WO2022255239A1 - 評価方法、評価装置及びコンピュータプログラム - Google Patents
評価方法、評価装置及びコンピュータプログラム Download PDFInfo
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- WO2022255239A1 WO2022255239A1 PCT/JP2022/021696 JP2022021696W WO2022255239A1 WO 2022255239 A1 WO2022255239 A1 WO 2022255239A1 JP 2022021696 W JP2022021696 W JP 2022021696W WO 2022255239 A1 WO2022255239 A1 WO 2022255239A1
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- image data
- coating film
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Definitions
- the present disclosure relates to an evaluation method, an evaluation device, and a computer program for evaluating blisters in a coating film.
- the state of scratches, unevenness, etc. of the coated surface may be used. Since the detection of scratches and unevenness on the painted surface differs depending on the light irradiation method, for example, in Patent Document 1, the angle of the irradiation light to the painted surface is adjusted to detect even small scratches of about 50 ⁇ m. is described.
- blistering of the coating film as specified in JIS K5600-8-2 is known.
- the surface condition of the coating film is compared with grade samples based on multiple reference drawings, and by visually judging which grade sample it is closest to, the degree of blistering is determined. (density and size) are graded.
- an object of the present disclosure is to provide a method, an apparatus, and a computer program that can quantitatively evaluate blisters in a coating film.
- the evaluation method of the present disclosure is an evaluation method for evaluating blisters in a coating film formed on an object, comprising: (a) image data of the surface of the coating film irradiated with light from a coaxial illumination device; (b) subjecting the image data to at least a binarization process to detect an area of the blister existing on the surface of the coating film; and (c) an area of the blister in the area to be evaluated of the image data. including determining the area ratio occupied by
- the evaluation method is based on at least one selected from the group consisting of the size of blisters present on the surface of the coating film, the surface roughness of the coating film, and the glossiness of the coating film.
- a first condition for acquiring the image data in (b) above and a second condition for detecting the area of the blister in (b) above can be selected.
- the first condition includes the shortest distance between the half mirror of the coaxial illumination device and the effective field of view on the surface of the coating film
- the second condition is the threshold value in the binarization process. It can include the setting method.
- (b) includes (i) trimming the image data to obtain trimmed image data corresponding to the region to be evaluated; (ii) smoothing the trimmed image data; performing the binarization process after performing the smoothing process or without performing the smoothing process.
- the second condition may include a kernel value used for a smoothing filter of the smoothing process.
- the evaluation method can further include subjecting the object having the coating film to a corrosion resistance test before (a).
- the evaluation device is an evaluation device that evaluates blisters of a coating film formed on an object, and acquires image data of the surface of the coating film that is irradiated by a coaxial illumination device and photographed by an imaging device.
- a detection unit that performs at least binarization processing on the image data to detect a blister area existing on the surface of the coating film; and an area occupied by the blister area in the evaluation target area of the image data.
- the computer program causes the computer to execute the evaluation method.
- FIG. 2 is a conceptual diagram for explaining coaxial illumination, showing both a coaxial illumination device and an imaging device; It is a conceptual diagram which shows an example of the relationship between irradiated light and reflected light.
- FIG. 4 is a conceptual diagram showing another example of the relationship between irradiated light and reflected light;
- FIG. 2 is a conceptual diagram showing the relationship between the surface of a coating film (workpiece) with blisters and irradiated light and reflected light.
- FIG. 10 is a branch diagram showing determination to select an evaluation method based on blister size, glossiness, and surface roughness. It is an example of the image data in which the surface of the coating film was imaged.
- 6B is an example of image data obtained by smoothing the image data of FIG. 6A. It is an example of the image data which binarized the image data of FIG. 6B. It is another example of the image data which the surface of the coating film was image
- 7B is an example of binarized image data after smoothing the image data of FIG. 7A. It is a figure which shows an example of the illumination range in the surface of a coating film. It is another example of the image data which the surface of the coating film was image
- 9B is an example of image data obtained by smoothing the image data of FIG. 9A. It is an example of image data obtained by binarizing the image data of FIG. 9B. It is a flow chart explaining processing of an evaluation method.
- the evaluation method, evaluation apparatus, and computer program according to the embodiment will be described below with reference to the drawings.
- the evaluation method, evaluation device, and computer program of the present disclosure are for evaluating blisters in a coating film. Moreover, in the following description, the same reference numerals are given to the same configurations, and the description thereof is omitted.
- coating film refers to a film formed on an object (object to be coated) and derived from paint.
- “Paint” refers to a material used to cover the surface of an object to be coated for various purposes such as protection and decoration.
- Objects include, for example, flat plates, cylinders, rods, and other shapes.
- Materials for "objects” include, for example, metals, resins, rubbers, and ceramics.
- Metals include single metals and alloys containing aluminum, stainless steel, and iron.
- the component of the coating film preferably contains a fluorine-containing polymer.
