WO2015152059A1 - 溶接状態監視システム及び溶接状態監視方法 - Google Patents
溶接状態監視システム及び溶接状態監視方法 Download PDFInfo
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Definitions
- the present invention relates to a welding state monitoring system and a welding state monitoring method.
- This application claims priority based on Japanese Patent Application No. 2014-77184 filed in Japan on April 3, 2014, the contents of which are incorporated herein by reference.
- ERW steel pipes manufactured by ERW welding are used as pipes used in nuclear power plants, geothermal power plants and chemical plants, or pipes used in mechanical structures and general piping.
- ERW steel pipes are used in a wide field.
- a strip coil made of a steel plate is continuously formed into a tubular shape by a large number of roll groups. Then, the tubular steel plate is subjected to induction heating with a work coil or direct current heating with a contact tip to heat and melt the circumferential end (butt end) of the steel plate to a predetermined temperature and apply it with a squeeze roll.
- ERW steel pipe is manufactured by welding while pressing. In a steel sheet to be subjected to electric resistance welding, a butt end region sandwiched between a contact tip or a work coil and a squeeze roll is called a welded portion.
- Patent Documents 1 and 2 disclose a technique for irradiating plasma to a welded part in order to reduce oxides generated on the surface of the welded part during electric seam welding.
- the technique of performing electric resistance welding while irradiating plasma to a welding part is called plasma shield electric resistance welding.
- plasma shield electro-resistance welding has a fundamentally different technical idea from plasma welding in which welding is performed by plasma irradiation itself.
- plasma shield electro-welding welding plasma is irradiated to the appropriate place in the welded part to heat or melt the butt surface of the steel sheet, and the shielding action of the butt surface by ionized plasma gas or ionized plasma gas It is possible to maintain a low oxygen concentration state due to the reducing action of the. As a result, an oxide film on the butt surface that may become an oxide defect after welding can be suppressed in the generation process, and high-quality welding with few defects is possible.
- Patent Documents 3 and 4 have a technique for photographing a radiation pattern in a visible region of a welded portion using a color or monochrome camera using a CCD image sensor and analyzing the welding state by image processing with respect to conventional electric welding. It is disclosed.
- Japanese Patent No. 4890609 Japanese Patent No. 5316320 Japanese Patent No. 5079929 Japanese Patent No. 5125670
- Patent Documents 1 and 2 disclose plasma shield electric seam welding, but do not disclose the imaging technique and image analysis technique in the welded state.
- FIG. 18A is an image obtained by photographing a molten steel radiation pattern disclosed in Patent Documents 3 and 4 by a color or monochrome photographing technique in a visible region, in a welded portion of a steel plate in conventional electric resistance welding.
- the direction from the left to the right is the conveying direction of the steel plate, and the state where both edge portions in the circumferential direction of the steel plate converge in a V shape is photographed.
- the present invention has been made in view of the above circumstances, and is a welding state monitoring system and a welding state monitoring method used for plasma shielded electric resistance welding in which plasma welding is performed on a welded portion of a steel plate to perform electric resistance welding.
- An object of the present invention is to provide a welding state monitoring system and a welding state monitoring method capable of analyzing a welding state without being affected by plasma.
- a welding state monitoring system is a welding state monitoring system used in plasma shield electric resistance welding for performing electric resistance welding by irradiating plasma on a welded portion of a steel sheet,
- a plasma irradiation device that irradiates the welded portion, a first imaging device that images the welded portion from above, and that has an image sensor capable of detecting light having a wavelength of 850 nm or more, and the first imaging device.
- a first wavelength band limiting device that limits light to be 850 nm or more, an image processing device that analyzes an image captured by the first imaging device and analyzes a welding state of the welded portion, and .
- the first wavelength range limiting device limits light incident on the first imaging device to a wavelength range of 900 nm or more. May be.
- the first imaging device has a resolution of 60 ⁇ m or less when photographing a range having a width of 100 mm or more. You may employ
- the image processing device is configured such that both butt ends of the steel sheet converged in a V shape geometrically intersect.
- the second imaging device having the same visual field range as the first imaging device, and the second imaging A second wavelength band limiting device that limits light incident on the device to only light having a wavelength of 500 nm or less, and the image processing device is configured to detect the steel plate based on the image captured by the second imaging device.
- the plasma processing apparatus further includes a third imaging device that images the welded portion from any one of the oblique directions, and the image processing device performs the plasma in the transport direction of the steel sheet based on an image captured by the third imaging device.
- a configuration further including a third wavelength band limiting device that limits light incident on the third imaging device to only light having a wavelength of 500 nm or less is adopted. May be.
- a welding state monitoring method is a welding state monitoring method used in plasma shielded electric resistance welding in which plasma welding is performed on a welded portion of a steel plate to perform electric resistance welding, and the wavelength is 850 nm.
- the imaging device provided with the image sensor capable of detecting the light as described above, limiting the light incident on the imaging device to a wavelength range of 850 nm or more, and imaging the weld from above, and image processing
- a welding state monitoring system and a welding state monitoring method used in plasma shielded electric resistance welding for performing electric resistance welding by irradiating plasma on a welded portion of a steel sheet, without being affected by plasma A welding state monitoring system and a welding state monitoring method capable of analyzing a welding state can be provided.
- FIG. 1 shows schematic structure of the welding condition monitoring system in the plasma shield electric resistance welding which concerns on 1st Embodiment. It is a schematic diagram which shows 1st type among the welding states of the welding part in plasma shield electro-resistance-welding. It is a schematic diagram which shows 2nd type among the welding states of the welding part in plasma shield electro-resistance-welding. It is a schematic diagram which shows a transition area
- Ar it is a characteristic diagram showing an emission spectrum of N 2 and O 2. It is a characteristic view which shows the spectrum of plank radiation. It is a characteristic view which shows the sensitivity characteristic of an InGaAs image sensor and a CMOS image sensor. It is a figure which shows the image which image
- FIG. 1 shows a schematic configuration of a welding state monitoring system in plasma shield electric resistance welding according to the first embodiment.
- the steel plate 1 is formed into a tubular shape by a group of rolls (not shown) while being conveyed from upstream (right side in FIG. 1) to downstream (left side in FIG. 1), and induction heating or contact by a work coil. Direct current heating with a chip is performed to heat and melt the butt end 1a of the steel plate 1.
- the direction from upstream to downstream which is the direction in which the steel plate 1 is transported, is referred to as the transport direction X of the steel plate 1.
- both butt ends 1a of the steel plate 1 are converged in a V shape.
- matching edge parts 1a of the steel plate 1 are butted and welded.
- the V-shaped corner formed by the both butted ends 1a of the steel plate 1 is referred to as a V-shaped convergence angle.
- matching edge parts 1a of the steel plate 1 is called V character convergence area
- an oxide is generated by oxidizing the surface of the molten steel. Since electromagnetic force (repulsive force) acts on both butt ends 1a in the welding process, the oxide is discharged out of the plane together with the molten steel. Further, the oxide generated on the surface of the molten steel is also discharged by the pressure of the squeeze roll 7. On the other hand, when the oxide generated on the surface of the molten steel is not properly discharged at the butt end portion 1a, a welding defect called a penetrator may be generated due to the oxide generated on the surface of the molten steel.
- a plasma irradiation device 2 is disposed above and upstream of the conveying direction X of the steel plate 1.
- the plasma irradiation apparatus 2 irradiates plasma toward the welded part 3.
- the plasma irradiation apparatus 2 irradiates the welded portion 3 with plasma during plasma shield electro-welding welding, so that the welded portion 3 is covered with plasma. Further, as will be described later, when the plasma contains H 2 gas, a reducing atmosphere is formed around the welded portion 3. Thereby, the oxygen concentration in the periphery of the welded portion 3 is lowered, and oxides are hardly formed on the surface of the welded portion 3.
- the length on the steel plate 1 can be irradiated to a range with a length of 100 mm or more. More preferably, it is preferable that the plasma irradiation apparatus 2 of this embodiment can irradiate plasma with respect to the range whose length on the steel plate 1 is 200 mm or more.
- the plasma irradiation apparatus 2 of this embodiment irradiates laminar plasma. Thereby, it is possible to greatly reduce the entrainment of air into the welded part 3 during the plasma shield electro-resistance welding. Therefore, it can reduce significantly that an oxide is produced
- the power consumption of the plasma irradiation apparatus 2 of this embodiment is about 40 kW. This is about 1/10 of the power consumption of the plasma welding apparatus.
- Plasma plasma irradiation apparatus 2 of this embodiment is irradiated, Ar, N 2 as a main component. In addition to these components, in order to form a reducing atmosphere around the welded portion 3, the plasma irradiated by the plasma irradiation apparatus 2 of the present embodiment may contain H 2 .
- a camera 4 having an image sensor capable of detecting light having a wavelength of 850 nm or more is installed as an imaging device for photographing the welded portion 3.
- An optical filter (long wavelength transmission filter) 6 that restricts light incident on the camera 4 to a wavelength range of 850 nm or more is attached to the front surface of the lens 5 of the camera 4, for example.
- the optical filter 6 corresponds to the first wavelength band limiting device in the present invention.
- being able to detect light having a wavelength of 850 nm or more means that the camera 4 has a quantum efficiency of 10% or more with respect to light having a wavelength of 850 nm or more. It is preferable that the camera 4 has a higher quantum efficiency of, for example, 20% or more for light having a wavelength of 850 nm or more.
- the image sensor capable of detecting light having a wavelength of 850 nm or more include CMOS, InGaAs, and InSb.
- the image processing apparatus 100 performs image processing on the image captured by the camera 4 and analyzes the welding state of the welded portion 3.
- Examples of the image processing apparatus 100 include a computer apparatus including a CPU, a ROM, and a RAM.
- FIG. 2A is a schematic diagram showing the first type of the welded state of the welded portion 3.
- FIG. 2B is a schematic diagram showing the second type of the welded state of the welded portion 3.
