WO2017130251A1 - 厚み計測方法及び厚み計測装置、並びに欠陥検出方法及び欠陥検出装置 - Google Patents
厚み計測方法及び厚み計測装置、並びに欠陥検出方法及び欠陥検出装置 Download PDFInfo
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- G01B21/08—Measuring arrangements or details thereof, where the measuring technique is not covered by the other groups of this subclass, unspecified or not relevant for measuring length, width, or thickness for measuring thickness
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- G01B21/02—Measuring arrangements or details thereof, where the measuring technique is not covered by the other groups of this subclass, unspecified or not relevant for measuring length, width, or thickness
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Definitions
- the present disclosure relates to a method and apparatus for measuring the thickness of a measurement object, and a method and apparatus for detecting a defect in an inspection object.
- Patent Document 1 discloses a defect diagnosis method (defect detection method) that can measure the depth from the surface of a defect such as a peeling or a cavity inside a structure (inspection object) using an infrared thermography method.
- the infrared thermography method detects the depth of defects by capturing changes in the surface temperature caused by heat transfer being hindered by the heat insulation of defects such as internal delamination and cavities in the structure, using an infrared camera (imaging device). It is a method to do.
- Infrared thermography requires heating or cooling of the structure in order to cause heat transfer within the structure. Heating / cooling methods include an active method using a heating device such as a heater or a lamp, and a passive method using solar radiation or natural air cooling.
- defect diagnosis method for measuring the defect depth inside the structure (inspection object) can be applied to a thickness measurement method for measuring the thickness of the measurement object.
- the passive method relies on solar radiation and natural air cooling, it takes a long time to obtain the temperature difference on the surface of the inspection object.
- the active method in general, after heating sufficiently to grasp the temperature difference in the thermal image generated by the infrared camera, the inside of the inspection object is based on the thermal image obtained by photographing the temperature difference generated during natural cooling. Since the depth of the defect is measured, it takes a relatively long time.
- the present disclosure provides a thickness measuring method and thickness measuring apparatus, a defect detecting method and a defect detecting apparatus capable of reducing the measuring time.
- the thickness measurement method in the present disclosure is a thickness measurement method for measuring the thickness of a measurement object, the step of heating the surface of the measurement object by a heating device, and the measurement target heated by the imaging device at a predetermined time interval
- a theoretical curve showing the change over time in the temperature of the surface of the measurement object is obtained by fitting a theoretical equation obtained from the heat conduction equation including the parameters related to the thickness of the measurement object to the temperature curve.
- the thickness measurement device is a thickness measurement device that measures the thickness of a measurement target, and inputs thermal image data generated by photographing the surface of the heated measurement target at a predetermined time interval.
- the defect detection method in the present disclosure is a defect detection method for measuring the depth of defects inside an inspection object, the step of heating the surface of the inspection object by a heating device, and a predetermined time interval by an imaging device, The step of photographing the surface of the heated inspection object and generating thermal image data corresponding to the temperature of the surface of the inspection object, and the time-dependent change of the temperature of the surface of the inspection object based on the thermal image data
- a theory that shows the change over time in the temperature of the surface of the object to be measured by fitting a theoretical equation obtained from the heat conduction equation including parameters related to the defect depth of the object to be inspected to the temperature curve.
- a defect detection apparatus is a defect detection apparatus that measures the depth of defects inside an inspection object, and is a thermal image generated by photographing the surface of a heated inspection object at a predetermined time interval.
- An input unit for inputting data, a first calculation unit for obtaining a temperature curve indicating a temporal change in the temperature of the surface of the measurement object based on the thermal image data, and a parameter related to the depth of the defect of the inspection object Fitting the theoretical formula obtained from the heat conduction equation, including the equation, to the temperature curve, and to obtain a theoretical curve indicating the change over time of the temperature of the surface of the measurement object, and the value of the parameter included in the theoretical formula corresponding to the theoretical curve And a second calculation unit for determining the depth of the defect of the inspection object.
- the thickness measurement method and apparatus can measure the thickness of a measurement object in a short time.
- the defect detection method and apparatus in this indication measure defects, such as peeling inside a test object, or a cavity, and can measure a defect in a short time.