- the fluoropolymer may be a fluororesin or a fluororubber, and is preferably a fluororesin.
- fluororesin examples include polytetrafluoroethylene [PTFE], tetrafluoroethylene [TFE]/hexafluoropropylene [HFP] copolymer [FEP], and TFE/perfluoro(alkyl vinyl ether) [PAVE] copolymer [PFA].
- PTFE polytetrafluoroethylene
- TFE tetrafluoroethylene
- HFP hexafluoropropylene
- PAVE TFE/perfluoro(alkyl vinyl ether) copolymer
- PFA TFE/HFP/PAVE copolymer
- EPA polychlorotrifluoroethylene
- CTFE chlorotrifluoroethylene
- ETFE TFE/ethylene [Et] copolymer
- ECTFE TFE /CTFE/Et copolymer
- PVDF polyvinylidene fluoride
- fluororubber examples include vinylidene fluoride [VdF]-based fluororubber, tetrafluoroethylene [TFE]/propylene [Pr]-based fluororubber, TFE/Pr/VdF-based fluororubber, ethylene [Et]/hexafluoropropylene [HFP ]-based fluororubber, Et/HFP/VdF-based fluororubber, Et/HFP/TFE-based fluororubber, fluorosilicone-based fluororubber, fluorophosphazene-based fluororubber, and the like.
- components other than the fluorine-containing polymer include, for example, liquid media.
- the liquid medium include water, organic solvents, mixed solvents of water and organic solvents, and the like.
- Binder resins are also included as components other than the fluorine-containing polymer.
- the binder resin is preferably a heat-resistant resin (excluding fluorine-containing polymer).
- Heat resistance means a property that allows continuous use at temperatures of 150°C or higher.
- examples of the heat-resistant resin include polyamideimide resin (PAI), polyimide resin (PI), polyethersulfone resin (PES), polyetherimide resin, aromatic polyetherketone resin, aromatic polyester resin, and polyarylene sulfide resin. etc.
- Components other than the fluorine-containing polymer include surfactants, dispersants, viscosity modifiers, film-forming aids, film-forming agents, antifoaming agents, drying retardants, thixotropic agents, pH adjusters, and pigments.
- Examples of the coating film forming method include spray coating, dip coating, roll coating, curtain flow coating, screen printing, dispenser coating, electrodeposition coating, electrostatic coating, fluidized dipping, rotolining, and rotomolding.
- the thickness of the coating film is preferably 1 to 5000 ⁇ m.
- a "blister” is a swelling of the paint film.
- Blisters can be caused by various causes, and when the coating film deteriorates, gas is generated between the coating film and the object to be coated (for example, components in the coating film or liquid components that have entered from the outside. vaporization). Blisters can be caused, for example, by natural deterioration of the coating, or by subjecting the coating to a corrosion resistance test for the purpose of evaluating the corrosion resistance of the coating.
- Evaluation of blisters on the painted surface is the evaluation of the current surface condition of the paint film (if it has been used after the paint film is formed, it is synonymous with deterioration evaluation), and (not passed through), including evaluation of the corrosion resistance of the coating film.
- Randomness (of the surface of the coating film) is the roughness obtained by measuring the unevenness of the surface of the coating film, for example, the arithmetic mean roughness Ra.
- Values indicating the surface of the coating film refer to values obtained in relation to the surface of the coating film to be evaluated, such as the size of the blister, the roughness of the surface of the coating film, and the glossiness of the coating film.
- Coaxial illumination is an illumination method in which light is emitted coaxially with the imaging axis (camera axis) of the imaging device. As shown in FIG. It can be a lighting method that incorporates light.
- the coaxial illumination is a work (that is, an object to be evaluated, which is an object on which a coating film is formed in the present disclosure) by reflecting light from a light source 31 by a half mirror 32.
- the surface of the workpiece corresponds to the surface of the coating film).
- the shortest distance from the half mirror 32 to the effective visual field of the work W is defined as the distance LWD (mm).
- the configuration including the light source 31 used for this coaxial illumination and the half mirror 32 is referred to as the coaxial illumination device 3 .
- FIG. 3A it is assumed that a work W having a flat surface faces the lens 21 of the photographing device 2, and the light source 31 irradiates the work W with irradiation light L1 from an oblique direction. do.
- the reflected light L2 obtained by reflecting the irradiation light L1 travels in a direction different from that of the lens 21 . Therefore, as shown in FIG. 3A, when the lens 21 of the photographing device 2 is arranged in a direction different from the optical path of the reflected light L2, the image of the workpiece W photographed by the photographing device 2 is an image of the diffusely reflected light. becomes.
- the photographing device 2 can obtain an image that captures the specularly reflected light.
- a workpiece W with blisters B generated on the surface of the coating film is photographed with coaxial illumination.
- the work W and the photographing device 2 face each other.
- illustration of the coating film formed on the surface of the workpiece W is omitted in FIG.