- FIG. 2C is a schematic diagram showing a transition region in the welded state of the welded part 3.
- FIG. 2D is a schematic diagram showing the second type of the welded state of the welded part 3.
- FIG. 2E is a schematic diagram showing excessive heat input in the welded state of the welded part 3. As the process proceeds from FIG. 2A to FIG. 2E, the amount of heat (heat input) applied to the welded portion 3 increases.
- the welding state of the welding part 3 is classified into five types according to the difference in heat input.
- the welding state when the heat input amount is less than the lower limit of the heat input amount necessary for welding is the first type shown in FIG. 2A.
- the welding state when the heat input is an appropriate heat input for welding is the second type shown in FIG. 2B.
- the welding state when the heat input amount is higher than that of the second type is a transition region shown in FIG. 2C.
- the welding state when the heat input is further increased from the transition region is the second type shown in FIG. 2D.
- the welding state when the amount of heat input is further increased from type 2 ′ is the excessive heat input shown in FIG. 2E.
- Geometric V convergence point V 0 the approximate line of the two butt ends 1a of the steel plate 1 which converges in a V-shape is a point intersecting the geometric. More specifically, when obtaining the geometric V convergence point V 0 , the image processing apparatus 100 linearly approximates a part of the butt end portion 1 a in the image taken by the camera 4, and is obtained thereby. the geometric V convergence point V 0 of the pair of intersection of the approximate straight line.
- Range with respect to the conveying direction X of the steel plate 1, can be defined as any range from the left end of the joining end 1a of the pictures taken with the camera 4, to the physical abutment point V 1 for linear approximation joining end 1a .
- the butt end portion 1a can be linearly approximated.
- Physical abutment point V 1 is both joining end 1a of the steel plate 1 which converges in a V-shape is in that physical abutment (contact).
- the welding point W is a point at which the discharge of molten steel by the squeeze roll 7 is started.
- the geometric V convergence point V 0 and the welding point W are separated, and a long and narrow gap called a slit 8 is generated. To do. Further, when the welding state of the welded part 3 of the plasma shield electro-resistance welding is excessive heat input from the transition region, the geometric V convergence point V 0 and the physical collision point V 1 are separated.
- the V-shaped convergence region has a characteristic shape having a two-stage V-shaped convergence angle. Thus, the phenomenon in which the V-shaped convergence region has two stages of V-shaped convergence angles is referred to as a two-stage convergence phenomenon.
- the camera 4 captures a range from the portion of the welded portion 3 where the steel plate 1 is in a red hot state to the welding point W.
- the image processing apparatus 100 determines the geometric V convergence point V 0 , the physical collision point V 1, and the welding point W based on the image of the welded portion 3 photographed by the camera 4. Therefore, the camera 4 images the welding point 3 with such a resolution that the image processing apparatus 100 can determine the geometric V convergence point V 0 , the physical collision point V 1, and the welding point W.
- the imaging region needs to include from the region where the red heat at the butt end 1a in the circumferential direction of the steel plate 1 can be detected by the camera 4 to the welding point W where the butt end 1a is crushed.
- the position where both butted ends 1a abut is shifted in the upstream direction or the downstream direction in the transport direction X depending on the pipe diameter, wall thickness, heat input conditions, or the like. Therefore, the camera 4 needs to secure an image field of view of 100 mm or more with respect to the conveyance direction X of the steel plate 1.
- the camera 4 preferably has a resolution of 60 ⁇ m or less when photographing a range having a width of 100 mm or more.
- having a resolution of 60 ⁇ m or less means having a resolution finer than 60 ⁇ m (having higher resolution characteristics).
- the camera 4 more preferably has a resolution of 60 ⁇ m or less when photographing a range having a width of 130 mm or more. More preferably, the camera 4 has a resolution of 60 ⁇ m or less when photographing a range having a width of 150 mm or more.
- the shutter speed of the camera 4 is preferably set to 1/5000 second or less. For the same reason as described above, it is more preferable to set it to 1/10000 second or less.
- the frame rate of the camera 4 (the number of images taken by the camera per second) is 30 fps (frame per second) or more.
- the weld bead portion refers to a raised portion formed by flowing out molten steel to the inner and outer surfaces of the steel plate 1 formed into a tubular shape when the both butted ends 1a are butted.
- the depth of field is ⁇ 4 mm or more.
- the camera 4 preferably adopts a progressive scan method.
- the progressive scan method is an image scanning method that sequentially scans images captured at the same timing, and is suitable for capturing moving images.
- the main components of the plasma irradiated by the plasma irradiation apparatus 2 are Ar and N 2 .
- Ar and N 2 are considered to emit light based on their emission spectra (bright line spectra).
- FIG. 3 is a characteristic diagram showing emission spectra of Ar, N 2 and O 2 .
- the light emission of the molten steel melted steel has a melting point of 1500 ° C. or higher
- the butt end 1a of the steel plate 1 is based on the Planck radiation spectrum.
- FIG. 4 is a characteristic diagram showing a spectrum of Planck radiation.
- the wavelength of the emission spectrum of the plasma was known, but the ratio of Planck radiation from the molten steel to be photographed and the emission intensity of the plasma was not known. Moreover, neither the wavelength (or frequency) of the emission spectrum nor the emission intensity has been known for light emission caused by the reaction between plasma and sputtering and the reaction between plasma and steel components.
- Patent Documents 3 and 4 disclose a technique for photographing a radiation pattern in a visible region of a welded portion using a color or monochrome camera using a CCD image sensor and analyzing the welding state by image processing, with respect to conventional electric welding. ing.
- a technique for photographing a radiation pattern in a visible region of a welded portion using a color or monochrome camera using a CCD image sensor and analyzing the welding state by image processing, with respect to conventional electric welding. ing.
- the photographing technique disclosed in Patent Documents 3 and 4 light emission generated by the self-emission of plasma and the reaction between plasma and sputtering.
- the emission spectrum of plasma is concentrated in the wavelength region of 400 to 800 nm, by using an image sensor capable of detecting light having a wavelength of 850 nm or more, such as InGaAs and InSb, the plasma itself is detected. It is considered that the influence of light emission, light emission caused by the reaction between plasma and sputtering, and light emission caused by the reaction between plasma and steel material components can be suppressed.
- sensitivity characteristics of an InGaAs image sensor are shown in FIG.
- the backside illuminated CMOS image sensor can detect light having a wavelength of 850 nm or more. Therefore, the inventors of the present invention have analyzed the welding state in plasma shielded electric resistance welding in which plasma is applied to the welded portion 3 in order to reduce welding defects, and the wavelength is 850 nm or more (as indicated by arrows in FIG. 5). I thought that it was effective to use the area shown in FIG.
- the CMOS image sensor has a low quantum efficiency in the region where the wavelength is 850 nm or more, and a low Planck radiation amount in the region where the wavelength is 850 nm or more. Was not known.
- the light quantity obtained when the camera is set to the maximum sensitivity is 30% or more of the dynamic range
- the level is 75 to 128 or higher in an image represented by 8-bit gradation.
- the amount of light is less than this, there is a problem in performing normal image processing, such as insufficient contrast, coarse gradation in digitization, and obtaining only discrete values.
- FIG. 6A is an image captured by mounting the optical filter 6 that transmits only light having a wavelength of 990 nm or more on the camera 4 having the CMOS image sensor having 2048 pixels in the horizontal direction.
- FIG. 6B is an image captured by attaching the optical filter 6 that transmits only light having a wavelength of 900 nm or more to the camera 4 having the CMOS image sensor.
- spatter, and the reaction of a plasma and a steel material component is suppressed. This condition has also been observed.
- FIG. 6C is an image captured by mounting the optical filter 6 that transmits only light having a wavelength of 810 nm or more on the camera 4 having the CMOS image sensor.
- the self-emission of plasma, the emission generated by the reaction between the plasma and the sputtering, and the emission generated by the reaction between the plasma and the steel material component are reflected, which hinders image processing.
- the optical filter 6 that transmits only light having a wavelength of 850 nm or more is attached to the camera 4 having the CMOS image sensor, the slit 8 is formed as in the case shown in FIGS. 6A and 6B. It was found that the condition could be observed.
- the inventor of the present application is suitable for photographing the welded portion 3 under conditions in which the camera 4 having the CMOS image sensor and the optical filter 6 that restricts the light incident on the camera 4 to a wavelength region of 850 nm or more are combined.
- the optical filter 6 preferably limits the light incident on the camera 4 to a wavelength range of 900 nm or more. Under this condition, it is possible to obtain a sufficient amount of light for photographing a radiation pattern from molten steel using a CMOS image sensor. Further, since the influence of the plasma can be suppressed at the longer wavelength side, the influence of the plasma can be further suppressed under this condition than in the case of 850 ⁇ m.
- the optical filter 6 limits the light incident on the camera 4 to a wavelength range of 990 nm or more.
- the optical filter 6 may adopt a configuration in which the light incident on the camera 4 is limited to only a part of the above-described wavelength ranges.
- FIG. 4 there is a peak of the radiance of Planck radiation near the wavelength of 1500 nm, and the radiance of Planck radiation is reduced on the longer wavelength side.
- the upper limit of the wavelength of the light transmitted through the optical filter 6 can be, for example, 5000 nm.
- the camera 4 having the CMOS image sensor is used as the camera 4 has been described.
- the camera 4 can detect light having a wavelength of 850 nm or more, and the camera 4 has the above-described resolution, field of view, and shutter speed. If the above is satisfied, the camera 4 is not limited to the camera 4 having a CMOS image sensor.
- FIG. 7 shows an image obtained by photographing the welded portion 3 of the plasma shield electric resistance welding with an InGaAs image sensor.
- the direction from left to right in FIG. 7 is the conveyance direction X of the steel plate 1. It can be seen that if the field of view is secured, the necessary resolution cannot be obtained, and detailed welding states such as slits cannot be recognized. On the other hand, if an element with a high pixel count can be manufactured in the future, InGaAs, InSb, etc. can be applied.
