KR101479857B1 - Automated inspection system for automobile parts - Google Patents

Abstract

The present invention relates to an automation testing device for vehicle components. More specifically, the device is formed of a body part (100) formed of an inlet (110) into which a product is inserted and an outlet (120) from which the product is discharged; a testing part (200) testing a bearing hole and the exterior of the product on an upper side of the body part (100); a work system part (300) formed of a bearing pressing and fitting device (310) formed as a side of the testing part (200) but pressing and fitting a bearing (b) into the bearing hole of the product; a step testing part (320) testing a step into which the bearing (b) is pressed and a processed part of the product; and a laser marking part (330) marking a side of the product with laser, and a transfer part (400) formed on the upper side of the body part (100) but transferring the product by being formed as a front surface of the work system part (300) such that a test on the product is automatically conducted. Thus, as each process is integrated, time to process is reduced, costs are reduced, and the failure rate is reduced as well such that productivity is maximized besides increasing in sales.

Description

[0001] Automated inspection system for automobile parts [0002]

More particularly, the present invention relates to an automatic inspection apparatus for automobile parts, and more particularly, to an automatic inspection apparatus for automobile parts, And an automation inspection apparatus for automobile parts having high economic efficiency which can maximize productivity by reducing defective rate.

In order to inspect machined workpieces which are usually used as parts of automobiles, an operator inspects workpieces processed by the naked eye, judges good goods, presses the bearings, inspects the stepped portions of the bearings, . However, in these works, most of the workers are not only required to work, but also because they have to look at the work pieces in the eye, and there is a lot of fatigue in the eyes, There was a falling factor.

First of all,

[0001] The present invention relates to an apparatus for press-fitting a bearing into an upper portion and a lower portion of an assembly, comprising: a press-in portion for press-fitting two bearings into an assembly placed at a press-in position; and a pallet A pallet transfer line which is divided into a supply section and a discharge section around the standby position, and a press-fit assembly provided between the standby position of the transfer line and the press-in position of the press- And a bearing supplying portion for simultaneously supplying bearings to upper and lower portions of the assembly placed at the press fitting position of the press fitting portion.

Registration No. 10-0613896 (Special) A sealed inspection room that blocks external light, one or more cameras installed in the inspection room, and lighting to supply the light source required for shooting, And a control unit for controlling the parts of the vehicle to be inspected in the inspection room based on the images captured by the camera, , A hole in the automobile part for seating the automobile part

A jig including a jig pin to be fitted, a product presence / absence detecting sensor for determining whether the component is seated, and an electromagnet for fixing a component seated on the jig pin; A guide unit for moving the jig into the inspection room; A controller for receiving an image of an automotive part photographed by the camera and comparing the coordinate value of the photographed image with a coordinate value of an image corresponding to a predetermined good product photographing screen of the inspection object to determine whether the automotive part is defective or not; And a monitor for displaying the photographed image and the related information of the automobile part by an operation signal of the control part.

A marking method of a fiber laser marker comprising an optical pump for outputting an optical signal to a resonator and a galvanometer scanner for scanning the laser beam emitted from the resonator to a predetermined position, Of the laser beam from the resonator to the output of the laser beam,

Measuring a delay time of an output of the low beam; Moving the mirror of the galvano scanner to a next marking start point; Calculating the jump time at which the mirror of the galvano scanner is moved to a next marking start point; Calculating the delay time according to the jump time; Activating the optical pump to input the optical signal to the resonator, and waiting the mirror of the galvanometer scanner for the delay time; And driving and marking the mirror of the galvano scanner, wherein the laser beam delayed during the delay time is synchronously discharged together with the driving of the mirror of the galvano scanner.

According to the above-described conventional technique, bearings can be simultaneously fed on one assembly and then simultaneously press-fit in a single press-fitting operation. It is limited to press-fitting bearings into assemblies used in automobile parts. Function can not be performed.

As for other types of technologies, there is a description of an apparatus for inspecting an automobile parts using a vision system, in which an image of an actual object photographed by a camera and a predetermined object to be inspected are compared and analyzed to minimize a defect rate. However, There is a problem in that only a simple defect check can be performed as in the prior art described above, and other functions are not performed at all.

Another type of technology is a limited technology, although it is configured to perform laser marking but to prevent portions where marking is not performed.