- the surface portion P1 of the coating film on the workpiece W on which the blisters B are not formed is irradiated with the irradiation light L1
- the reflected light L2 is directed toward the lens 21 of the photographing device 2 . Therefore, the surface portion P1 of the coating film appears bright on the image data.
- the reflected light L2 obtained by the irradiation light L1 applied to the vertex portion P2 of the blister B travels toward the lens 21. As shown in FIG. Therefore, the vertex portion P2 of the blister B appears bright on the image data.
- the reflected light L2 obtained by the irradiation light L1 applied to another portion (for example, P3) of the blister B travels in a direction corresponding to the inclination of the portion (for example, P3) irradiated with the irradiation light L1. Therefore, on the image data, a portion such as the blister B that is inclined with respect to the workpiece W on which the coating film is formed appears dark.
- image data in which the flat portions, which are the coating film portions, are bright, and the inclined portions, such as the convex portions, such as the blister B, are dark. That is, in the image data, the white portion is the surface of the coating film, the black portion is the portion where the blister B is generated, and the entire blister area can be extracted.
- image data is acquired using an evaluation method selected according to the value indicating the surface of the coating film, and the acquired image data is processed to extract the region of the blister B.
- Evaluation device 1 is an evaluation device for evaluating blisters of a coating film formed on an object, an acquisition unit 112 that acquires image data of the surface of the coating film irradiated with light by the coaxial illumination device 3 and photographed by the imaging device 2; a detection unit 113 that performs at least binarization processing on the image data and detects the area of the blisters present on the surface of the coating film; a calculation unit 114 that calculates the area ratio of the blister region in the evaluation target region of the image data; including.
- the evaluation device 1 is an information processing device that includes a control unit 11, a storage unit 12, and a communication unit 13.
- the control unit 11 is a controller that controls the evaluation apparatus 1 as a whole.
- the control unit 11 reads out and executes the evaluation program P stored in the storage unit 12, thereby performing processes as the selection unit 111, the acquisition unit 112, the detection unit 113, the calculation unit 114, and the result processing unit 115.
- the control unit 11 is not limited to one that realizes a predetermined function by cooperation of hardware and software, and may be a hardware circuit designed exclusively for realizing a predetermined function. That is, the control unit 11 can be realized by various processors such as CPU, MPU, GPU, FPGA, DSP, and ASIC.
- the storage unit 12 is a recording medium for recording various information.
- the storage unit 12 is realized by, for example, RAM, ROM, flash memory, SSD (Solid State Drive), hard disk, other storage devices, or an appropriate combination thereof.
- the storage unit 12 stores various data and the like.
- the storage unit 12 stores image data 121, result data 122, and an evaluation program P.
- the communication unit 13 is an interface circuit (module) for enabling data communication with an external device via the network 4.
- the communication unit 13 may perform data communication with the imaging device 2 that captures image data.
- the communication unit 13 may perform data communication with another external device.
- the evaluation device 1 can include an input unit 14 and an output unit 15.
- the input unit 14 is input means such as operation buttons, a mouse, and a keyboard used for inputting operation signals and data.
- the output unit 15 is output means such as a display used for outputting processing results and data.
- the evaluation device 1 may be implemented by a single computer, or may be implemented by a combination of multiple computers connected via a network. Also, although illustration is omitted, for example, all or part of the data stored in the storage unit 12 is stored in an external recording medium connected via a network, and the evaluation device 1 stores data in the external recording medium. It may be configured to use stored data.
- the selection unit 111 is based on at least one selected from the group consisting of the size of blisters present on the surface of the coating film, the roughness of the surface of the coating film, and the glossiness of the coating film.
- a first condition for acquiring image data and a second condition for detecting a blister region by the detection unit 113, which will be described later, are selected.
- the selection unit 111 receives at least one of "blister size", "glossiness”, and "surface roughness” as a value indicating the surface of the coating film to be evaluated.
- the selection unit 111 selects an “evaluation method” that defines a first condition regarding acquisition of image data and a second condition regarding image processing according to the received value indicating the surface of the coating film.
- the blister size for example, an operator can use a value visually measured using a ruler. At this time, it is preferable to use the average value of the blister size of the portion to be evaluated. For example, when measuring the size of a blister, 5 blisters may be randomly measured from the portion of the coating film to be evaluated, and the average value thereof may be used. This makes it possible to prevent selection of biased evaluation methods depending on only one blister size.
- glossiness of the coating film for example, a value measured using a gloss meter can be used.
- the surface roughness of the coating film for example, a value measured using a surface roughness measuring instrument can be used.
- the operator inputs these blister size, glossiness, and surface roughness values measured as described above to the evaluation device 1 via the input unit 14, so that the selection unit 111 selects the evaluation method to select.
- the selection unit 111 selects the evaluation method based on the criteria shown in Table 1.
- FIG. 5 shows the branching of the determination of each value for selection of the evaluation method shown in Table 1.
- the selection unit 111 selects the evaluation method a.
- the selection unit 111 selects the evaluation method h.