- the lens 5 having a focal length of 300 mm is attached to the camera 4 using a CMOS image sensor having a horizontal pixel count of 2048, a vertical pixel count of 512, and a frame rate of 200 fps. Install downwards at the position of. Then, an optical filter (long wavelength transmission filter) 6 provided with a multilayer film that transmits only light having a wavelength of 900 nm or more is attached to the front surface of the lens 5 of the camera 4. It adjusts so that the visual field about the conveyance direction X of the steel plate 1 at the time of image
- the shutter speed of the camera 4 is set to 1/10000 second, and the lens aperture of the camera 4 is set to F8.
- the optical filter 6 In the state where the optical filter 6 is mounted, only light having a wavelength of 900 nm or more is transmitted. Therefore, for example, when an imaging target is irradiated with an LED or a fluorescent lamp, an image capable of determining the imaging target cannot be obtained. Therefore, it is preferable to adjust the field of view of the camera 4 with the optical filter 6 removed.
- a scale (with a scale indicating a dimension such as a ruler) may be irradiated with a light source that generates light having a wavelength of 900 nm or more.
- a light source is a halogen light source. In this case, the field of view of the camera 4 can be adjusted even when the optical filter 6 is attached.
- the image processing apparatus 100 performs image processing on the image of the welded portion 3 sent from the camera 4, thereby performing three point geometric V convergence points V 0 , physical collision points V 1 , behavior of the welding points W, slits 8. And the state of the V-shaped convergence region are analyzed.
- FIG. 8 is a flowchart illustrating an example of processing for analyzing the welding state of the welded portion 3 using the image processing apparatus 100.
- FIG. 9A is a schematic diagram showing a method for linearly approximating the butt end 1a in the binarized image by the image processing apparatus 100.
- FIG. 9B is a schematic diagram illustrating a method of extracting the blob in the V-shaped convergence area by the image processing apparatus 100.
- FIG. 9C is a schematic diagram illustrating a method for setting a slit search region by the image processing apparatus 100.
- FIG. 9D is a schematic diagram illustrating a method for detecting a welding point W by the image processing apparatus 100.
- the image processing apparatus 100 repeatedly executes the image processing shown in FIG. 8 every time image data is sent from the camera 4.
- step S ⁇ b> 101 the image processing apparatus 100 inputs image data sent from the camera 4.
- step S102 the image processing apparatus 100 binarizes the image input in step S101. If necessary, in step S102, the image processing apparatus 100 performs edge enhancement processing on the image input in step S101.
- step S103 the image processing apparatus 100 linearly approximates the butt end 1a of the steel plate 1 in the image binarized in step S102.
- a schematic diagram of an image obtained by linearly approximating the butt end 1a is shown in FIG. 9A.
- the butt end 1a is linearly approximated by the method described above.
- the straight line approximation of the butt end 1a is performed in the upstream portion of the steel sheet 1 in the transport direction X from the position where the convergence of the second stage starts.
- step S104 the image processing apparatus 100 includes a geometrical V convergence point V 0 to the intersection of the joining end 901 which is linearly approximated in step S103.
- step S105 the image processing apparatus 100 calculates the bisector 902 of the corner (V-shaped convergence angle) formed by the pair of joining end 901 and the geometric V convergence point V 0 which is linearly approximated.
- step S106 the image processing apparatus 100 inverts and binarizes the image input in step S101.
- step S107 the image processing apparatus 100 performs a labeling process for allocating a label for each blob on the image binarized in step S106.
- the image processing apparatus 100 extracts a blob that meets a predetermined condition as a blob 903 in a V-shaped convergence area formed by both the butted ends 1a of the steel plate 1.
- a blob is an area to which the same label is assigned.
- the predetermined condition for example, the right edge of the image is not touched but only the left edge of the image is touched, the area is 50 mm 2 or more, and the vertical length of the blob is divided by the horizontal length of the blob.
- the condition that the measured value (aspect ratio) is 0.2 or less can be mentioned.
- step S108 the image processing apparatus 100, the most downstream point of the blob 903 of the V-convergence region extracted in step S107 the physical abutment point V 1.
- step S109 the image processing apparatus 100 sets a slit search area 904 in the image binarized in step S102.
- a portion where both butted ends 1a of the steel plate 1 are butted and observed as one line is called a weld line.
- the weld line is located on the bisector 902 of the V-shaped convergence angle obtained in step S105.
- the slit search area 904 is a rectangular area surrounding the bisector 902 of the V-shaped convergence angle.
- the physical collision point V 1 is the upstream end of the slit search area 904, and the downstream end of the image is the downstream end of the slit search area 904.
- the slit search area 904 is an area having a predetermined width (for example, 2 mm) in the positive and negative directions of the y-axis from the bisector 902 of the V-shaped convergence angle.
- step S110 the image processing apparatus 100 rebinarizes the slit search area 904 set in step S109.
- the image processing apparatus 100 performs a labeling process for assigning a label for each blob to the binarized image in the slit search area 904 obtained in step S110.
- step S112 the image processing apparatus 100 calculates the aspect ratio of each blob labeled in step S111, and determines whether there is a blob having an aspect ratio of less than 1/2. As a result of the determination, if there is a blob with an aspect ratio of less than 1/2, the process proceeds to step S113, and among the blobs with an aspect ratio of less than 1/2, the blob located on the most downstream side in the conveyance direction X of the steel plate 1 The most downstream point is set as a welding point W. In the case of FIG.
- step S114 connects the blob on the bisector 902 of the V-shaped convergence angle and then connect the connected blob.
- the most downstream point with respect to the conveying direction X of the steel plate 1 is set as a welding point W.
- the camera 4 is used to restrict only light having a wavelength of 900 nm or more to enter the camera 4 and the welded part 3 is photographed from above.
- a welding state can be analyzed based on the image which image
- the image processing by the image processing apparatus 100 has been mainly described, but for example, based on the result of the image processing, an image photographed by the camera 4 is added to the geometric V convergence point V 0 and the physical collision point V 1. , And welding points W may be superimposed and displayed on the monitor.
- the heat input amount may be set to increase when the distance V 1 -V 0 becomes equal to or less than a set value. In this case, it is not necessary to detect the position of the welding point W. Further, from the detected position of the welding point W, when the distance between the welding point W and the squeeze roll 7 becomes a set value or more, control may be performed so as to reduce the heat input amount.
- FIG. 10 shows the relationship between the amount of heat input and the defect occurrence rate of welding in plasma shield electro-welding when plasma is not irradiated (white square in the figure), when the plasma irradiation position is appropriate (black circle in the figure), And it is a figure shown about the case where the plasma irradiation position has shifted
- the horizontal axis of FIG. 10 represents the heat input, and is expressed as a ratio to the reference heat input during operation.
- shaft of FIG. 10 has shown the incidence rate of the welding defect, and is represented by the ratio of the defect occurrence area with respect to the total area of the welded part.
- the solid line in FIG. 10 is an approximate curve for the relationship between the amount of heat input and the incidence of welding defects when the plasma irradiation position is appropriate.
- the dotted line in FIG. 10 is an approximate curve regarding the relationship between the amount of heat input and the incidence of welding defects when the plasma irradiation position is deviated 10 mm upstream from the appropriate position in the conveying direction X of the steel sheet 1.
- the alternate long and short dash line in FIG. 10 is an approximate curve for the relationship between the amount of heat input and the incidence of welding defects when no plasma is irradiated.
- FIG. 10 shows that when the heat input is 80%, the plasma irradiation position is shifted from the appropriate position by 10 mm in the upstream direction of the conveying direction X of the steel sheet 1, thereby increasing the incidence of welding defects by several tens of times. Is shown (circled portion in FIG. 10). Further, in FIG. 10, when the heat input is 80%, the plasma irradiation position is shifted from the appropriate position by 10 mm in the upstream direction of the conveying direction X of the steel sheet 1, so that the incidence of welding defects is irradiated with plasma. It is shown that it is almost the same as the case without it.
- the plasma irradiation apparatus 2 preliminarily estimates the position of the geometric V convergence point V 0 in a state where only the molding is performed without welding, and based on the estimated position of the geometric V convergence point V 0.
- the plasma irradiation position was determined.
- the position of the geometric V convergence point V 0 is deviated by 10 mm or more between when welding is performed and when welding is not performed.
- the position of the geometrical V convergence point V 0 varies depending on the amount of heat input and the forming state of the roll group. Therefore, in the conventional method for determining the plasma irradiation position, there is a problem that the plasma irradiation position is shifted from an appropriate position and the welding quality is deteriorated. Thus, it is required to be able to detect in real time whether or not the plasma irradiation position is appropriate.
- FIG. 11 shows a schematic configuration of a welding state monitoring system in plasma shield electric resistance welding according to the second embodiment.
- symbol is attached
- a second camera 9 and a third camera 10 are installed separately from the camera 4 (hereinafter referred to as the first camera in the present embodiment).
- the second camera 9 is installed in order to detect a plasma irradiation position in a direction (width direction of the steel plate 1) perpendicular to the conveyance direction X of the steel plate 1 as described in detail below.
- the first camera 4 and the second camera 9 share the lens 5, and the branch unit 11 is incorporated between the first camera 4 and the second camera 9 and the lens 5.
- the branch unit 11 has a multilayer film that separates incident light into light of 900 nm or more and light of 500 nm or less. That is, in a state where the fields of view of the first camera 4 and the second camera 9 match, only light of 900 nm or more enters the first camera 4 and only light of 500 nm or less enters the second camera 9. .
- the branch unit 11 restricts the wavelength of light incident on the second camera 9 to 500 nm or less.
- the second camera 9 is not a camera for photographing Planck radiation at the butt end 1a of the steel plate 1, but a camera for photographing plasma.