Taking all of the above prior arts into consideration, they are optimized to perform indenting, inspection, and marking arbitrarily, but are technologies that can not integrally perform such functions.

Accordingly, it is an object of the present invention to provide an automation system in which a main body part is configured to automatically inflow and discharge a workpiece used as an automobile part, And the bearing inspection part which inspects the gap and the diameter of the bearing hole of the processed product judged as good product to constitute the inspection part for promptness and convenience A stepper inspecting device for inspecting the step of the bearing hole of the pressed bearing and the bearing hole of the workpiece, and a laser marking part for performing the laser marking on the workpiece after the step difference inspection is completed To be able to be automated as a whole. And to provide a device that can maximize the productivity as well as improving the efficiency of the system.

The main body 100 includes an inlet 110 into which a workpiece is inserted and a discharge 120 through which the workpiece is discharged. A bearing inserter 310 for inserting the bearing into the bearing hole of the workpiece 200, and a bearing insulator 310 for inserting the bearing into the bearing hole of the workpiece 200, And a laser marking unit 330 for marking the laser mark on one side of the workpiece. The laser marking unit 330 includes a work unit 300, And a transfer unit 400 configured to transfer the processed work to the discharge unit 120, the transfer unit 400 being disposed on one side of the upper surface of the work system unit 300.

According to the automatic inspection apparatus for an automotive part of the present invention, since the respective processes are integrated and processed as a whole, the running time can be reduced, the installation space and manufacturing cost of the apparatus can be reduced, Therefore, it is a useful invention to increase the economic efficiency by minimizing the defect rate caused by the manual operation as well as the increase of the sales in the future.

1 is a front view showing a preferred embodiment of the present invention;
2 is a plan view showing a preferred embodiment of the present invention.
3 is a top view of the inlet of the present invention
Fig. 4 is a front view showing the articulated robot of the present invention, an operating state diagram
5 is a plan view showing the bearing indenter of the present invention
6 is an operating state diagram showing the operation of the bearing indenter of the present invention
7 is an operating state diagram showing the operation of the bearing indenter of the present invention
8 is an operating state diagram showing the operation of the step difference checker of the present invention
Fig. 9 is an operational state diagram showing the operation of the conveyance portion of the present invention
Fig. 10 is an operational state diagram showing the operation of the conveyance portion of the present invention
11 is a plan view showing a configuration including an operating system unit and a control unit of the present invention

The present invention enables the processes of aluminum casting and external inspection of finished products, bearing assembly, step difference inspection and laser marking to be integrated, thereby shortening time for process procedure, cost reduction, The present invention provides an automation inspection apparatus for automotive parts having high economic efficiency.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention.

1 and 2, the inlet portion 110 and the outlet portion 120 are formed at both sides of the body 110. The inlet portion 110 and the outlet portion 120, (200) for inspecting an outer surface of the workpiece and a bearing hole on one side of the upper part of the main body part (100), and a bearing part of the inspection part (200) A stepper inspecting unit 320 for inspecting a machined part of the workpiece and a step where the bearing is press-fitted, and a laser marking unit 330 for laser marking at one side of the workpiece And a transfer unit 400 configured to transfer workpieces completed on the front surface of the work system unit 300 to the discharge unit 120. The transfer unit 400 includes a work system unit 300, do.

As shown in FIG. 3, the inlet 110 of the main body 100 has a rectangular shape, and a plurality of jigs 111 And the jig 111 is configured to rotate in the clockwise direction by the jumping member 112. The jig 111 is rotated by the jig 111 in the clockwise direction.

That is, when the worker places the workpiece on the plurality of jigs 111, the inflow unit 110 automatically operates the jig member 112 in the clockwise direction, The robot 300 is an automated apparatus that can perform the inspection one by one by the articulated robot 220 of FIG.

In the present invention, the inflow part 110 is operated in a clockwise direction. However, the inflow part 110 may be operated in a counterclockwise direction if necessary, or may be operated in a linear direction by applying a technique such as a conventional conveyor or a chain The present invention is not limited to the embodiments of the present invention.