- FIG. Diagram for explaining the outline of defect detection The figure which shows an example of the thermal image according to the temperature of the surface of the test subject image
- Diagram showing output of halogen lamp The figure which shows an example of the display of the measurement result of the defect depth by a display part The figure which shows the measurement operation
- FIG. The figure which shows the measurement operation
- FIG. The figure which shows the defect detection operation
- Diagram for explaining the outline of thickness measurement (A) The figure which shows the temperature curve obtained from the measured thermal image data in Example 1, and the theoretical curve obtained by fitting a theoretical formula to the measured temperature curve, (b) Inspection in Example 1 The figure which shows the measurement result of the depth of the defect of the object (A) The figure which shows the temperature curve obtained from the measured thermal image data in Example 2, and the theoretical curve obtained by fitting a theoretical formula to the measured temperature curve, (b) The theory in Example 2 The figure which shows the fitting result using a type
- the figure which shows the temperature curve obtained from the measured thermal image data in Example 3, and the theoretical curve obtained by fitting the theoretical formula which considered heat conduction and heat transfer to the measured temperature curve The figure which shows the temperature curve obtained from the measured thermal image data in Example 3, and the theoretical curve obtained by fitting the theoretical formula which considered heat conduction and heat transfer to the measured temperature curve.
- the figure which shows the measurement result of the depth of the defect of the test target object in Example 3 The figure which shows the measurement result of the depth of the defect of the test target object in Example 1 for comparison
- FIG. 1 is a diagram illustrating a configuration of a defect detection system 1 according to the first embodiment. As shown in FIG. 1, the defect detection system 1 performs defect detection by measuring the depth of a defect such as a peeling or a cavity inside an inspection object.
- the defect detection system 1 includes a halogen lamp 10, a lamp driving unit 11, an infrared camera 20, and a defect detection device 30.
- the halogen lamp 10 is a heating device that heats the surface of the inspection object.
- the halogen lamp 10 includes a shutter for starting and stopping the heating output.
- the lamp driving unit 11 is a device that drives the halogen lamp 10.
- the lamp driving unit 11 controls the start and stop of the heating output of the halogen lamp 10 according to the control of the control unit 35 of the defect detection device 30. For this reason, the lamp driving unit 11 controls the opening and closing of the shutter of the halogen lamp 10.
- the lamp driving unit 11 may control the start and stop of the heating output of the halogen lamp 10 by starting and stopping power supply to the halogen lamp 10.
- the infrared camera 20 is a photographing device that photographs the surface of the inspection object.
- the infrared camera 20 has a plurality of pixels, and generates thermal image data corresponding to the temperature of the surface of the inspection object at a predetermined frame rate.
- the defect detection device 30 controls the start and stop of the heating output of the halogen lamp 10 by controlling the lamp driving unit 11. Further, the defect detection device 30 controls the photographing operation of the infrared camera 20. Further, the defect detection device 30 performs defect detection by measuring the depth of the defect inside the inspection object based on the thermal image data from the infrared camera 20.
- the configuration of the defect detection apparatus 30 will be described.
- the defect detection device 30 is configured by a computer, for example. As shown in FIG. 1, the defect detection device 30 includes first to third communication units 31, 32, 33, a storage unit 34, a control unit 35, a display unit 36, and an operation unit 37.
- the first to third communication units 31, 32, and 33 are each configured with, for example, a communication interface (for example, USB, HDMI (registered trademark)).
- the first communication unit 31 is an input unit that sequentially receives thermal image data captured at a predetermined frame rate from the infrared camera 20.
- the second communication unit 32 receives lamp control information related to the start and stop of heating of the halogen lamp 10 from the control unit 35 and transmits the lamp control information to the lamp driving unit 11.
- the third communication unit 33 receives camera control information related to the start and end of shooting of the infrared camera 20 from the control unit 35 and transmits the camera control information to the infrared camera 20.
- the storage unit 34 is a recording medium, and includes, for example, an HDD or an SSD.
- the storage unit 34 sequentially stores the thermal image data received by the first communication unit 31.
- the storage unit 34 stores various setting values that are input from the operation unit 37 to be described later, and are necessary for measuring the depth of the defect of the inspection object.
- the storage unit 34 stores various programs for the control unit 35.
- the control unit 35 includes a CPU, an MPU, and the like, and controls the entire defect detection device 30 by executing various programs stored in the storage unit 34.
