JPH0875673A - Surface inspection device - Google Patents

Abstract

(57) [Abstract] [Purpose] To provide a surface inspection device capable of more reliably detecting and removing a defective can. [Constitution] The cans 2, 2, ... As inspection objects are placed on the vacuum elevator 1 and sequentially conveyed. The photodetector 5 emits inspection light for irradiating a plurality of inner surfaces of the cans 2, 2, ... And of the reflected light obtained by reflecting the inspection light on the inner surfaces of the cans 2, 2 ,. Detect intensity. Then, the control device 6 detects a defective can on the basis of the detection result, operates the drive unit 7 and operates the air nozzle 8
The compressed air is jetted from the target to the defective can.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a surface inspection device for inspecting a surface condition of a container, particularly a coating failure on the inner surface of a can.

[0002]

2. Description of the Related Art A can used as a container for various beverages such as beer or juice is formed of a metal such as aluminum or tin into a predetermined shape by a press or the like.
The inner surface of such a can is coated after molding in order to prevent oxidation of the inner surface. Then, in order to confirm this coating failure, conventionally, the following inspection has been performed. That is, by utilizing the fact that the light reflectance of a normal can that has been normally coated is lower than the light reflectance of a defective can that has not been normally coated, By irradiating light toward the opening of the can and detecting the intensity of the reflected light reflected at one point on the bottom of the can (bottom of the inner surface of the can), it is determined whether it is a normal can or a defective can. However, only the defective can was removed.

[0003]

By the way, as described above, in the conventional surface inspection apparatus, since the normal can and the defective can are judged based on the reflected light at one point on the bottom of the can, the light is irradiated. There is a problem in that an erroneous determination may be made due to the fact that foreign matter has adhered to the damaged portion.

The present invention has been made in view of the above problems, and an object thereof is to provide a surface inspection apparatus capable of more reliably detecting and removing a defective can.

[0005]

According to a first aspect of the present invention, in order to solve the above-mentioned problems, an inspection light irradiating a surface of an object to be inspected which is placed on a conveying device and sequentially conveyed. And a light detecting means having a plurality of light detecting elements for respectively detecting the intensities of the reflected light obtained by the inspection light being reflected at a plurality of portions of the inspection object, based on the detection result. It is characterized by comprising defective product removing means for removing an inspected object having a surface different from a predetermined state.

The surface inspection apparatus according to claim 2 is the same as claim 1.
In the invention described above, a plurality of the light emitting means are provided corresponding to the photodetecting elements.

The surface inspection apparatus according to claim 3 is the same as that according to claim 1.
In the invention described above, the photo-detecting elements are arranged in a line, and the photo-detecting elements are arranged so that the arrangement direction thereof is the conveying direction of the inspection object.

[0008]

According to the surface inspection apparatus of the present invention, the light detecting means detects the reflected light from a plurality of portions of the object to be inspected by the plurality of detecting elements. Therefore, the state of the surface of the inspection object can be accurately determined.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment in which the surface inspection device of the present invention is applied to a can inspection device for inspecting whether or not the inner surface of a can is coated will be described in detail with reference to the drawings. FIG.
[Fig. 3] is a view of the can inspection device of this embodiment as viewed from above. In the figure, reference numeral 1 is a vacuum elevator. This vacuum elevator 1 has a can 2 placed on the upper surface,
2, etc. are adsorbed by air and conveyed at a constant speed in the arrow X direction. The surface of the vacuum elevator 1 is surface-treated so as not to reflect light. The inner surfaces of the cans 2, 2, ... Are coated for oxidation prevention in the previous step, and they are placed on the vacuum elevator 1 at regular intervals with their upper surfaces open. An irradiation unit 3 is provided above the reference position a of the vacuum elevator 1. The irradiation unit 3 irradiates the inner surfaces of the cans 2, 2, ... With inspection light and receives reflected light obtained by reflecting the inspection light. In addition, the irradiation unit 3 includes the image fiber 4
It is connected to the photodetector 5 via. Photodetector 5
Emits inspection light and converts the reflected light into an electric signal. The image fiber 4 is a bundle of a large number of optical fibers, transmits the inspection light emitted by the photodetector 5 to the irradiation unit 3, and reflects the reflected light received by the irradiation unit 3 to the photodetector 5. To transmit.