The discharge unit 120 is also disposed on the other side of the inflow unit 110. The discharge unit 120 is also connected to the inspection unit 200 and the operation system unit 300 Is configured to perform a role of discharging finished workpieces, and is constituted by a conventional conveyor or a chain, and is shown as a conveyor in the present invention.

A stationary fixing part 101 for fixing and fixing workpieces in the lengthwise direction of the main body 100 is formed between the working system part 300 and the transfer part 400, So that the workpiece is picked up and transported. When the workpiece picked up is raised, the workpiece can be naturally seated and fixed to the seat fixing unit 101, And to fix the workpiece in progress.

As shown in FIGS. 1 and 2, the inspection unit 200 is configured to check the positions, diameters, and gaps of holes of a workpiece. Referring to the detailed configuration of the inspection unit 200, A camera 210 for photographing and recognizing the workpiece including a light emitting LED 211 on the side thereof and a bearing inspecting unit 230 for inspecting a diameter and an interval of a bearing hole formed in the workpiece, Joint robot 220 for positioning the robot 210 in the camera 210, inserting it in the bearing inspecting unit 230, inspecting it, and positioning it in the transfer unit 400.

In the case of the camera 210, when the articulated robot 220 picks up a workpiece and places the workpiece close to the camera 210, the conventional camera 210 is configured to recognize and recognize the workpiece, For example, a 2D data model can be generated using a camera having a resolution of 300,000 pixels or more, and it is preferable that the human body is composed of a camera that is bigger than the human eye and can be verified in detail.

The operator can inspect the screw hole and the thread by using the operating system unit 240, which is to be operated by the operator, through the camera 210.

In addition, a plurality of LEDs 211 are formed on one side of the camera 210 so that nighttime or dark portions can be identified and photographed.

The articulated robot 220 fixes the workpiece inserted through the inlet 110 and places the workpiece into the camera 210. After the camera 210 recognizes the workpiece, the bearing inspection unit 230 detects the diameter of the bearing hole 4, the articulated robot 220 has six axes, and is installed on one side of the inner lower surface of the main body 100, A first rotary support shaft 222 connected to an upper center portion of the rotary plate 221 and configured to flow in a semicircular arc shape is installed on the upper side of the rotary plate 221, Second, third, fourth, fifth, and sixth rotation supporting shafts 223, 224, 225, 226, and 227 that are installed at the ends of the shaft 222 are sequentially configured to flow in a semicircular arc shape, At the end of the rotation support shaft 227, To which 228 is configured.

The sixth rotary shaft 227 is configured to rotate in a direction different from that of the second rotary shaft 227, the second rotary shaft 227, the second rotary shaft 227, And is configured to rotate and flow in another direction.

That is, the articulated robot 220 is configured to be six-axis and freely flowed through the respective axes, so that even if the positions of the camera 210 and the bearing inspection unit 230 are variable, So that the camera 210 and the bearing inspection unit 230 can flow to enable recognition and inspection.

The articulated robot 220 is configured to flow in six axes. However, the articulated robot 220 may be configured to reduce or additionally use the number of shafts as needed, and the present invention is not limited to the embodiments of the present invention.

When the workpiece is positioned on the articulated robot 220, the bearing inspecting unit 230 inspects whether the diameter and the thread and the gap of the bearing hole are properly machined so that the air is ejected to the upper end, The air supply device is configured to be identified as defective if it becomes severe, and the air supply device for supplying air separately is not shown in the present invention.

As shown in FIG. 11, the inspection unit 200 further includes an operating system unit 240 connected to the inspection unit 200 so that the inspection unit 200 can visually check the status of the processed product. It is possible to easily conduct inspection through the operating system unit 240 and convenience is provided. Further software is installed in the operating system unit 240 to perform data history management and analysis So that the reliability of the product can be ensured.

Conventionally, in the inspection corresponding to the present invention, the workers list the products one by one and conduct inspection with the naked eye. However, as a result of human inspection, not only the defect rate of the products is very high but also the productivity is remarkably decreased.

However, since the inspection unit 200 of the present invention is constructed as an automated system, many workpieces can be inspected in a short time, thereby maximizing productivity and achieving accuracy.

The workpiece having been inspected through the inspection unit 200 pushes the bearing b into the workpiece through the work system unit 300 and performs the step difference inspection. The finished workpiece finally inspected is discharged from the main body 100 (120).