- the branch unit 11 can restrict the wavelength of the light incident on the second camera 9 to 500 nm or less, thereby restricting the light caused by Planck radiation to enter the second camera 9.
- the branch unit 11 more preferably limits the wavelength of light incident on the second camera 9 to 450 nm or less.
- the emission spectra of Ar and N 2 have emission intensity even in the region where the wavelength is 450 nm or less.
- FIG. 3 the emission spectra of Ar and N 2 have emission intensity even in the region where the wavelength is 450 nm or less.
- the branch unit 11 can capture plasma emission with the second camera 9 in a state where the influence of Planck radiation is further reduced. It can.
- the branch unit 11 may limit the wavelength of light incident on the second camera 9 to a part of the wavelength range of 500 nm or less, such as the wavelength range of 400 nm to 500 nm or the wavelength range of 400 nm to 450 nm. Good.
- the branching unit 11 corresponds to the first wavelength band limiting device and the second wavelength band limiting device referred to in the present invention.
- the wavelength range of light incident on the first camera 4 restricted by the branch unit 11 is the same as the wavelength range of light incident on the camera 4 restricted by the optical filter 6 in the first embodiment. .
- At least one of the first camera 4 and the second camera 9 has a plane perpendicular to the optical axis and the optical axis 3 It has a total of four axis adjustment mechanisms that move in parallel with the axis and rotate around the optical axis.
- a calibration plate depicting a rectangle indicating the target field of view or an orthogonal scale is placed on the measurement target surface, and the first camera 4 Then, the calibration plate or scale is photographed using the second camera 9 and the fields of view of the first camera 4 and the second camera 9 are adjusted so that the photographed images coincide with each other. It is also possible to adjust the field of view of the first camera 4 and the second camera 9 by superimposing the image captured by the first camera 4 and the image captured by the second camera 9.
- the third camera 10 is installed in order to detect the plasma irradiation position in the conveyance direction X of the steel plate 1.
- an optical filter (short wavelength transmission filter) 13 is attached to the front surface of the lens 12 of the third camera 10.
- the optical filter 13 preferably limits the light incident on the third camera 10 to 500 nm or less. Similar to the second camera 9, the third camera 10 is not a camera for photographing Planck radiation at the butt end 1 a of the steel plate 1 but a camera for photographing plasma. For this reason, the optical filter 13 limits the wavelength of light incident on the third camera 10 to the above range, thereby limiting the light caused by Planck radiation from entering the third camera 10. . More preferably, the optical filter 13 limits the light incident on the third camera 10 to 450 nm or less. As shown in FIG. 3, the emission spectra of Ar and N 2 have emission intensity even in the region where the wavelength is 450 nm or less. On the other hand, as shown in FIG.
- the optical filter 13 limits the wavelength of light incident on the third camera 10 to 450 nm or less to capture plasma emission with the third camera 10 while further reducing the influence of Planck radiation. Can do.
- the optical filter 13 may limit the wavelength of light incident on the third camera 10 to a part of a wavelength range of 500 nm or less, such as a wavelength range of 400 nm to 500 nm or a wavelength range of 400 nm to 450 nm. Good.
- the optical filter 13 corresponds to the third wavelength band limiting device in the present invention.
- FIG. 12A is a diagram for explaining the arrangement of the third camera 10 as viewed from the side surface of the steel plate 1.
- FIG. 12B is a diagram for explaining the arrangement of the third camera 10 as viewed from above the steel plate 1.
- the third camera 10 takes an image of the welded portion 3 from an upstream side in the transport direction X of the steel plate 1 (already formed into a steel pipe shape) from either the left or right oblique direction of the transport direction X. As shown in FIG. 12A, the third camera 10 is preferably installed in a range of about 30 to 60 ° above the upper edge 1b of the steel plate 1 when viewed from the side of the steel plate 1. .
- the third camera 10 when viewed from above the steel plate 1 (already formed into a steel pipe shape), the third camera 10 has a width direction (in FIG. 12B, the steel plate 1 of the steel plate 1). It is preferably installed in the range of about 10 to 30 ° in the vertical direction of the transport direction X). After the third camera 10 is installed at the above-described position, the third camera 10 is used to adjust the position of the third camera 10 so that both the whole plasma and the welded portion 3 are captured. After determining the installation position of the third camera 10, the third line is set so that the position of the weld line corresponds to the image shot by the third camera 10 and the image shot by the first camera 4. The shooting range of the camera 10 is adjusted.
- the second camera 9 and the third camera 10 for example, similarly to the first camera 4, a monochrome camera including a CMOS image sensor can be used.
- the plasma exhibits a movement specific to plasma called plasma oscillation. Therefore, if the exposure time of the second camera 9 and the third camera 10 when imaging plasma is shortened, there is a possibility that the plasma cannot be appropriately captured. Therefore, in this embodiment, the exposure time of the second camera 9 and the third camera 10 is increased (for example, 1/40 second), and plasma is imaged. Since the amount of plasma emission is very large, the second camera 9 and the third camera 10 are preferably equipped with a neutral density filter.
- FIG. 13 is a flowchart illustrating an example of processing for detecting a plasma irradiation position in the width direction of the steel plate 1 using the image processing apparatus 100.
- FIG. 14A is a diagram illustrating an image obtained by photographing the welded portion 3 of the steel plate 1 with the second camera.
- FIG. 14B is a diagram illustrating extraction of an image processing region by the image processing apparatus 100 for detecting a plasma irradiation position in the width direction of the steel plate 1.
- FIG. 14C is a schematic diagram showing binarization of the plasma image by the image processing apparatus 100 for detecting the plasma irradiation position in the width direction of the steel plate 1.
- FIG. 14D is a schematic diagram illustrating detection of plasma blobs by the image processing apparatus 100 for detecting a plasma irradiation position in the width direction of the steel plate 1.
- FIG. 14E is a schematic diagram illustrating the calculation of the plasma blob centerline by the image processing apparatus 100 for detecting the plasma irradiation position in the width direction of the steel sheet 1.
- the frame rate of the first camera 4 is 200 fps and the frame rate of the second camera 9 is 40 fps will be described.
- the first camera 4 takes 5 frames while the second camera 9 takes 1 frame.
- an image captured by the first camera 4 is referred to as a welded portion image
- an image captured by the second camera 9 is referred to as a plasma image.
- step S201 the image processing apparatus 100 inputs plasma image data (see FIG. 14A) sent from the second camera 9.
- step S202 the image processing apparatus 100 limits an area (processing area) to be subjected to image processing for the plasma image input in step S201.
- the plasma image is appropriately used in a region where, in addition to the light caused by the plasma, the light caused by the reaction between the sputter and the plasma and the light caused by the reaction between the sputter and the steel component are mixed. It is difficult to process images.
- step S202 the image processing apparatus 100 is an image obtained by photographing the welded portion 3, sets the region upstream of the conveying direction X of the physical abutment point the steel plate 1 than V 1 as a processing region. Specifically, in step S202, the image processing apparatus 100 sets a region surrounded by a white dotted line in FIG. 14B as a processing region.
- the image processed in step S202 is an image originally captured by the second camera 9. For this reason, five frames of the welded portion image are captured by the first camera 4 after the previous frame of the image is captured and before the frame is captured. For each of the weld image, in step S108 shown in FIG. 8, the physical abutment point V 1 is being detected. In step S202, the image processing apparatus 100 calculates the average position of the physical abutment point V 1 of the 5 frame, sets the upstream regarding conveying direction X of the steel plate 1 than the average position as the processing area.
- step S203 the image processing apparatus 100 binarizes the processing area set in step S202 as shown in FIG. 14C.
- the image processing apparatus 100 performs a labeling process for assigning a label for each blob to the binarized processing area in step S203, and as shown in FIG. Extract as blob 1401.
- Examples of the predetermined condition include a condition in which both ends of the processing region are in contact and the area is 1000 mm 2 .
- step S205 the image processing apparatus 100 calculates a center line (hereinafter simply referred to as a center line) 1402 in the width direction of the steel sheet 1 for the plasma blob 1401 extracted in step S204, as shown in FIG. 14E.
- the center line 1402 extends in the conveyance direction X of the steel plate 1.
- step S206 the image processing apparatus 100 determines the width of the center line 1402 of the plasma blob 1401 with respect to the bisector 902 (that is, the weld line) of the V-shaped convergence angle obtained in step S105 of FIG. Obtain the direction shift and inclination.
- the plasma irradiation position in the width direction of the steel plate 1 is detected as a relative position with respect to the welded part 3 photographed by the first camera 4.
- the center line 1402 of the plasma blob 1401 is largely deviated from the bisector 902 of the V-shaped convergence angle, or the center line 1402 of the plasma blob 1401 is bisected to the bisector 902 of the V-shaped convergence angle. If it is greatly inclined, it can be said that the plasma irradiation position in the width direction of the steel sheet 1 is not appropriate.
- the image processing by the image processing apparatus 100 has been mainly described here.
- an image of plasma captured by the second camera 9 is superimposed on the image of the welded portion 3 captured by the first camera 4 and displayed on the monitor. You may make it do.
- plasma blob 1401 may be superposed center line 1402 and the physical abutment point V 1 and the like.
- difference regarding the width direction of the steel plate 1 of a plasma irradiation position can be expressed numerically and sensibly, and it becomes easy to adjust a plasma irradiation position manually.
- the plasma irradiation position is automatically adjusted so that the bisector 902 of the V-shaped convergence angle and the center line 1402 of the plasma blob 1401 coincide with each other. May be.
- the image processing apparatus 100 performs image processing on the image of the welded portion 3 of the steel plate 1 sent from the third camera 10 and detects a plasma irradiation position in the conveyance direction X of the steel plate 1.
- FIG. 15A and FIG. 15B the image image
- FIG. 15A is a diagram illustrating an image obtained by photographing the welded portion 3 with the third camera 10.