- a parameter that is a first condition used in image acquisition and a parameter that is a second condition used in image processing are set.
- the first condition is a parameter specifying the shortest distance LWD between the half mirror 32 of the coaxial illumination device 3 and the effective field of view on the surface of the coating film.
- the second condition includes, as a parameter, the image size when trimming the evaluation target area from the photographed image data. Also, the second condition includes a parameter used for setting a threshold value in the binarization process. Furthermore, the second condition includes the kernel value used for the median filter of the smoothing process as a parameter.
- the selection unit 111 selects an evaluation method by integrating values indicating the surface of a plurality of types of coating films. Further, the evaluation apparatus 1 performs image data acquisition processing and image processing using predetermined parameters for each evaluation method selected by the selection unit 111 .
- FIG. 6A is an example of image data of the surface of the coating film.
- FIG. 6B is image data obtained by smoothing the image data of FIG. 6A.
- FIG. 6C is image data obtained by binarizing the image data of FIG. 6B.
- the smoothing process and the binarization process are image processes intended to accurately detect the blister area, and are executed by the detection unit 113 described later. For example, when the size of the blister is relatively large, as shown in FIG. 6C, the portion reflecting the strong reflected light becomes wider near the center of the blister, and the image data may become white (for example, A1 in FIG. 6C part).
- the whitened portion is considered not to be the blister region and cannot be evaluated accurately. Therefore, when the blister size is larger than a predetermined value in this way, for example, in the smoothing filter, a wider area of pixels is allocated for each pixel compared to when the blister size is smaller than the predetermined value. It becomes easy to extract the blister B portion by performing a smoothing process using the .
- the kernel value used in the smoothing filter which is a parameter, is adjusted according to the size of the blister B, and the extraction accuracy of the blister B is improved.
- the size of the blister B is small, for example, by shortening the distance LWD, which is the shortest distance between the half mirror 32 of the coaxial illumination and the effective field of view on the surface of the coating film, it becomes easier to extract the blister B portion. . That is, when the size of the blister B is small, the contrast between the surface of the coating film and the blister B portion in the image data tends to be small, making it difficult to detect the blister B region. Therefore, when the blister is small, detection of the blister B becomes difficult. Therefore, for example, when the blister size is smaller than a predetermined size, shortening the parameter distance LWD makes it easier to extract the blister B portion.
- the evaluation device 1 adjusts the distance LWD, which is a parameter, according to the size of the blister B to improve the extraction accuracy of the blister B.
- ⁇ Adjustment according to surface roughness ⁇ For example, when evaluating the surface of a coating film having a large surface roughness and convex portions other than blisters on the surface of the coating film, binarization may cause parts other than blisters to become black (for example, part A2 in FIG. 6C). In such cases, portions other than blisters may be detected as blisters. If convex portions other than blisters existing on the surface of the coating film are erroneously detected as blisters in this way, accurate evaluation cannot be performed. Therefore, when the surface roughness is greater than a predetermined value, for example, the smoothing filter removes convex portions other than the blister B by blurring each pixel using pixels in a wide surrounding area. easier.
- the evaluation apparatus 1 adjusts the kernel value used in the smoothing filter, which is a parameter, according to the surface roughness, thereby improving the extraction accuracy of the blisters B.
- FIG. 7A is an example of image data obtained by photographing the surface of a coating film with high glossiness.
- the reflected light L2 may become weak due to scattering of the reflected light due to scratches on the surface.
- the smoothing and binarization may darken such a portion of the image data such as a flaw (A3 portion in FIG. 7B).
- the scratched portion other than the blister B will also be blackened and detected as the blister B.
- the scratches can be made inconspicuous by setting the threshold to the black side and performing the binarization process. Specifically, in 256 gradations, "0" is a value indicating black, and "255" is a value indicating white. Then, in order to shift the threshold to the black side, the value of the parameter set according to the degree of glossiness is subtracted from the threshold set by a predetermined method to obtain a new threshold, thereby making the flaw stand out. can be made difficult.
- the acquisition unit 112 acquires the image data 121 including the evaluation target area using the parameters determined by the evaluation method selected by the selection unit 111 . Specifically, the acquisition unit 112 acquires the image data 121 using the parameter distance LWD determined by the evaluation method. Further, the acquisition unit 112 causes the storage unit 12 to store the acquired image data 121 . For example, the acquisition unit 112 is connected to the imaging device 2 , transmits a shooting operation signal to the imaging device 2 , and acquires image data 121 shot by the imaging device 2 .
- the detection unit 113 (i) trims the image data to obtain trimmed image data corresponding to the region to be evaluated, and (ii) performs smoothing on the trimmed image data. It can include applying a binarization process without applying a conversion process. Specifically, the detection unit 113 performs image processing on the image data 121 acquired by the acquisition unit 112 using each parameter determined by the evaluation method selected by the selection unit 111, and determines the blister region included in the evaluation target region. To detect. Specifically, the detection unit 113 executes processing of “grayscaling”, “trimming”, “smoothing”, and “binarization” as image processing. Specifically, the image data 121, which is the color image data acquired by the acquisition unit 112, is set as the first image data.