As shown in FIGS. 1 and 2, the operation system unit 300 includes a bearing indentifier 310 for pressing a bearing into a bearing hole of a workpiece inspected by the inspection unit 200. The bearing indenter 310 includes a bearing storage 311 for storing a plurality of bearings b and for flowing the aero bearing b as shown in Fig. 5, A bearing position fixing portion 312 for fixing the bearing b moved in the storage portion 311 and a bearing b fixed by the bearing position fixing portion 312, And the bearing b is press-fitted into the bearing hole of the workpiece conveyed by the articulated robot 220 of the inspection unit 200.

6, the bearings b inserted in the bearing storage part 311 for storing the first plurality of bearings are inserted into the bearing press-fitting part 313 as shown in FIG. 6, The bearing position fixing portion 313 positions the bearing b so as to be located on the same line as the lower end and then the bearing press-in portion 313 rides on the rail from the upper portion to the lower portion as shown in Fig. So that the bearing b is pressed into the workpiece.

By this operation, the bearing b can be press-fitted in a consistent and prompt manner, thereby maximizing the productivity.

The step checker 320 is configured to inspect the step on the machined part of the workpiece in which the bearing is press-fitted by the bearing presser 310. The step difference inspecting apparatus 320 is a normal step difference inspecting apparatus. The step difference inspecting apparatus 320 may constitute and fix a jig capable of fixing a work piece as shown in FIG. 8, and then may inspect the step difference. A common technique can be applied, and a step difference inspection of a portion where the bearing is press-fitted can be performed in addition to a step difference inspection on a machining portion. The step difference between the step (b) and the step (b) can be checked by the step difference inspection of the step difference inspecting device (320).

The laser marking unit 330 further includes a laser marking unit 330 for laser marking the workpiece having undergone the step difference inspection by the step difference inspection unit 320. The laser marking unit 330 marks the product for history management, So that the accuracy can be improved.

The work system part 300 described above can be combined as follows. The bearing b is pressed into the workpiece having been inspected in the inspection part 200, the step difference is checked with respect to the machined part, and finally the laser marking part 330 The laser marking is performed for the history management of the product. The operation system unit 300 is provided with convenience by integrally automating the operations of pressing the bearings, which have been carried out manually by a conventional method, and marking the workpieces with ink by performing a step difference inspection using an instrument.

In the above-described operation system unit 300, when the bearing press-in, the step difference inspection, and the laser marking are automatically performed, the workpiece having been completed to the front surface of the working system unit 300, 9 to 10, a body portion 410 which flows through the rails, as shown in FIGS. 9 to 10, and a holding portion 400 which is fixedly seated on the seat fixing portion 101, And a fixing bar 430 installed to penetrate through the body 410 to prevent shaking when the body 410 moves upward and downward.

In other words, when the workpiece is placed on the seat fixing part 101 closest to the articulated robot 220 by the first articulated robot 220, the clamp 420 picks up the workpiece and fixes the body part 410, The entire body is moved toward the discharge port 120 while being separated from the upper part and finally the body part 410 is separated again to the lower part so that the workpiece is naturally seated on the seat fixing part 101, When the clamp 420, which flows in close proximity, releases the workpiece, the inspected product is delivered to the outlet 120 for delivery. The above-described operation is continuously performed.

Also, although the body 410 is described as flowing through the rail, it may be constructed by applying a flowable technology such as a conventional cylinder.

A space portion 130 is formed in the main body portion 100 and a space 130 is formed in the lower portion of the inspection portion 200 and in the lower portion of the operation system portion 300 to store defective products And a defective article storage hole 131 connected to the defective article storage hole 131. [ If the defective products are identified during inspection due to the defective article storage hole 131, the defective article is rapidly dropped through the defective article storage hole 131 and the next processed article is inspected.

The control unit 500 may further include a controller 500 for controlling the main body 100, the inspection unit 200, the operation system unit 300, and the transfer unit 400 as a whole, So that the work can be performed through the speed and various settings operated by the control unit 500.

According to the automatic inspection apparatus for an automotive part of the present invention, since the respective processes are integrated and processed as a whole, the running time can be reduced, the installation space and manufacturing cost of the apparatus can be reduced, In addition, it is possible to increase the sales efficiency and to increase the economic efficiency by minimizing the defect rate caused by the manual operation. It is possible to perform all the inspections with a single input by integrating the general and individual inspections It is a useful invention that is constructed by changing the general inspection dramatically.