- the control unit 35 controls the start and stop of the heating output of the halogen lamp 10 by controlling the lamp driving unit 11.
- the control unit 35 controls shooting operations such as shooting start and shooting stop of the infrared camera 20.
- the control unit 35 obtains the defect depth of the inspection object based on the thermal image data stored in the storage unit 34.
- the control unit 35 functions as a first calculation unit, a fitting unit, and a second calculation unit. Details of these functions will be described in the operation description to be described later.
- the display unit 36 is configured by, for example, a display, and displays the depth of the defect obtained by the control unit 35 as, for example, color information or gradation information.
- the operation unit 37 is composed of, for example, a keyboard or a touch panel.
- the operation unit 37 is a device that is operated by the user when setting various setting values necessary for measuring the depth of the defect of the inspection object.
- the object to be inspected is naturally cooled.
- the surface temperature of the object 100 is imaged by an imaging device such as an infrared camera, and a thermal image corresponding to the surface temperature of the inspection object 100 is generated.
- a defect is detected based on a temperature difference indicated by a thermal image.
- FIG. 16 shows the change over time of the surface temperature of the defective part and the change over time of the surface temperature of the healthy part during natural cooling after heating.
- Curve 330 is the time change of the surface temperature of the healthy part
- curve 331 is the time change of the surface temperature of the defective part.
- the temperature difference ⁇ T2 between the surface temperature of the defective part and the surface temperature of the healthy part that occurs during natural cooling is the temperature between the surface temperature of the defective part and the surface temperature of the healthy part that occurs during heating. It becomes larger than the difference ⁇ T1.
- this phenomenon is used to detect a defect using a thermal image during natural cooling after heating.
- an imaging device such as an infrared camera is used to determine the surface temperature of the inspection object 100 while the surface of the inspection object 100 is heated by the heating device 10. 20, the thermal image data corresponding to the surface temperature of the inspection object 100 is generated. And the defect detection method of this indication performs a defect detection using this thermal image data and the theoretical formula (formula (1) mentioned later) obtained from a heat conduction equation.
- FIG. 3 is a diagram showing an example of a thermal image corresponding to the temperature of the surface of the inspection object photographed by the infrared camera.
- FIG. 4 is a diagram showing an example of a temperature curve showing the change with time of temperature in a partial region P of the thermal image shown in FIG.
- the broken line 200 is a temperature curve of the temperature change of the inspection object surface obtained from the actually measured thermal image data
- the solid line 201 is a theoretical expression of the equation (1) described later, and the temperature of the temperature change of the broken line 200. It is the theoretical curve of the temperature change of the surface of the test object obtained by curve fitting to a curve.
- a theoretical equation (1) described later obtained from the heat conduction equation is curve-fitted to the temperature curve 200 obtained from the actually measured thermal image data.
- the theoretical curve 201 is obtained.
- the defect depth of the inspection object is calculated from the value of the parameter a or b in the theoretical formula corresponding to the theoretical curve 201 using the formula (2) or formula (3) described later. Find L.
- FIG. 5 is a diagram showing an example of a temperature curve of a healthy part in an inspection object and an example of a temperature curve of a defective part.
- a curve 300 is a temperature curve showing the temperature change of the healthy part
- a curve 301 is a temperature curve showing the temperature change of the defective part.
- the temperature curves 300 and 301 in FIG. 5 are results calculated using a theoretical formula of formula (1) described later.
- FIG. 5 is a diagram showing an example of a temperature curve of a healthy part in an inspection object and an example of a temperature curve of a defective part.
- a curve 300 is a temperature curve showing the temperature change of the healthy part
- a curve 301 is a temperature curve showing the temperature change of the defective part.
- the temperature curves 300 and 301 in FIG. 5 are results calculated using a theoretical formula of formula (1) described later.
- the value of mortar (concrete) is used as each material constant (the thermal diffusivity ⁇ is 1.21 ⁇ 10 ⁇ 6 m 2 / s, which is the general thermal diffusivity of concrete), and the defect portion
- a difference begins to appear between the surface temperature of the healthy part and the surface temperature of the defective part from the heating time of about 120 seconds.