- the detection unit 113 performs grayscaling processing on the first image data, and uses the processed image data as second image data.
- the detection unit 113 also extracts (trimming) an evaluation target area from the second image data.
- the detection unit 113 performs smoothing processing (blurring processing) on the second image data of the trimmed target region, and uses the obtained smoothed image data as third image data.
- the detection unit 113 performs binarization processing on the third image data, and uses the obtained binarized image data as fourth image data. After that, the detection unit 113 detects the blister area from the fourth image data.
- the grayscaling process is unnecessary, and the detection unit 113 converts the acquired image data 121 into Trimming should be done. Further, the conversion to grayscale is not processing using parameters set for each evaluation method, but conversion from a general color image to a grayscale image.
- Trimming is extraction of an evaluation target area.
- the detection unit 113 performs image processing from the second image data with the trimming image size, which is a parameter determined by the evaluation method selected in the selection unit 111, according to at least one of the values indicating the surface of the coating film. Crop the area of interest.
- the image data 121 photographed by the photographing device 2, for example, as shown in FIG. 8 is bright only in a part of the area irradiated with the light from the light source 31, and dark in the area not irradiated with the light. Therefore, when trimming, it is necessary to trim within a bright area in the second image data.
- the second image data after trimming is, for example, image data as shown in FIG. 9A when enlarged.
- the trimming image size is determined by extracting a range that can be used for image analysis according to the spread of light when the coating film is irradiated with light.
- FIG. 9B is image data obtained by smoothing the image data of FIG. 9A.
- the detection unit 113 performs smoothing processing on the trimmed second image data using a smoothing filter using a kernel value, which is a parameter set according to the evaluation method.
- the image data obtained by the smoothing process is the third image data.
- the detection unit 113 can use, for example, a Gaussian filter as a smoothing filter.
- a Gaussian filter is a filter that uses a Gaussian distribution to increase the weight of the central portion of a pixel of interest.
- the parameters set by the selection unit 111 are kernel values used in the Gaussian filter.
- the detection unit 113 may use a smoothing filter, a median filter, a bilateral filter, or the like as the smoothing filter.
- FIG. 9C is image data obtained by binarizing the image data of FIG. 9B.
- the image data of FIG. 9C is an example in which a blister region generated on the base material could be detected. Specifically, the black portion in FIG. 9C is the blister area.
- the detection unit 113 uses the threshold adjusted by the parameter value set according to the evaluation method selected by the selection unit 111 so as to accurately detect the blister area, and the smoothed third image data. Execute the binarization process.
- the image data obtained by the binarization process is the fourth image data. By binarizing, for example, the influence of the surface state of the coating film can be removed to detect the blister area.
- the detection unit 113 can use, for example, adaptive binarization process that calculates a threshold value for each small area in the image.
- the parameter set by the selection unit 111 is a value used for adjusting the threshold set in the binarization process.
- the threshold value is set between 0 and 255
- the parameter is a value indicating the number of gradations to shift the set threshold value to the white side (closer to “255”), for example. is.
- the detection unit may use various methods such as the discriminant analysis method (Otsu's binarization), iterative threshold selection, and the P-tile method for the binarization process.
- the evaluation method is selected according to at least one value of the "blister size", “roughness”, and “glossiness” of the surface of the coating film. select.
- the evaluation apparatus 1 can quantitatively evaluate the blisters of the coating film using this blistering area.
- the calculation unit 114 calculates, as an evaluation value, the area ratio occupied by the detected blister area with respect to the target area of the image size trimmed by the detection unit 113 . Specifically, when the area ratio calculated by the calculator 114 is small, the performance of the coating film is evaluated to be high. Conversely, when the area ratio calculated by the calculator 114 is large, the performance of the coating film is evaluated to be low. As described above, in the evaluation apparatus 1, the evaluation value obtained by the calculation unit 114 is a value obtained by quantifying the corrosion resistance. It is possible to quantitatively evaluate membrane blisters. In addition, in the example of FIG. 9C, the area ratio of the blister region was calculated to be 42.63%.
- the result processing unit 115 sets the area ratio of the blister region calculated by the calculation unit 114 as the result data 122 and stores it in the storage unit 12 in association with the image data 121 . Also, the result processing unit 115 may output the evaluation value to the output unit 15 . The result processing unit 115 registers the obtained evaluation value in the storage unit 12 as result data 122 . At this time, the result processing unit 115 associates various image data obtained by the acquisition unit 112 and various image data after binarization obtained by the detection unit 113 with the original image data 121 and stores them in the storage unit 12. may be stored. Further, the result processing unit 115 may store various data related to the image data 121 in the storage unit 12 in association with the image data 121 .