- FIG. 15B is a schematic diagram showing the positional relationship between the plasma torch 1501, the plasma gas 1502, and the bisector 1503 of the V-shaped convergence angle in FIG. 15A.
- the third camera 10 takes an image of the welded portion 3 upstream of the steel plate 1 in the conveyance direction X and above the steel plate 1 and from either the left or right oblique direction with respect to the conveyance direction X of the steel plate 1. Therefore, as shown in FIGS. 15A and 15B, the orientation of the image differs between the image captured by the third camera 10 and the image captured by the first camera 4 and the second camera 9. Note that the image shown in FIG. 15A was taken without the optical filter 13 being attached.
- the first camera 4 and the third camera 10 are used to photograph the steel plate 1 on which the marker is set in advance.
- the image captured by the first camera 4 and the image captured by the third camera 10 are associated with each other.
- FIG. 16 is a flowchart illustrating an example of processing for detecting a plasma irradiation position in the conveyance direction X of the steel plate 1 using the image processing apparatus 100.
- FIG. 17A is a schematic diagram illustrating binarization of a plasma image by the image processing apparatus 100 for detecting a plasma irradiation position in the conveyance direction X of the steel plate 1.
- FIG. 17B is a schematic diagram illustrating detection of plasma blobs by the image processing apparatus 100 for detecting a plasma irradiation position in the conveyance direction X of the steel plate 1.
- FIG. 17C is a schematic diagram illustrating calculation of a plasma irradiation axis by the image processing apparatus 100 for detecting a plasma irradiation position in the conveyance direction X of the steel plate 1.
- the image processing apparatus 100 repeatedly executes the image processing shown in FIG. 16 every time image data is sent from the third camera 10.
- the frame rate of the first camera 4 is 200 fps
- the frame rate of the third camera 10 is 40 fps. That is, as in the case of the second camera 9, the first camera 4 can capture 5 frames while the third camera 10 captures 1 frame.
- an image captured by the first camera 4 is referred to as a welded portion image
- an image captured by the third camera 10 is referred to as a plasma image.
- step S ⁇ b> 301 the image processing apparatus 100 inputs plasma image data sent from the third camera 10.
- step S302 the image processing apparatus 100 binarizes the plasma image input in step S301 as shown in FIG. 17A.
- step S303 the image processing apparatus 100 performs a labeling process for assigning a label for each blob to the plasma image binarized in step S302.
- step S303 the image processing apparatus 100 extracts, as a plasma blob 1701, a blob having the largest area among the blobs assigned with labels, as shown in FIG. 17B.
- step S304 the image processing apparatus 100 calculates the long axis of the blob 1701 as the irradiation axis 1702 by the moment calculation function, as shown in FIG. 17C.
- step S305 the image processing apparatus 100 determines the positional relationship between the irradiation axis 1702 with respect to the geometric V convergence point V 0 that is detected in step S104 of FIG. 8.
- step S ⁇ b> 304 the image for which the irradiation axis 1702 has been calculated is taken by the third camera 10. For this reason, five frames of the welded portion image are captured by the first camera 4 after the previous frame of the image is captured and before the frame is captured. For each of the weld image, in step S104 shown in FIG. 8, geometrical V convergence point V 0 is detected.
- step S305 the image processing apparatus 100 calculates the average position of the geometrical V convergence point V 0 which five frames, obtains the positional relationship between the irradiation axis 1702 with respect to its mean position.
- irradiation axis 1702 is far from geometrical V convergence point V 0 can be said to plasma irradiation position is not correct regarding the transport direction X of the steel plate 1.
- the plasma irradiation position may be adjusted based on the result of the image processing. For example, when the plasma irradiation position is out of the range of 20 mm upstream from the geometric V convergence point V 0 in the conveying direction X of the steel plate 1, the plasma irradiation position is automatically adjusted so as to be within that range. It may be configured.
- the plasma image captured by the second camera 9 is taken as an image of the welded part 3 captured by the first camera 4. Can be superimposed on each other.
- the field of view of the third camera 10 does not coincide with the field of view of the first camera 4, so the plasma image captured by the third camera 10 is welded 3 captured by the first camera 4. It cannot be overlaid on the image.
- a color camera equipped with a CCD or CMOS image sensor may be used as the third camera 10.
- a filter that transmits only light having a wavelength of 580 to 700 nm (mainly for photographing the butt end 1a of the steel plate 1) and light having a wavelength of 500 nm or less (mainly for photographing plasma) (band cut filter). ) May be attached to the third camera 10.
- the optical filter 6 that transmits only light having a wavelength of 900 nm or more is required.
- the major axis direction of the weld 3 is different from the major axis direction of the plasma.