- fitting measurement is possible if there is thermal image data for a time (ie, heating time) to the extent that a difference appears between the surface temperature of the healthy part and the surface temperature of the defective part. Therefore, in the defect detection method of the present disclosure, the heating time of the surface of the inspection object and the measurement time from the heating to the measurement of the defect depth can be shortened compared to the conventional case (example of FIG. 5). (Several minutes to several tens of minutes).
- the heating time at which the surface temperature difference starts to appear is related to the defect depth, and becomes longer as the defect depth becomes deeper.
- T (x, t) is the surface temperature [K] of the inspection object
- x is the position [m] in the depth direction with respect to the surface of the inspection object (0 ⁇ x ⁇ L )
- T is the time [s]
- F 0 is the heat flux [W / m 2 ]
- ⁇ is the density [kg / m 3 ] of the inspection object
- c is the specific heat [J of the inspection object] / (Kg ⁇ K)]
- ⁇ c is the volume specific heat [J / (m 3 ⁇ K)] of the inspection object
- k is the thermal conductivity [W / (m ⁇ K)] of the inspection object.
- the inventor of the present application tried to curve-fit the above theoretical formula into a temperature curve obtained from actually measured thermal image data.
- there are four fitting parameters F 0 , ⁇ c, k, and L and a plurality of combinations exist as solutions of F 0 , ⁇ c, k, and L.
- the inventor of the present application converts the four parameters F 0 , ⁇ c, k, and L into two parameters a and b as shown in the following formula (2) and the following formula (3), It was found that this can be dealt with by reducing the fitting parameters.
- the defect detection method of the present disclosure performs fitting on the actually measured temperature curve using the above equations (1) to (3).
- control unit 35 acquires the maximum heating time Tm, the maximum measurement depth Lm, the measurement range W, and the unit measurement range P as set values (S10). These set values are input by the user using the operation unit 37 and stored in the storage unit 34 in advance.
- the maximum measurement depth Lm is the maximum value of the depth to be measured in this defect detection, and is set according to the depth of the defect to be detected. For example, in the detection of defects on highways and the like, the outermost steel frame is 50 cm from the surface, so it is required to detect whether there are defects such as delamination or cavities up to a depth of about 50 cm from the surface. ing. In such a case, the maximum measurement depth Lm is set to 50 cm.
- the maximum heating time Tm is set in relation to the maximum measurement depth Lm.
- the maximum heating time Tm is set to a heating time at which a difference appears sufficiently between the surface temperature of the defective portion and the surface temperature of the healthy portion at the maximum measurement depth Lm.
- the measurement range W is a range in which measurement is performed in the imaging range of the infrared camera 20, as shown in FIG.
- the unit measurement range P is a range in which measurement is performed at once in the measurement range W, as shown in FIG.
- the unit measurement range P is set for each pixel of the infrared camera 20, and may be one pixel unit or a plurality of pixel units. When the unit measurement range P is a unit of a plurality of pixels, the thermal image data corresponding to these pixels may be averaged.
- control unit 35 controls the lamp driving unit 11 to open the shutter of the halogen lamp 10 and heat the surface of the inspection object so that the heat flux Fo is constant as shown in FIG. It starts in a step shape (S11). That is, heating is performed so that the heating input becomes a step input.
- control unit 35 controls the infrared camera 20 simultaneously with the start of heating of the inspection object, and starts photographing the surface of the inspection object (S11).
- the above equation (1) is a theoretical equation of the heat conduction equation at the time of step response. Therefore, in order to actually measure the temperature curve for fitting to this theoretical formula, heating is started in a step-like manner.
- the control unit 35 supplies power to the halogen lamp 10 in advance, and controls the opening and closing of the shutter of the halogen lamp 10 to start heating the surface of the inspection object in a stepped manner. To do.
- control unit 35 acquires thermal image data corresponding to the surface temperature of the inspection object from the infrared camera 20 (S12).
- the acquired thermal image data is stored in the storage unit 34.
- control unit 35 determines whether or not the heating time t from the start of heating exceeds the maximum heating time Tm (S13), and acquires thermal image data until the heating time t exceeds the maximum heating time Tm. Continue (S12).
- the control unit 35 controls the infrared camera 20 and ends the imaging of the surface of the inspection object (S14). Moreover, the control part 35 controls the lamp drive part 11, closes the shutter of the halogen lamp 10, and complete
- control unit 35 measures the defect depth (S15). This process will be described later.