- the evaluation device 1 executes processing using the determined parameters for each evaluation method. As a result, it is possible to eliminate influences unrelated to paint performance contained in the image data, and to quantitatively evaluate blisters in the coating film based on numerical calculations of the blister area ratio. For example, various resins and pigments may be used in paints, and by using the above-described treatment, it is possible to quantitatively evaluate blisters in paint films.
- An evaluation method is an evaluation method for evaluating blisters of a coating film formed on an object, (a) Acquiring image data of the surface of the coating film irradiated with light by the coaxial illumination device with a photographing device; (b) subjecting the image data to at least a binarization process to detect the area of the blisters present on the surface of the coating film; Ask.
- An evaluation method using the evaluation apparatus 1 will be described below with reference to the flowchart shown in FIG.
- the evaluation device 1 receives input of a value indicating the surface of the coating film, which is data for selecting an evaluation method (S01). For example, when the evaluation device 1 inputs values of blister size, glossiness, and surface roughness as values indicating the surface of the coating film by the operation using the input unit 14 by the user, evaluation used for evaluation method is selected.
- the evaluation device 1 uses the parameters set in the first condition of the evaluation method selected in step S01 to acquire image data of the surface of the coating film on the workpiece W to be evaluated (S02). Specifically, the evaluation device 1 sets the shortest distance LWD from the half mirror 32 of the coaxial illumination device to the effective field of view on the surface of the workpiece W using the parameters defined by the first condition of the selected evaluation method, Get image data.
- the image data acquired in step S02 is the first image data.
- the evaluation device 1 also causes the storage unit 12 to store the acquired first image data.
- the evaluation device 1 grayscales the first image data acquired in step S02 (S03).
- the image data converted to grayscale in step S03 is the second image data.
- the evaluation device 1 also causes the storage unit 12 to store the grayscaled second image data.
- the evaluation apparatus 1 extracts an area to be evaluated from the second image data converted to grayscale in step S03 ( trimming) (S04). Specifically, the evaluation device 1 sets the position of the target region according to the irradiation position of the light onto the work W at the time of acquisition in step S02.
- the evaluation device 1 performs smoothing processing on the second image data of the target area extracted in step S04 (S05). At this time, the evaluation device 1 smoothes the second image data of the target region using a smoothing filter that uses a kernel value corresponding to the parameter set in the second condition of the evaluation method selected in step S01. process.
- the evaluation device 1 performs binarization processing on the third image data obtained by the smoothing processing in step S05 (S06). At this time, the evaluation device 1 adjusts the threshold used for binarization using the parameter set in the second condition of the evaluation method selected in step S01, and the luminance value of each pixel of the third image data. is equal to or greater than the adjusted threshold value, it is white, and if it is less than the threshold value, it is black.
- the evaluation device 1 detects a blister area from the fourth image data obtained by the binarization process in step S06 (S07). As described above, in the image data, flat portions become brighter and convex portions become darker. Therefore, in the binarized image data, since the original workpiece W portion is flat, it becomes white, and the blister B portion, which is a convex portion, becomes black. Therefore, a black area is detected as a blister area from the binarized image data.
- the evaluation device 1 uses the blister area detected in step S07 to calculate the area ratio of the blister area to the target area to be evaluated (S08). Specifically, the evaluation device 1 calculates the number of pixels in the blister area with respect to the number of pixels in the binarized image data of the trimmed target area. The evaluation device 1 also stores the calculated area ratio in the storage unit 12 as an evaluation result.
- the evaluation device 1 outputs the result obtained in step S08 to the output unit 15 (S09).
- the coating film to be evaluated by the evaluation device 1 can be evaluated for blisters after being subjected to a corrosion resistance test for the purpose of evaluating corrosion resistance. Therefore, when evaluating a coating film that has been subjected to a corrosion resistance test, the corrosion resistance test is carried out before starting the evaluation process in the evaluation apparatus 1 described above.
- the conditions for the corrosion resistance test of the coating film can be appropriately selected according to the coating film, purpose of evaluation, and the like.
- a lining tester (trade name: Yamazaki Lining Tester LA-15, manufactured by Yamazaki Seiki Laboratory Co., Ltd.), which is commonly used for resin lining corrosion resistance testing, can be used for coating film corrosion resistance testing.
- an accelerated test can be performed by giving a temperature gradient to the inner and outer surfaces of the test piece.
- the coating film shown in FIG. 9A is obtained by coating a SUS304 base material with a fluororesin paint so that the film thickness after film formation is 300 ⁇ m, and applying water at 100 ° C as an environmental liquid to the inside of the test piece. was used, water at 30°C was flowed outside, and the liquid phase portion was photographed after the test was conducted for 24 hours.
- the evaluation method, evaluation device, and computer program of the present disclosure are useful for quantitatively evaluating the state of the surface of the coating film.