100: main body 101: seat fixing part 110: inflow part
111: jig 112: jig member 120:
130: Space part 131: Defective product storage hole
200: inspection unit 210: camera 211: LED
220: articulated robot 221: rotary plate 222: first rotary support shaft
223: second rotation support shaft 224: third rotation support shaft 225: fourth rotation support shaft
226: fifth rotation supporting shaft 227: sixth rotation supporting shaft 228: fixing member
230: Bearing inspection part 240: Operating system part
300: Operation system part 310: Bearing presser 311: Bearing storage part
312: Bearing position fixing part 313: Bearing press fitting part
320: step difference checker 330: laser marking unit
400: conveying part 410: body part 420: clamp 430: fixing rod 500: operating system part

Claims (9)

A main body 100 constituted by an inlet 110 into which the workpieces are inserted on both sides and a discharge portion 120 through which the workpieces are discharged;
An inspection part (200) for inspecting an outer surface of the workpiece and a bearing hole on an upper side of the main body part (100);
A bearing inserter 310 for inserting the bearing into the bearing hole of the workpiece 200, a step difference checker 320 for inspecting the stepped portion of the machined part and the bearing, And a laser marking unit 330 for laser marking the one side of the workpiece.
A transfer unit 400 disposed at one side of the upper portion of the main body 100 for transferring the processed work finished to the front of the working system unit 300 to the discharge unit 120; Wherein the automatic inspection apparatus for an automotive part
The method according to claim 1,
The inlet 110 of the main body 100 is formed in a rectangular shape and includes a plurality of jigs 111 for fixing the workpiece therein and a jig 111 for moving the jigs 111 112) for the automobile parts The method according to claim 1,
The inspection unit 200 inspects the positions, diameters, and gaps of the holes of the workpiece,
A camera 210 that includes a light emitting LED 211 on one side or side of an upper portion of the main body 100 to recognize and photograph the processed product,
The inspection of the diameter and spacing of the bearing holes formed in the workpiece is performed by a bearing inspection unit 230,
And a jointing robot 220 for fixing the workpiece to the camera 210, recognizing the workpiece, placing the workpiece on the bearing inspecting unit 230, inspecting the workpiece, and positioning the workpiece in the conveyance unit 400. Automated Inspection System for Parts
The method of claim 3,
The articulated robot 220 has six axes,
A rotating plate 221 is installed on one side of the inner lower surface of the main body 100,
A first rotary support shaft 222 connected to the center of the upper side of the rotary plate 221,
Second, third, fourth, fifth, and sixth rotation supporting shafts 223, 224, 225, 226, and 227, which are installed at the ends of the first rotation support shaft 222,
And a movable fixing member (228) for fixing the workpiece is formed at an end of the sixth rotation support shaft (227)
The method according to claim 1,
And an operating system unit (240) connected to the inspection unit (200) so that the inspection unit (200) can visually check the condition of the workpiece during inspection.
The method according to claim 1,
The bearing indenter (310)
A bearing storage portion 311 for storing a plurality of bearings b and for flowing the aero bearing b,
A bearing position fixing part 312 for fixing the bearing b flowing in the bearing storage part 311 and flowing back and forth by the cylinder,
And a bearing press-in portion (313) for press-fitting the bearing (b), which flows upward and downward by the cylinder, and fixed by the bearing position fixing portion (312) into the work piece
The method according to claim 1,
The conveying unit 400 includes:
A body portion 410 flowing on the upper, lower, left, and right rails,
A clamp 420 for holding and fixing the workpiece fixedly seated on the seat fixing part 101,
And a fixing bar 430 installed to penetrate through the body 410 to prevent the body 410 from shaking when the body 410 moves upward and downward.
The method according to claim 1,
A space part 130 is formed in the body part 100 and a space 130 is formed in the lower part of the inspection part 200 and in the lower part of the operation system part 300 so as to store defective products And a defective product storage hole (131) to be connected to the automotive parts
The method according to claim 1,
And a control unit (500) for selectively controlling the entire system on one side of the automation inspection apparatus.

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