- FIG. 8 is a diagram illustrating an example of display of the measurement result of the defect depth.
- FIG. 8 shows that a defect having a defect depth L exists in the region A.
- the control unit 35 may display the defect depth L information as color information as shown in FIG. 8, or may display it as gradation information.
- the control unit 35 for each unit measurement range P, the control unit 35, as shown in FIG. 4, based on the thermal image data acquired during the maximum heating time Tm, a temperature curve indicating the change over time of the surface temperature of the inspection object. 200 is obtained (S150).
- control unit 35 fits the theoretical equation of the above equation (1) obtained from the heat conduction equation to the obtained temperature curve 200 to obtain a theoretical curve 201 indicating the change over time in the temperature of the surface of the inspection object.
- the control unit 35 changes the parameters a and b in the theoretical formula of the above formula (1), and performs fitting so that the residual is minimized by using the nonlinear least square method.
- the control unit 35 obtains the defect depth L of the inspection object using the above equation (3) from the value of the parameter b in the theoretical equation of the above equation (1) corresponding to the theoretical curve 201 (S152). .
- the thermal diffusivity ⁇ in the above equation (3) for example, a substance constant based on the material information of the inspection object may be used.
- the control unit 35 calculates the defect depth L of the inspection object from the value of the parameter a, the heat flux F 0 based on the material information of the inspection object, and the thermal conductivity k using the above equation (2). You may ask for it.
- control unit 35 determines whether or not the defect depth measurement has been completed for all the unit measurement ranges P in the measurement range W (S153). If there is a unit measurement range P that has not been measured yet, the control unit 35 repeats the above processing until the above-described steps S150 to S153 are performed on all the unit measurement ranges P. On the other hand, when the defect depth measurement is completed for all the unit measurement ranges P in step S153, the control unit 35 ends the defect depth measurement operation.
- the defect detection method is a defect detection method for measuring the depth of the defect inside the inspection object.
- the surface of the inspection object is heated by the halogen lamp (heating device) 10 and the inspection object heated by the infrared camera (imaging device) 20 at the maximum heating time interval (predetermined time interval) Tm.
- a step of photographing the surface of the object and generating thermal image data corresponding to the temperature of the surface of the inspection object, and a temperature curve 200 indicating a change with time of the temperature of the surface of the inspection object is obtained based on the thermal image data.
- the surface of the measurement object is obtained by fitting a theoretical formula (formula (1)) obtained from the heat conduction equation including the steps and parameters a and b related to the defect depth L of the inspection object to the temperature curve 200. Based on the step of obtaining the theoretical curve 201 indicating the change in temperature of the sample over time and the value of the parameter b included in the heat conduction equation corresponding to the theoretical curve 201, And a step of determining the depth of Recessed.
- the defect detection apparatus 30 is the defect detection apparatus 30 which measures the depth of the defect inside a test target object, Comprising: The 1st communication part (input part) 31 and a control part ( A first calculation unit, a fitting unit, and a second calculation unit) 35.
- the first communication unit 31 inputs thermal image data generated by photographing the surface of the heated inspection object at the maximum heating time interval (predetermined time interval) Tm.
- the control unit 35 obtains a temperature curve 200 indicating the change over time of the temperature of the surface of the measurement object.
- control unit 35 fits a theoretical equation (the above equation (1)) obtained from a heat conduction equation including parameters a and b related to the depth of defects of the inspection object to the temperature curve 200, and then measures the measurement object.
- a theoretical curve 201 indicating a change with time in the temperature of the surface of the object is obtained.
- the control unit 35 obtains the defect depth L of the inspection object based on the value of the parameter b included in the heat conduction equation corresponding to the theoretical curve 201.
- the defect detection system 1 is a defect detection system 1 that measures the depth of a defect inside an inspection object, and includes a halogen lamp (heating device) 10 and an infrared camera (imaging device). 20 and the defect detection apparatus 30 described above.
- the halogen lamp 10 heats the surface of the inspection object.
- the infrared camera 20 images the surface of the heated inspection object and generates thermal image data corresponding to the temperature of the surface of the inspection object.
- the defect detection device 30 measures the depth of the defect inside the inspection object based on the thermal image data.