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Abstract
Description
始めに、評価装置で用いる画像データの取得の際の照明について説明する。図1を用いて後述する評価装置1は、撮影装置2によって撮影された塗膜の表面(塗装面)の画像データを用いる。ここで、撮影装置2は、塗装面の撮影に同軸照明を利用する。同軸照明は、撮影装置の撮影軸(カメラ軸)と同軸上に光を照射する照明方法であり、図2に一例を示すように、撮影装置2のレンズ21の光路内に光源31からの照射光が組み込まれた照明方法であり得る。具体的には、同軸照明は、図2に示すように、光源31からの光を、ハーフミラー32によって反射させてワーク(即ち、評価対象、本開示では塗膜が形成された物体であり、ワークの表面が塗膜の表面に対応する)Wに照射させる照明方法である。このとき、ハーフミラー32からワークWの有効視野までの最短距離を距離LWD(mm)とする。ここでは、この同軸照明に用いる光源31と、ハーフミラー32とを含む構成を同軸照明装置3とする。
続いて、図1を参照して、実施形態に係る評価装置1について説明する。評価装置1は、物体上に形成された塗膜のブリスターを評価する評価装置であって、
同軸照明装置3で光照射され、撮影装置2で撮影された塗膜の表面の画像データを取得する取得部112と、
画像データに少なくとも二値化処理を施して、塗膜の表面に存在するブリスターの領域を検出する検出部113と、
画像データの評価対象の領域においてブリスターの領域が占める面積率を求める算出部114と、
を含む。
図6Aは、塗膜の表面を撮影した画像データの一例である。また、図6Bは、図6Aの画像データを平滑化処理して得られた画像データである。さらに、図6Cは、図6Bの画像データを二値化処理して得られた画像データである。平滑化処理、および、二値化処理は、ブリスターの領域を精度良く検出することを目的とする画像処理であり、後述する検出部113で実行される。例えば、ブリスターのサイズが比較的大きい場合、図6Cに示すように、ブリスターの中央付近において強い反射光を反射する部分が広くなり、画像データにおいて白くなることがある(例えば、図6C中のA1の部分)。このようにブリスターの一部について白くなった場合、白くなった部分についてはブリスターの領域ではないとされ、正確に評価することができない。したがって、このようにブリスターのサイズが所定の値よりも大きい場合、例えば、平滑化フィルタにおいて、ブリスターのサイズが所定の値よりも小さい場合と比較して、各画素に対して広い領域の画素を用いて平滑化処理を施すことにより、ブリスターB部分を抽出しやすくなる。評価装置1では、ブリスターBのサイズに応じて、パラメータである平滑化フィルタで用いるカーネル値を調整し、ブリスターBの抽出精度を向上させる。
例えば、表面粗度が大きく、塗膜の表面にブリスター以外の凸部が存在する塗膜の表面を評価する場合、二値化することにより、ブリスター以外の部分も黒くなることがある(例えば、図6C中のA2の部分)。このような場合、ブリスター以外の部分がブリスターとして検出される恐れがある。このように塗膜の表面に存在するブリスター以外の凸部が誤ってブリスターとして検出されると、正確に評価することができなくなる。したがって、このように表面粗度が所定の値よりも大きい場合、例えば、平滑化フィルタにおいて、各画素に対して広い周囲領域の画素を用いてぼかすことにより、ブリスターB以外の凸部を除去しやすくなる。これは、このようなブリスターB以外の凸部は、通常、ブリスターB自体よりも小さいためである。このように、評価装置1では、表面粗度に応じて、パラメータである平滑化フィルタで用いるカーネル値を調整し、ブリスターBの抽出精度を向上させる。
図7Aは、光沢度が高い塗膜の表面を撮影した画像データの一例である。例えば、塗膜の光沢度が高い場合、表面上の傷において反射光が散乱する等により、反射光L2が弱くなることがある。それにより、平滑化かつ二値化することにより、図7Bに示すように、画像データにおいてこのような傷等の部分(図7B中のA3の部分)が暗くなることがある。この場合、通常と同様の二値化処理によって、ブリスターBの領域を抽出する方法では、ブリスターB以外の傷の部分についても黒くなることにより、ブリスターBとして検出されるおそれがある。したがって、このように二値化された画像データで傷が表れやすい光沢度の高い塗膜の場合、閾値を黒側に設定して二値化処理することで、傷を目立ちにくくすることができる。具体的には、256階調において、「0」が黒を示す値であり、「255」が白を示す値である。そして、閾値を黒側にシフトさせるため、所定の方法で設定された閾値に、光沢度の程度に応じて設定されるパラメータの値をマイナスして、新たな閾値とすることで、傷を目立ちにくくすることができる。