- the welded portion 3 can be detected in the image taken by the third camera 10. Therefore, when detecting the plasma irradiation position in the conveyance direction X of the steel plate 1 using the image photographed by the third camera 10, it is possible to remove the welded portion 3 from the image photographed by the third camera 10. . In the case where the plasma irradiation position and the welded portion 3 overlap, when the welded portion 3 is removed from the image taken by the third camera 10, the plasma irradiation position of the portion overlapping the welded portion 3 is detected. Can not do it.
- the third camera 10 does not necessarily need to include the optical filter 13.
- the fourth camera When the plasma image captured by the third camera 10 is superimposed on the image of the welded portion 3, the fourth camera has the same field of view as the third camera 10 and has the same performance as the first camera 4.
- a camera may additionally be used.
- the third camera 10 and the fourth camera are used to photograph the welded portion 3 from an upstream side in the conveyance direction X of the steel plate 1 from any one of the left and right sides of the conveyance direction X of the steel plate 1. Also good.
- a welding state monitoring system and a welding state monitoring method used for plasma shielded electric resistance welding in which electric welding is performed by irradiating plasma to a welded portion of a steel sheet, and is not affected by plasma. It is possible to provide a welding state monitoring system and a welding state monitoring method capable of analyzing the welding state.
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Abstract
Description
本願は、2014年4月3日に、日本に出願された特願2014-77184号に基づき優先権を主張し、その内容をここに援用する。
従来の電縫溶接では、鋼板からなる帯状コイルを連続的に多数のロール群によって管状に成形する。そして、この管状の鋼板に対し、ワークコイルによる誘導加熱またはコンタクトチップによる直接通電加熱を行い、鋼板の周方向の端部(突合せ端部)を所定温度に加熱及び溶融するとともに、スクイズロールによって加圧しながら溶接して電縫鋼管を製造する。
電縫溶接の対象となる鋼板において、コンタクトチップまたはワークコイルとスクイズロールとに挟まれる突合わせ端部領域を溶接部と言う。
プラズマシールド電縫溶接では、溶接部の適所にプラズマを照射することにより、鋼板の突合わせ面が加熱、溶融する過程において、イオン化されたプラズマガスによる突き合わせ面のシールド作用や、イオン化されたプラズマガスによる還元作用等によって、酸素濃度の低い状態を保持できるようになる。その結果、溶接後に酸化物欠陥となる可能性のある突き合わせ面の酸化膜を発生過程において抑制することができ、欠陥の少ない高品質な溶接が可能になる。
図18Aは、従来の電縫溶接における鋼板の溶接部を、特許文献3及び4に開示された溶鋼の輻射パターンを可視域におけるカラー或いはモノクロ撮影技術により撮影した画像である。図18Aでは、左から右が鋼板の搬送方向であり、鋼板の周方向の両エッジ部がV字状に収束する様子が撮影されている。
(1)本発明の一態様に係る溶接状態監視システムは、鋼板の溶接部にプラズマを照射して電縫溶接を行うプラズマシールド電縫溶接に用いられる溶接状態監視システムであって、前記プラズマを前記溶接部に照射するプラズマ照射装置と、前記溶接部を上方から撮影する、波長が850nm以上である光を検出可能なイメージセンサを有する第1の撮像装置と、前記第1の撮像装置に入射する光を、850nm以上の波長域に制限する第1の波長域制限装置と、前記第1の撮像装置で撮影した画像を画像処理して、前記溶接部の溶接状態を解析する画像処理装置と、を備える。
[第1の実施形態]
図1に、第1の実施形態に係るプラズマシールド電縫溶接における溶接状態監視システムの概略構成を示す。
プラズマシールド電縫溶接では、鋼板1を上流(図1の右側)から下流(図1の左側)に搬送しながら、ロール群(図示せず)によって管状に成形し、ワークコイルによる誘導加熱またはコンタクトチップによる直接通電加熱を行い、鋼板1の突合せ端部1aを加熱及び溶融する。
本明細書では、鋼板1が搬送される方向である、上流から下流の方向を、鋼板1の搬送方向Xと呼称する。
なお、鋼板1の両突合せ端部1aにより形成されるV字状の角をV字収束角と言う。また、鋼板1の両突合せ端部1aにより形成されるV字状に収束した領域をV字収束領域と言う。
一方、突合せ端部1aにおいて、溶鋼の表面に生じた酸化物が適切に排出されなかった場合には、溶鋼の表面に生じた酸化物に起因するペネトレーターと呼ばれる溶接欠陥が生じる可能性がある。
プラズマ照射装置2が、プラズマシールド電縫溶接の際に溶接部3に対してプラズマを照射することにより、溶接部3がプラズマにより覆われる。また、プラズマ中には、後述の通り、H2ガスが含まれている場合には、溶接部3の周辺に還元性雰囲気が形成される。
これにより、溶接部3の周辺における酸素濃度が低くなり、溶接部3の表面に酸化物が形成されにくくなる。
より好ましくは、本実施形態のプラズマ照射装置2は、鋼板1上の長さが200mm以上の範囲に対してプラズマを照射可能であることが好ましい。
本実施形態のプラズマ照射装置2の消費電力は、約40kWである。これは、プラズマ溶接装置の消費電力の約1/10である。
本実施形態のプラズマ照射装置2が照射するプラズマは、Ar,N2が主成分である。これらの成分の他には、溶接部3の周辺に還元性雰囲気を形成するために、本実施形態のプラズマ照射装置2が照射するプラズマは、H2を含有する場合もある。
850nm以上の波長を有する光を検出可能なイメージセンサとしては、例えば、CMOS、InGaAs及びInSbが挙げられる。
図2A~図2Eを参照して、プラズマシールド電縫溶接の溶接部3の溶接状態について説明する。
図2Aは、溶接部3の溶接状態のうち、第1種を示す模式図である。図2Bは、溶接部3の溶接状態のうち、第2種を示す模式図である。図2Cは、溶接部3の溶接状態のうち、遷移領域を示す模式図である。図2Dは、溶接部3の溶接状態のうち、第2’種を示す模式図である。図2Eは、溶接部3の溶接状態のうち、過入熱を示す模式図である。
図2Aから図2Eに進むに従い、溶接部3に加えられる熱量(入熱量)が増加する。
入熱量が、溶接に必要な入熱量の下限未満である場合の溶接状態は、図2Aに示す第1種である。
入熱量が、溶接を行うのに適切な入熱量である場合の溶接状態は図2Bに示す第2種である。
遷移領域からさらに入熱量を増加した場合の溶接状態は、図2Dに示す第2’種である。
第2’種からさらに入熱量を増加した場合の溶接状態は、図2Eに示す過入熱である。
幾何学的V収束点V0は、V字状に収束する鋼板1の両突合せ端部1aの近似直線が幾何学的に交わる点である。より具体的には、幾何学的V収束点V0を求める際には、画像処理装置100が、カメラ4で撮影した画像中の突合せ端部1aの一部を直線近似し、これにより得られた一対の近似直線の交点を幾何学的V収束点V0とする。
なお、幾何学的V収束点V0を求める際は、予め突合せ端部1aのどの範囲を直線近似するか定めておく。突合せ端部1aを直線近似する範囲は、鋼板1の搬送方向Xに関して、カメラ4で撮影した画像における突合せ端部1aの左端から、物理的衝合点V1までの任意の範囲として定めることができる。例えば、突合せ端部1aの左端から、物理的衝合点V1までの50%の範囲において、突合せ端部1aを直線近似することができる。
溶接点Wは、スクイズロール7の圧下による溶鋼の排出が始まる点である。
プラズマシールド電縫溶接の溶接部3の溶接状態が第1種の場合には、幾何学的V収束点V0、物理的衝合点V1、及び溶接点Wの3つの点は略重なっている。
プラズマシールド電縫溶接の溶接部3の溶接状態が第2’種の場合には、V字収束領域が、2段階のV字収束角を持つ特徴的な形状となる。このように、V字収束領域が2段階のV字収束角を有する現象を2段収束現象と言う。
このとき、物理的衝合点V1が搬送方向Xの上流にホッピングすると、鋼板1の搬送方向Xの下流の電磁力が消失する。これにより、両突合せ端部1aの酸化物が排出されなくなり、溶接欠陥が増加する傾向がある。
溶接部3の溶接状態を適切に監視するために、カメラ4は、溶接部3のうち鋼板1が赤熱状態である部位から溶接点Wまでの範囲を撮影する。
後述するように、画像処理装置100は、カメラ4により撮影された溶接部3の画像に基づいて、幾何学的V収束点V0、物理的衝合点V1及び溶接点Wを決定する。そのため、カメラ4は、画像処理装置100が幾何学的V収束点V0、物理的衝合点V1及び溶接点Wを決定できるような分解能で溶接点3を撮影する。
撮影領域は、鋼板1の周方向の突合せ端部1aの赤熱がカメラ4で検知できる領域から、突合せ端部1aが圧下される溶接点Wまでを含む必要がある。両突合せ端部1aが突き合う位置は、管径、肉厚または入熱条件等によって搬送方向Xの上流方向または下流方向にずれる。そのため、カメラ4は、鋼板1の搬送方向Xに関して、100mm以上の画像視野を確保することが必要となる。
カメラ4は、130mm以上の幅を有する範囲を撮影した際に、60μm以下の分解能を有することがより好ましい。カメラ4は、150mm以上の幅を有する範囲を撮影した際に、60μm以下の分解能を有することがさらに好ましい。
溶接状態の時間変化を適切に捉えるためには、カメラ4のフレームレート(カメラが1秒間に撮像する枚数)は、30fps(frame per second)以上にすることが好ましい。
溶接部3の上方3m程度の位置にカメラ4を設置した場合には、上記の撮影条件を満たすために、カメラ4の絞り条件をF8~11に設定することが好ましい。
上述の通り、プラズマ照射装置2によって照射するプラズマの主成分は、Ar及びN2である。Ar及びN2は、それぞれの発光スペクトル(輝線スペクトル)に基づいて自発光すると考えられる。図3は、Ar、N2及びO2の発光スペクトルを示す特性図である。
一方、鋼板1の突合せ端部1aの溶鋼(溶鋼は1500℃以上の融点を持つ)の発光は、プランク輻射のスペクトルに基づくことが知られている。図4は、プランク輻射のスペクトルを示す特性図である。
例として、InGaAsイメージセンサの感度特性を図5に示す。
