the same time.

To this end, the measuring device of the present invention includes an image pickup unit including a camera 30 and an illumination 31 rotating together with the rotating drum-shaped housing 100, and a laser scanner 40 mounted at a predetermined position inside the drum. It is done. Preferably, the camera 30 and the laser scanner 40 are fixedly installed at intervals of 90 kPa on the circumference, respectively.

The camera 30 is a line scan camera or an aerial scan camera. Preferably, the camera 30 checks the inlet hole 20a of the through hole 20 formed on the central axis of one side of the housing 100 for measurement. It is arranged to photograph the entire length of the inflow.

Preferably, the camera 30 has a pair of cameras opposite to each other with the rod-shaped body 10 interposed therebetween so that the camera 30 can be divided and photographed with respect to the rod-shaped body 10 introduced through the inlet 20a in the housing. In the horizontal direction so as to be arranged in the wider area can be taken in a quick time (see Figure 3).

The camera 30 is preferably coupled to the transfer member 60 installed inside the housing so as to obtain a precise surface image according to the diameter of the rod-like body to be controlled to be able to move back and forth with respect to the structure.

The transfer member 60 may be manually adjusted to its position, and automatically moved to its position by a controller (not shown) so that the position can be moved by a predetermined length using the diameter of the rod-shaped body 10 as an input value. It is also possible to adjust it.

The transfer member 60 is composed of a rack and pinion gear driven by a step motor mounted in the drum, or is connected to the sock end of the housing by a pair of upper and lower link members 61 as shown in FIG. The horizontal movement of the camera may be implemented so that the vertical movement.

As a data processing process of an image photographed from the camera 30, a known image processing process may be used. For example, the photographed image is transmitted to an image processing board and converted into a digital signal. Image processing boards are currently available or can be used with any of the types of image processing board types modified by the user for some specific applications. The image processing board transmits the converted image digital signal to the image processor through a PCI bus.

The image processor may detect whether there is a surface defect, process image data to calculate a result value, and display the detection result on a screen through a graphical user interface that is easy for the user to see.

The laser scanner 40 includes a laser light emitting unit 40a and a laser light receiving unit 40b, and the light emitting unit 40a and the light receiving unit 40b are installed in the housing so as to face each other with the bar-shaped body 10 interposed therebetween. The laser scanner 40 is fixed at a predetermined position in the housing 100 and rotates together with the housing to perform a circular motion using the rod-shaped body 10 introduced into the housing as a rotation axis.

When the rod-shaped body 10 rotates in the above process, the laser is irradiated toward the rod-shaped body 10 from the laser light emitting unit 40a constituting the laser scanner 40 and receives the light incident on the opposite light receiving unit 40b. The height and diameter of the rod-shaped body 10 are measured.

In this case, when the rod-shaped body 10 has a normal straightness, the heights measured in all the lengths are the same, and in the case of the presence of the 휜 part at any part, a change in the height of the structure is detected at a specific angle range during the rotation. .

The roundness may be measured by analyzing the value of the laser scanner 40 as described above, calculating the diameter, and calculating the diameter difference for each angle.

In the defect measuring apparatus of the rod-shaped body according to the present invention, the camera 30 and the laser scanner 40 are installed in the housing 100 together, preferably spaced apart at intervals of 90 함께, together with the housing 100. It is possible to measure surface defects and straightness to roundness at the same time for the length section of the rod-shaped body 10 introduced into the housing while rotating, so that any defects that may exist over the entire length of the rod-shaped body can be measured quickly and accurately. You can do it.

Through-holes 20 formed on both sides of the housing 100 are composed of an inlet 20a and an outlet 20b, the rod-shaped body 10 is fed to the inlet 20a to the camera 30 and the laser scanner 40 ) Rotates with the housing to measure the surface inspection and straightness to roundness for all points of the rod-shaped body 10 in real time.

It is preferable that the housing 100 is formed in a drum shape, and the pulley 51 is formed on a rotation shaft of one side of both sides, and the belt 52 and the motor 50 can be connected thereto to rotate the housing. In this case, the balancing device 200 may be connected separately to equally adjust the rotation of the wheels constituting both sides. At this time, the balancing device 200 may be applied to any equipment that can be used conventionally to balance the wheel of the automobile tire.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. It can be understood that

10: rod-shaped body
20: through hole
30: Camera
40: laser scanner
50: Motor
100: Housing

Claims (4)

A housing 100 having a through hole 20 through which the rod-shaped body 10 penetrates on both sides of the rotation shaft; The rod-shaped body 10 is mounted inside the housing 100 and is fixed to the inside of the housing 100 at an upper portion of the rod-shaped body 10 moving through the through hole 20 while rotating about the rod-shaped body 10. A camera 30 and an illumination 31 for imaging the surface of the camera; A laser scanner 40 fixed to the inside of the housing 100 to measure straightness to roundness while rotating about a rod-shaped body together; And a motor (50) for rotating the housing (100). The method of claim 1,
The camera and the light is a defect measuring device of the rod-shaped body, characterized in that installed on each side on the basis of the structure. The method of claim 1,
The housing is a defect measuring device of the rod-shaped body, characterized in that the balancing device 200 is connected so that the rotation of both sides at the same time balanced. The method of claim 1,
The camera is a defect measuring apparatus of the rod-shaped body, characterized in that the transfer member 60 is coupled to move back and forth in the direction of the rod-shaped body.

Images