The control device 6 outputs a trigger pulse to the drive device 7 in response to the electric signal output by the photodetector device 5.
When the trigger pulse is input, the driving device 7 sends the compressed air to the air nozzle 8. The air nozzle 8 injects this compressed air toward the cans 2, 2, ..., And blows the cans 2, 2 ,. The waste duct 9 is the blown can 2,
2, ... are collected in the waste container collection basket 10.

Next, referring to FIGS. 2 and 3, the structures of the irradiation unit 3, the image fiber 4 and the photodetector 5 will be described in more detail. FIG. 2 is a diagram showing a configuration of a surface of the irradiation unit 3 which emits inspection light and receives reflected light.
In the figure, reference numerals 4a1 to 4a16 are end faces of an irradiation optical fiber for irradiating detection light, and 4b1 to 4b16 are end faces of a light receiving optical fiber for receiving reflected light. As shown in the drawing, the irradiation optical fibers 4a1 to 4a16 and the light receiving optical fibers 4b1 to 4b16 each have 16 end faces alternately arranged in a line. The inspection light emitted in the photodetector 5 propagates in each of the irradiation optical fibers 4a1 to 4a16 and is emitted from each end face of the irradiation optical fibers 4a1 to 4a16. On the other hand, the reflected light is received by the light receiving optical fibers 4b1 ...
The light is received by the end face of 4b16, and the receiving optical fibers 4b1-4
The light propagates through b16 and is input to the photodetector 5. With this configuration, this can inspection device is
2. Detects 16 states on the inner surface of. Here, in this can inspection device, the irradiation optical fiber 4a in the irradiation unit 3 with respect to the conveying direction of the cans 2, 2, ... (Arrow X direction).
The end faces of 1 to 4a16 and the light-receiving optical fibers 4b1 to 4b16 are arranged so that the arrangement directions of the end faces are at right angles.

As shown in FIG. 3, the photodetector 5 is provided with a light emitting section 5a for emitting inspection light and a light receiving section 5b for converting reflected light into an electric signal and outputting the electric light according to an instruction from the control unit 6. There is. The light emitting section 5a includes light emitting elements 5a1 to 5a16.
(Light emitting diode, etc.) is used for each irradiation optical fiber 4a1
.About.4a16 are provided. Each light emitting element 5
a1 to 5a16 emit light of a constant intensity. Detector 5b
Are provided with light receiving elements 5b1 to 5b16 (phototransistors or the like) corresponding to the respective light receiving optical fibers 4b1 to 4b16. In addition, the detection unit 5b is configured so that each light receiving element 5b1
The electric signals converted by 5b16 are integrated and output as a detection signal. That is, the detection unit 5b
Uses an operational amplifier or the like to perform analog integration and output a detection signal.

The operation of this can inspection device will be described below. When this can inspection device operates, the photodetector 5 emits detection light according to an instruction from the controller 6. The inspection light is constantly emitted from the irradiation unit 3 toward the surface of the vacuum elevator 1 or the inner surfaces of the cans 2, 2, ....
In such a state, the reflected light reflected from the surface of the vacuum elevator 1 or the inner surfaces of the cans 2, 2, ...
The light receiving elements 5b1 to 5b16 respectively convert the electric signals. Then, the detection unit 5b integrates these electric signals and outputs them as a detection signal. The level of the detection signal changes with time as shown in FIG. That is, since the surface of the vacuum elevator 1 is surface-treated so that the light reflectance is low, the detection signal of this portion has the lowest signal level a. on the other hand,
Since the inner surfaces of the cans 2, 2, ... Are normally coated on the surface of the normal can, the detection signal has a signal level b higher than the signal level a. Also, on the surface of defective cans,
Since the inner surface is not painted, the detection signal has the highest signal level c.