CMOSイメージセンサは、波長が850nm以上の領域では量子効率が低く、また、波長が850nm以上の領域ではプランク輻射量が低いため、上述した撮影条件を満たした上で十分な光量が得られるかについては知られていなかった。なお、カメラを最高感度にした場合に得られる光量が、ダイナミックレンジの30%以上の光量である場合には、十分な光量が得られるとし、ダイナミックレンジの50%以上の光量が得られることが好ましい。これは8ビット階調で表される画像において75~128レベル以上であることを表す。これ以下の光量では、コントラストが不十分であったり、デジタル化の階調が粗くなって、離散的な値しか得られなかったりする等、正常な画像処理を行う上で問題が生じる。
なお、図6A~6Cでは、左から右が鋼板1の搬送方向Xである。
図6A及び図6Bでは、プラズマの自発光、プラズマとスパッタとの反応により生じる発光及びプラズマと鋼材成分との反応により生じる発光によって溶接部3の撮影に与えられる影響が抑制されており、スリット8の状態も観察されている。
なお、図示はしないが、CMOSイメージセンサを有するカメラ4に波長850nm以上の光のみを透過する光学フィルタ6を装着した場合には、図6A及び図6Bに示した場合と同様に、スリット8の状態を観察できることが分かった。
光学フィルタ6は、カメラ4に入射する光を、900nm以上の波長域に制限することが好ましい。この条件では、CMOSイメージセンサを用いて溶鋼からの輻射パターンを撮影するのに十分な光量を得ることができる。また、長波長側ほどプラズマの影響を抑制できるため、この条件では、プラズマの影響を850μmの場合よりも更に抑制することが可能である。
光学フィルタ6は、カメラ4に入射する光を、990nm以上の波長域に制限することがより好ましい。
なお、光学フィルタ6は、カメラ4に入射する光を、上述の波長域のうち一部の波長域のみに制限する構成を採用してもよい。
光学フィルタ6が透過する光の波長の上限は、特に設けない。しかしながら、図4に示すように、波長1500nm付近にプランク輻射の放射輝度のピークが存在し、より長波長側ではプランク輻射の放射輝度が低減する。図4には示していないが、波長が5000nm超の領域では、プランク輻射の放射輝度が相当量減少する。そのため、光学フィルタ6が透過する光の波長の上限としては、例えば5000nmを挙げることができる。
上記の説明では、カメラ4としてCMOSイメージセンサを有するカメラ4を用いる場合について説明したが、カメラ4が850nm以上の波長を有する光を検出可能であり、カメラ4が上述した分解能、視野及びシャッタースピードを満たしていれば、カメラ4としてはCMOSイメージセンサを有するカメラ4に限られない。
水平方向画素数が2048個、垂直方向画素数が512個であり、フレームレートが200fpsであるCMOSイメージセンサを用いたカメラ4に焦点距離が300mmのレンズ5を装着し、溶接部3の上方3mの位置に下向きに設置する。そして、カメラ4のレンズ5の前面に、波長900nm以上の光のみを透過する多層膜を施した光学フィルタ(長波長透過フィルタ)6を装着する。画像を撮影した際の鋼板1の搬送方向Xについての視野が130mm程度になるように調整する。カメラ4のシャッタースピードを1/10000秒に設定し、カメラ4のレンズ絞りをF8に設定する。
光学フィルタ6を装着した状態でも、波長900nm以上の光を発生する光源でスケール(物差しなどの寸法を表わす目盛りがついたもの)を照射するようにしてもよい。このような光源の例としては、ハロゲン光源が挙げられる。この場合には、光学フィルタ6を装着した状態においても、カメラ4の視野を調整することが可能となる。
画像処理装置100は、カメラ4から送られる溶接部3の画像を画像処理することによって、3つの点幾何学的V収束点V0、物理的衝合点V1並びに溶接点Wの挙動、スリット8の状態及びV字収束領域の状態を解析する。
図8は、画像処理装置100を用いて溶接部3の溶接状態を解析する処理の例を示すフローチャートである。
画像処理装置100は、カメラ4から画像データが送られてくるたびに、図8に示す画像処理を繰り返し実行する。
ステップS102において、画像処理装置100は、ステップS101で入力した画像を2値化する。必要に応じて、ステップS102において、画像処理装置100は、ステップS101で入力した画像をエッジ強調処理する。
溶接状態が第1種、第2種及び遷移領域である場合には、前述の方法により突合せ端部1aを直線近似する。
一方、溶接状態が第2’種及び過入熱である場合には、2段目の収束が始まる位置よりも鋼板1の搬送方向Xの上流部分において、突合せ端部1aの直線近似を行う。
ステップS105において、画像処理装置100は、直線近似した一対の突合せ端部901と幾何学的V収束点V0とにより形成される角(V字収束角)の二等分線902を算出する。
ステップS107において、画像処理装置100は、ステップS106で反転2値化した画像に対し、ブロッブ毎にラベルを割り当てるラベリング処理を行う。図9Bに示すように、画像処理装置100は、所定の条件に合致するブロッブを、鋼板1の両突合せ端部1aにより形成されるV字収束領域のブロッブ903として抽出する。
所定の条件としては、例えば、画像の右端には接さずに、画像の左端のみに接しており、面積が50mm2以上であり、ブロッブの縦の長さをブロッブの横の長さで除した値(アスペクト比)が0.2以下であるという条件が挙げられる。
図9Cに示すように、スリット探索領域904を、V字収束角の二等分線902を囲む矩形状の領域とする。具体的には、物理的衝合点V1をスリット探索領域904の上流端とし、画像の下流端をスリット探索領域904の下流端とする。
図9Cに示すように、スリット探索領域904は、V字収束角の二等分線902からy軸の正の方向及び負の方向にそれぞれ所定の幅(例えば2mm)を有する領域である。
ステップS111において、画像処理装置100は、ステップS110で得られたスリット探索領域904の2値化画像に対し、ブロッブ毎にラベルを割り当てるラベリング処理を行う。
この判定の結果、アスペクト比が1/2未満のブロッブがある場合には、ステップS113に進み、アスペクト比が1/2未満のブロッブのうち、鋼板1の搬送方向Xの最下流にあるブロッブの最下流の点を溶接点Wと設定する。
図9Dの場合には、アスペクト比が1/2であり、鋼板1の搬送方向Xに関して最下流に位置するブロッブがブロッブ905であるため、ブロッブ905の鋼板1の搬送方向Xに関する最下流の点が溶接点Wとして設定される。
このようにブロッブのアスペクト比に基づいて溶接点Wの位置を設定することにより、例えばスリット探索領域904内にノイズに起因するブロッブ906がある場合でも、そのブロッブ906を除くことが可能になる。
なお、ここでは画像処理装置100による画像処理を中心に説明したが、例えば画像処理の結果に基づいて、カメラ4で撮影した画像に、幾何学的V収束点V0、物理的衝合点V1、及び溶接点W等を重ね合わせてモニタに表示するようにしてもよい。
また、画像処理の結果に基づいて、例えばV1-V0の距離が設定値以下になると入熱量を上げるように設定してもよい。この場合には、溶接点Wの位置を検出する必要はない。また、検出した溶接点Wの位置から、溶接点Wとスクイズロール7との距離が設定値以上になると入熱量を下げるように制御を行ってもよい。
第2の実施形態では、第1の実施形態で説明した溶接状態の解析に加えて、プラズマ照射位置を同時検出する例を説明する。
溶接部3がトップロールに挟まれていることや、鋼板1の突合せ端部1aが数度以下の狭い角度で接近すること等から、プラズマ照射装置2にはスペース的な制約が課される。そのため、プラズマの有効径が制限されるために、プラズマを照射できる範囲は限られ、溶接部3に対するプラズマ照射位置がずれると、所望の溶接品質が得られなくなる。
図10を参照して、プラズマ照射位置と欠陥発生率との関係について説明する。
図10の横軸は入熱量を示しており、操業時の基準入熱量に対する比率として表されている。
図10の実線は、プラズマ照射位置が適切な場合における、入熱量と溶接欠陥の発生率との関係についての近似曲線である。図10の点線は、プラズマ照射位置が適切な位置から鋼板1の搬送方向Xの上流方向に10mmずれた場合における、入熱量と溶接欠陥の発生率との関係についての近似曲線である。図10の一点鎖線は、プラズマを照射しなかった場合における、入熱量と溶接欠陥の発生率との関係についての近似曲線である。
また、図10には、入熱量が80%の場合には、プラズマ照射位置が適切な位置から鋼板1の搬送方向Xの上流方向に10mmずれることにより、溶接欠陥の発生率がプラズマを照射しなかった場合とほぼ同じであることが示されている。
このように、プラズマ照射位置が適切であるか否かをリアルタイムで検出できるようにすることが求められている。
第2の実施形態では、カメラ4(以下、本実施形態では第1のカメラと呼ぶ)とは別に、第2のカメラ9及び第3のカメラ10が設置される。
第1のカメラ4と第2のカメラ9とはレンズ5を共用し、第1のカメラ4及び第2のカメラ9とレンズ5との間には、分岐ユニット11が組み込まれる。分岐ユニット11は、入射した光を900nm以上の光と500nm以下の光とに分離する多層膜を有している。
すなわち、第1のカメラ4及び第2のカメラ9の視野が一致した状態で、第1のカメラ4には900nm以上の光のみが、第2のカメラ9には500nm以下の光のみが入射する。
分岐ユニット11は、第2のカメラ9に入射する光の波長を450nm以下に制限することがより好ましい。図3に示すように、Ar,N2の発光スペクトルは、波長が450nm以下の領域においても発光強度を有する。一方、図4に示すように、波長が450nm以下の領域において、プランク輻射の放射輝度は、波長が500nmの場合よりもさらに低減し、0に近くなる。そのため、分岐ユニット11が第2のカメラ9に入射する光の波長を450nm以下に制限することにより、プランク輻射の影響をより低減した状態で、第2のカメラ9によりプラズマ発光を撮影することができる。
なお、分岐ユニット11は、第2のカメラ9に入射する光の波長を、400nm~500nmの波長域または400nm~450nmの波長域のように、500nm以下の一部の波長域に制限してもよい。
なお、分岐ユニット11によって制限される第1のカメラ4に入射する光の波長の範囲は、第1実施形態における光学フィルタ6によって制限されるカメラ4に入射する光の波長の範囲と同様である。
第3のカメラ10の例えばレンズ12の前面に、光学フィルタ(短波長透過フィルタ)13が装着される。
光学フィルタ13は、第3のカメラ10に入射する光を450nm以下に制限することがより好ましい。図3に示すように、Ar,N2の発光スペクトルは、波長が450nm以下の領域においても発光強度を有する。一方、図4に示すように、波長が450nm以下の領域において、プランク輻射の放射輝度は波長が500nmの場合よりもさらに低減し、0に近くなる。そのため、光学フィルタ13が、第3のカメラ10に入射する光の波長を450nm以下に制限することにより、プランク輻射の影響をより低減した状態で、第3のカメラ10によりプラズマ発光を撮影することができる。
なお、光学フィルタ13は、第3のカメラ10に入射する光の波長を、400nm~500nmの波長域または400nm~450nmの波長域のように、500nm以下の一部の波長域に制限してもよい。
第2の実施形態では、光学フィルタ13が本発明における第3の波長域制限装置に相当する。
図12Aは、鋼板1の側面から見た第3のカメラ10の配置を説明するための図である。図12Bは、鋼板1の上方から見た第3のカメラ10の配置を説明するための図である。
図12Aに示すように、第3のカメラ10は、鋼板1の側面から見た場合に、鋼板1の上縁部1bに対して上方に30~60°程度の範囲に設置されるのが好ましい。
第3のカメラ10を上述の位置に設置した上で、第3のカメラ10を用いて、プラズマ全体と溶接部3との両方が写るように第3のカメラ10の位置を調整する。第3のカメラ10の設置位置を決定した後、第3のカメラ10により撮影される画像と、第1のカメラ4により撮影される画像とにおいて、溶接線の位置が対応するように、第3のカメラ10の撮影範囲を調整する。
プラズマは、プラズマ振動と呼ばれるプラズマに特有の運動を示す。そのため、プラズマを撮影する際の第2のカメラ9及び第3のカメラ10の露光時間を短くした場合には、適切にプラズマを撮影できない可能性がある。そのため、本実施形態では、第2のカメラ9及び第3のカメラ10の露光時間を長く(例えば1/40秒)して、プラズマを撮影する。