トリミングは、評価の対象領域の抽出である。検出部113は、選択部111において、塗膜の表面を示す各値の少なくともいずれかに応じて、選択された評価手法で定められるパラメータであるトリミングの画像サイズで、第2画像データから画像処理の対象の領域をトリミングする。このとき、撮影装置2で撮影される画像データ121は、例えば、図8に示すように、光源31からの照射光が当たる一部の領域のみ明るく、照射光の当たらない領域は暗くなる。したがって、トリミングする際には、第2画像データのうち、明るい領域内でトリミングする必要がある。トリミング後の第2画像データは、拡大すると、例えば、図9Aに示すような画像データである。なお、トリミングの画像サイズは、塗膜に光を照射した際の光の広がりに応じて、画像解析に使用可能な範囲を抽出することにより決定する。
続いて、平滑化の一例を説明する。図9Bは、図9Aの画像データを平滑化処理して得られた画像データである。検出部113は、評価手法に応じて設定されたパラメータであるカーネル値を用いた平滑化フィルタによって、トリミングされた第2画像データに平滑化処理を実行する。平滑化処理により得られた画像データは、第3画像データである。平滑化処理をすることで、例えば、ブリスターのサイズが大きい場合にブリスターの領域を抽出しやすくしたり、塗膜の粗度による影響を軽減することができる。
次に、二値化の一例を説明する。図9Cは、図9Bの画像データを二値化処理して得られた画像データである。図9Cの画像データは、基材に発生したブリスター領域が検出できた例である。具体的には、図9Cにおける黒色部分がブリスター領域である。しかしながら、画像取得および画像処理に利用するパラメータによっては、図9Cに示すように、ブリスター領域が検出できる画像データばかりであるとは限らない。したがって、検出部113は、ブリスター領域を正確に検出できるように、選択部111で選択された評価手法に応じて設定されたパラメータの値で調整した閾値により、平滑化された第3画像データに二値化処理を実行する。二値化処理により得られた画像データは、第4画像データである。二値化処理することで、例えば、塗膜の表面状態の影響を除去してブリスター領域を検出することができる。
実施形態に係る評価方法は、物体上に形成された塗膜のブリスターを評価する評価方法であって、
(a)同軸照明装置で光照射された塗膜の表面の画像データを撮影装置によって取得し、
(b)画像データに少なくとも二値化処理を施して、塗膜の表面に存在するブリスターの領域を検出し、および
(c)画像データの評価対象の領域において前記ブリスターの領域が占める面積率を求める。
以下、図10に示すフローチャートを参照して評価装置1を用いた評価方法について説明する。
以上のように、本出願において開示する技術の例示として、上記実施形態を説明した。しかしながら、本開示における技術は、これに限定されず、適宜、変更、置き換え、付加、省略などを行った実施形態にも適用可能である。
11 制御部
111 選択部
112 取得部
113 検出部
114 算出部
115 結果処理部
12 記憶部
121 画像データ
122 結果データ
P 評価プログラム
13 通信部
14 入力部
15 出力部
2 撮影装置
3 同軸照明装置
W ワーク(塗膜が形成された物体)
Claims (8)
- 物体上に形成された塗膜のブリスターを評価する評価方法であって、
(a)同軸照明装置で光照射された前記塗膜の表面の画像データを撮影装置によって取得し、
(b)前記画像データに少なくとも二値化処理を施して、前記塗膜の表面に存在するブリスターの領域を検出し、および
(c)前記画像データの評価対象の領域において前記ブリスターの領域が占める面積率を求める
ことを含む、評価方法。 - 前記塗膜の表面に存在するブリスターのサイズ、前記塗膜の光沢度、および前記塗膜の表面の粗度からなる群より選択される少なくとも1つに基づいて、前記(a)における前記画像データを取得する第1条件、および前記(b)における前記ブリスターの領域を検出する第2条件が選択される、請求項1に記載の評価方法。
- 前記第1条件が、前記同軸照明装置のハーフミラーと前記塗膜の表面の有効視野までの間の最短距離を含み、前記第2条件が、前記二値化処理における閾値の設定方法を含む、請求項2に記載の評価方法。
- 前記(b)が、
(i)前記画像データをトリミングして、前記評価対象の領域に対応するトリミングされた画像データを得、
(ii)前記トリミングされた画像データに、平滑化処理を施した後、または平滑化処理を施さずに、前記二値化処理を施す、
ことを含む、請求項2又は3のいずれかに記載の評価方法。 - 前記第2条件が、前記平滑化処理の平滑化フィルタに用いるカーネル値を含む、請求項4に記載の評価方法。
- 前記(a)の前に、
前記塗膜を有する前記物体を耐蝕性試験に付す
ことを更に含む、請求項1~5のいずれかに記載の評価方法。 - 物体上に形成された塗膜のブリスターを評価する評価装置であって、
同軸照明装置で光照射され、撮影装置で撮影された前記塗膜の表面の画像データを取得する取得部と、
前記画像データに少なくとも二値化処理を施して、前記塗膜の表面に存在するブリスターの領域を検出する検出部と、
前記画像データの評価対象の領域において前記ブリスターの領域が占める面積率を求める算出部と、
を含む評価装置。 - 請求項1~5のいずれかに記載の評価方法をコンピュータに実行させるためのコンピュータプログラム。
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