The control device 6 outputs the detection pulse shown in FIG. 4 (b) by comparing the level of this detection signal with the threshold value d. That is, this detection pulse is output when a defective can is detected. The control device 6 is at time t
_When a defective can is detected at ₀ , the trigger pulse shown in FIG. 4C is output after a time Ta (time t ₁ ) until the defective can is located in front of the air nozzle 8. Drive device 7
When this trigger pulse is input, the air nozzle 8
Deliver compressed air to. Then, the air nozzle 8 injects this compressed air to the defective can located in the front and blows it into the waste container duct 9. Therefore, only normal cans are transported to the next step.

According to the can inspecting device of this embodiment having the above-mentioned structure, the following effects can be obtained. (1) The irradiation unit 3 and the light detection device 5 are optically coupled via the image fiber 4. With this configuration, the photodetector 5 can be installed at a position apart from the irradiation unit 3 installed around the cans 2, 2, .... Therefore, when a temperature change occurs around the cans 2, 2, ..., The photodetector 5 can stably convert the reflected light into an electric signal without being affected by the change. (2) The irradiation unit 3 is installed so that the arrangement direction of the end faces of the optical fibers 4a1 to 4a16 and 4b1 to 4b16 is at right angles to the conveying direction of the cans 2, 2, .... Therefore, the irradiation optical fibers 4a1 to 4a16 and the reception optical fiber 4
When the arrangement direction of the end faces of b1 to 4b16 is set parallel to the conveying direction of the cans 2, 2 ,.
It is possible to suppress the influence of the reflected light from the edge portion (the edge portion is not coated) in the opening of the. (3) Since the defective can is removed by the air jetted from the air nozzle 8, the defective can is easily removed.

The method of detecting a defective can is not limited to the above method, but the following method can be considered. (1) Normal canisters and defective cans by converting the electric signals output from the light receiving elements 5b1 to 5b16 into digital data and adding the data, and comparing the data obtained by the addition with a predetermined threshold value. Make a decision. (2) The electric signals output from the light receiving elements 5b1 to 5b16 are compared with predetermined threshold values, respectively, and the number of defects is counted. Then, when this count value is larger than a predetermined count value, it is judged as a defective can, and when this count value is smaller than a predetermined count value, it is judged as a normal can.

[0017]

According to the surface inspection apparatus of the present invention,
It is possible to accurately identify the inspection object and select only the normal inspection object. Therefore, the reliability of the surface inspection device is improved.

[Brief description of drawings]

FIG. 1 is a configuration diagram showing an embodiment of a surface inspection apparatus according to the present invention.

FIG. 2 is a diagram showing a configuration example of an irradiation unit in the surface inspection device of the present invention.

FIG. 3 is a diagram showing a configuration example of an irradiation unit, an image fiber, and a photodetector in the surface inspection apparatus of the present invention.

FIG. 4 is a diagram for explaining the operation of the surface inspection apparatus according to the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 vacuum elevator 2 can 3 irradiation part 4 image fiber 4a1 to 4a16 irradiation optical fiber 4b1 to 4b16 light receiving optical fiber 5 photodetector 5a light emitting part (light emitting means) 5a1 to 5a16 light emitting element 5b detection part (light detecting means) 5b1 -5b16 Light receiving element (light detecting element) 6 Control device 7 Drive section 8 Air nozzle 9 Waste container duct 10 Waste container collecting basket

Claims (3)

[Claims] 1. A light emitting means for emitting inspection light for irradiating the surface of an object to be inspected, which is placed on a transfer device and sequentially transferred, and the inspection light reflected by a plurality of portions of the object to be inspected. A light detecting means having a plurality of light detecting elements for respectively detecting the intensities of the obtained reflected light; and a defective product removing means for removing an inspected object having a surface different from a predetermined state based on the detection result. Surface inspection device characterized by. 2. A plurality of the light emitting means are provided corresponding to the photodetector elements.
The surface inspection device described. 3. The surface inspection apparatus according to claim 1, wherein the photodetection elements are arranged in a line, and the arrangement direction is set to be a transport direction of an object to be inspected. .