なお、プラズマの発光量は非常に大きいので、第2のカメラ9及び第3のカメラ10は、減光フィルタを装着することが好ましい。
図13及び図14A~図14Eを参照して、画像処理装置100を用いた、鋼板1の幅方向に関するプラズマ照射位置の検出方法について説明する。
図13は、画像処理装置100を用いて鋼板1の幅方向に関するプラズマ照射位置を検出する処理の例を示すフローチャートである。図14Aは、第2のカメラにより鋼板1の溶接部3を撮影した画像を示す図である。図14Bは、鋼板1の幅方向に関するプラズマ照射位置を検出するための、画像処理装置100による画像処理領域の抽出を示す図である。
図14Cは、鋼板1の幅方向に関するプラズマ照射位置を検出するための、画像処理装置100によるプラズマ画像の2値化を示す模式図である。図14Dは、鋼板1の幅方向に関するプラズマ照射位置を検出するための、画像処理装置100によるプラズマのブロッブの検出を示す模式図である。図14Eは、鋼板1の幅方向に関するプラズマ照射位置を検出するための、画像処理装置100によるプラズマのブロッブの中心線の算出を示す模式図である。
なお、図13の説明においては、第1のカメラ4で撮影した画像を溶接部画像、第2のカメラ9で撮影した画像をプラズマ画像と言う。
次に、ステップS202において、画像処理装置100は、ステップS201で入力したプラズマ画像について、画像処理の対象となる領域(処理領域)を限定する。
溶接部3を撮影した画像において、プラズマに起因する光に加えて、スパッタとプラズマとの反応に起因する光及びスパッタと鋼材成分との反応に起因する光が混在する領域では、プラズマ画像を適切に画像処理することが難しい。
溶接部3を撮影した画像において、物理的衝合点V1よりも鋼板1の搬送方向Xの下流の領域では、上述のように、プラズマに起因する光に加えて、スパッタとプラズマとの反応に起因する光及びスパッタと鋼材成分との反応に起因する光が混在する。
そのため、溶接部3を撮影した画像において、物理的衝合点V1よりも鋼板1の搬送方向Xの上流の領域では、プラズマ画像を適切に画像処理することが可能である。
具体的には、ステップS202において、画像処理装置100は、図14Bの白点線で囲んだ領域を処理領域として設定する。
ステップS202において、画像処理装置100は、5フレームの物理的衝合点V1の平均位置を算出し、その平均位置よりも鋼板1の搬送方向Xに関する上流を処理領域として設定する。
ステップS204において、画像処理装置100は、ステップS203で2値化した処理領域に対し、ブロッブ毎にラベルを割り当てるラベリング処理を行い、図14Dに示すように、所定の条件に合致するブロッブをプラズマのブロッブ1401として抽出する。所定の条件としては、例えば、処理領域の両端に接しており、かつ、面積を1000mm2有するなどの条件が挙げられる。
次に、ステップS206において、画像処理装置100は、図8のステップS105で得られているV字収束角の二等分線902(すなわち、溶接線)に対するプラズマのブロッブ1401の中心線1402の幅方向のずれ及び傾きを求める。すなわち、鋼板1の幅方向に関するプラズマ照射位置を、第1のカメラ4で撮影した溶接部3との相対位置として検出する。プラズマのブロッブ1401の中心線1402がV字収束角の二等分線902に対して大きくずれている場合またはプラズマのブロッブ1401の中心線1402がV字収束角の二等分線902に対して大きく傾いている場合には、鋼板1の幅方向に関するプラズマ照射位置が適切でないといえる。
プラズマのブロッブ1401の中心線1402がV字収束角の二等分線902に対して所定の閾値以上ずれている場合又はプラズマのブロッブ1401の中心線1402がV字収束角の二等分線902に対して所定の閾値以上傾いている場合には、V字収束角の二等分線902とプラズマのブロッブ1401の中心線1402とが一致するように、プラズマ照射位置を自動調整するように構成してもよい。
画像処理装置100は、第3のカメラ10から送られる鋼板1の溶接部3の画像を画像処理して、鋼板1の搬送方向Xに関するプラズマ照射位置を検出する。
図15A及び図15Bを参照して、第3のカメラ10により撮影される画像について説明する。
図15Aは、第3のカメラ10で溶接部3を撮影した画像を示す図である。図15Bは、図15Aにおけるプラズマトーチ1501、プラズマガス1502及びV字収束角の二等分線1503の位置関係を示す模式図である。
なお、図15Aに示す画像は、光学フィルタ13を装着しない状態で撮影したものである。
図16は、画像処理装置100を用いて鋼板1の搬送方向Xに関するプラズマ照射位置を検出する処理の例を示すフローチャートである。図17Aは、鋼板1の搬送方向Xに関するプラズマ照射位置を検出するための、画像処理装置100によるプラズマ画像の2値化を示す模式図である。
図17Bは、鋼板1の搬送方向Xに関するプラズマ照射位置を検出するための、画像処理装置100によるプラズマのブロッブの検出を示す模式図である。図17Cは、鋼板1の搬送方向Xに関するプラズマ照射位置を検出するための、画像処理装置100によるプラズマの照射軸の算出を示す模式図である。
ここで、第1のカメラ4のフレームレートが200fpsであるのに対して、第3のカメラ10のフレームレートは40fpsである。すなわち、第2のカメラ9の場合と同様に、第3のカメラ10により1フレーム撮影する間に、第1のカメラ4では5フレーム撮影することができる。
図16の説明においては、第1のカメラ4で撮影した画像を溶接部画像と呼称し、第3のカメラ10で撮影した画像をプラズマ画像と呼称する。
ステップS302において、画像処理装置100は、図17Aに示すように、ステップS301で入力したプラズマ画像を2値化する。
ステップS303において、画像処理装置100は、ステップS302で2値化したプラズマ画像に対し、ブロッブ毎にラベルを割り当てるラベリング処理を行う。また、ステップS303において、画像処理装置100は、図17Bに示すように、ラベルを割り当てたブロッブのうち、最大の面積を有するブロッブをプラズマのブロッブ1701として抽出する。
ステップS305において、画像処理装置100は、図8のステップS104で検出されている幾何学的V収束点V0に対する照射軸1702の位置関係を求める。ステップS304において、照射軸1702が算出された画像は、第3のカメラ10で撮影されたものである。そのため、その画像の1つ前のフレームが撮影されてから、該フレームが撮影されるまでの間に、第1のカメラ4により溶接部画像は5フレーム撮影されている。その溶接部画像のそれぞれに対して、図8に示すステップS104において、幾何学的V収束点V0が検出されている。
照射軸1702が幾何学的V収束点V0から大きく離れているときは、鋼板1の搬送方向Xに関するプラズマ照射位置が適切でないといえる。
ただし、上述の方法は、あくまでも第3のカメラ10でプラズマ及び溶接部3の両方を撮影してモニタに表示することを目的とするものである。第3のカメラ10で撮影した画像のみに基づいて、プラズマ照射による影響を抑えながら溶接部3の溶接状態を解析することは難しい。プラズマ照射による影響を抑えながら溶接部3の溶接状態を解析するためには、例えば、第1の実施形態で説明したように、波長900nm以上の光のみを透過する光学フィルタ6が必要となる。
プラズマ照射位置と溶接部3とが重なっている場合において、第3のカメラ10により撮影した画像から溶接部3を取り除いた場合には、溶接部3と重なっている部分についてのプラズマ照射位置を検出することができない。しかしながら、溶接部3と重なっていない部分におけるプラズマ照射位置とプラズマの照射方向とから、溶接部3と重なっている部分についてのプラズマ照射位置を検出することが可能である。
そのため、第3のカメラ10を用いて撮影した画像から、溶接部3を取り除いた場合には、第3のカメラ10は必ずしも光学フィルタ13を備える必要はない。
第3のカメラ10と第4のカメラとにより、鋼板1の搬送方向Xの上流の上方であって、鋼板1の搬送方向Xの左右いずれかの斜め方向から溶接部3を撮影するようにしてもよい。
1a 突合せ端部
1b 上縁部
2 プラズマ照射装置
3 溶接部
4 カメラ、第1のカメラ
5 レンズ
6 光学フィルタ
7 スクイズロール
8 スリット
9 第2のカメラ
10第3のカメラ
11 分岐ユニット
12 レンズ
13 光学フィルタ
100 画像処理装置
Claims (9)
- 鋼板の溶接部にプラズマを照射して電縫溶接を行うプラズマシールド電縫溶接に用いられる溶接状態監視システムであって、
前記プラズマを前記溶接部に照射するプラズマ照射装置と;
前記溶接部を上方から撮影する、波長が850nm以上である光を検出可能なイメージセンサを有する第1の撮像装置と;
前記第1の撮像装置に入射する光を、850nm以上の波長域に制限する第1の波長域制限装置と;
前記第1の撮像装置で撮影した画像を画像処理して、前記溶接部の溶接状態を解析する画像処理装置と;
を備えることを特徴とする、溶接状態監視システム。 - 前記第1の波長域制限装置が、前記第1の撮像装置に入射する光を、900nm以上の波長域に制限する
ことを特徴とする、請求項1に記載の溶接状態監視システム。 - 前記イメージセンサが、前記波長域の光に対して10%以上の量子効率を有する
ことを特徴とする、請求項1又は請求項2に記載の溶接状態監視システム。 - 前記第1の撮像装置は、100mm以上の幅を有する範囲を撮影した際に、60μm以下の分解能を有する
ことを特徴とする、請求項1から請求項3の何れか1項に記載の溶接状態監視システム。 - 前記画像処理装置が、V字状に収束する前記鋼板の両突合せ端部が幾何学的に交わる点である幾何学的V収束点とV字状に収束する前記鋼板の前記両突合せ端部が物理的に衝合する点である物理的衝合点とを求める
ことを特徴とする、請求項1から請求項4のいずれか1項に記載の溶接状態監視システム。 - 前記第1の撮像装置と同一の視野範囲を有する第2の撮像装置と、
前記第2の撮像装置に入射する光を波長500nm以下の光のみに制限する第2の波長域制限装置と、
を更に備え、
前記画像処理装置が、前記第2の撮像装置で撮影した画像に基づいて、前記鋼板の搬送方向に直交する方向である前記鋼板の幅方向のプラズマ照射位置を、前記溶接部を基準とする相対位置として求める
ことを特徴とする、請求項1から請求項5のいずれか1項に記載の溶接状態監視システム。 - 前記鋼板の前記搬送方向の上流であって、前記鋼板の上方かつ前記鋼板の前記搬送方向の左右いずれかの斜め方向から前記溶接部を撮影する第3の撮像装置を更に備え、
前記画像処理装置が、前記第3の撮像装置で撮影した画像に基づいて、前記鋼板の前記搬送方向の前記プラズマ照射位置を、前記溶接部を基準とする相対位置として求める
ことを特徴とする、請求項1から請求項6のいずれか1項に記載の溶接状態監視システム。 - 前記第3の撮像装置に入射する光を波長500nm以下の光のみに制限する第3の波長域制限装置を更に備える
ことを特徴とする請求項7に記載の溶接状態監視システム。 - 鋼板の溶接部にプラズマを照射して電縫溶接を行うプラズマシールド電縫溶接に用いられる溶接状態監視方法であって、
波長が850nm以上である光を検出可能なイメージセンサを備えた撮像装置を用いて、前記撮像装置に入射する光を850nm以上の波長域に制限して、前記溶接部を上方から撮影する工程と;
画像処理装置が、前記撮像装置で撮影した画像に基づいて、前記溶接部の溶接状態を解析する工程と;
を有することを特徴とする、溶接状態監視方法。
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US20160350902A1 (en) | 2016-12-01 |
EP3127646A1 (en) | 2017-02-08 |
US10262412B2 (en) | 2019-04-16 |
EP3127646A4 (en) | 2017-12-13 |
JP5880794B1 (ja) | 2016-03-09 |
JPWO2015152059A1 (ja) | 2017-04-13 |
EP3127646B1 (en) | 2021-11-10 |
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