- the defect depth can be obtained by using the thermal image data during heating corresponding to the theoretical formula at the time of step response of the above equation (1) obtained from the heat conduction equation.
- the theoretical formula (1) is fitted to the temperature curve obtained from the measured thermal image data, thermal image data with a relatively small temperature difference, that is, acquired in a relatively short heating time from the start of heating.
- the defect depth can be obtained from the obtained thermal image data. Therefore, the heating time of the surface of the inspection object and the measurement time from the heating to the measurement of the defect depth can be shortened.
- the defect depth at the maximum measurement depth Lm is measured only once using all the thermal image data acquired during the maximum heating time Tm.
- the defect depth is measured while changing the depth to be measured stepwise using a part of the thermal image data acquired stepwise during the maximum heating time Tm.
- control unit 35 sets the measurement depth interval Sm and the measurement time interval S in addition to the above-described maximum heating time Tm, maximum measurement depth Lm, measurement range W, and unit measurement range P. Obtained as a set value (S20).
- steps S21, S22, S23, and S24 are performed.
- the operations in steps S21, S22, S23, and S24 are the same as the operations in steps S11, S12, S13, and S14, respectively.
- the control part 35 acquires the thermal image data in the maximum heating time Tm, before performing defect depth measurement.
- control unit 35 first sets n to an initial value 1 when measuring the defect depth in stages at the n measurement depths n ⁇ Sm with respect to the maximum measurement depth Lm (S25). .
- control unit 35 uses the thermal image data measured up to the measurement time n ⁇ S among the thermal image data acquired during the maximum heating time Tm, and uses the measurement depth of the maximum measurement depth Lm.
- the depth of defects existing up to n ⁇ Sm is measured (S26). Details of the defect depth measurement process will be described later.
- control unit 35 increases n by 1 in order to change the depth of the measurement target (S27).
- the control unit 35 determines whether or not the measurement depth n ⁇ Sm exceeds the maximum measurement depth Lm, or whether or not the measurement time n ⁇ S exceeds the maximum heating time Tm (S28). .
- the process returns to step S26, and the control unit 35 uses thermal image data corresponding to the measurement time increased by the measurement time interval S.
- the depth of the defect existing up to the measurement depth increased by the measurement depth interval Sm is measured.
- step S28 when n ⁇ Sm exceeds Lm or n ⁇ S exceeds Tm in step S28, the control unit 35 displays the measurement result of the defect depth in the measurement range W on the display unit 36. (S29), and the defect detection operation is terminated.
- step S26 of FIG. 10 will be described with reference to the flowchart of FIG.
- the control unit 35 uses the thermal image data measured up to the measurement time n ⁇ S among the thermal image data acquired during the maximum heating time Tm, as shown in FIG. As described above, the temperature curve 200 indicating the change with time of the surface temperature of the inspection object is obtained (S260).
- the control unit 35 does not measure the defect depth for the unit measurement range P corresponding to the thermal pixel data for which the measurement end flag is set in step S263 to be described later.
- the measurement end flag is a flag indicating that the measurement of the defect depth has ended.
- the control part 35 performs the redundant measurement about the unit measurement range P in which the measurement of the defect depth has already been completed by the step of the last measurement depth nxS in step S262 mentioned later. Can be avoided.
- steps S261 and S262 are performed.
- the operations in steps S261 and S262 are the same as the operations in steps S151 and S152 described above, respectively. Thereby, it is possible to measure the depth of the defect existing up to the measurement depth n ⁇ S.
- control unit 35 sets a measurement end flag for the thermal image data of the unit measurement range P for which the defect depth L is obtained (S263).
- the theoretical formula of the above formula (1) is fitted to the temperature curve obtained from the thermal image data actually measured during heating, so that it is acquired in a relatively short heating time from the start of heating.
- the defect depth can be obtained from the obtained thermal image data. Therefore, the heating time of the surface of the inspection object and the measurement time from the heating to the measurement of the defect depth can be shortened.
- the defect depth is measured stepwise after acquiring all the thermal image data over the maximum heating time Tm.
- the defect depth is measured step by step during the acquisition of the thermal image data.
- steps S30 and S31 are performed.
- the operations in steps S30 and S31 are the same as the operations in steps S20 and S21 described above, respectively. Thereby, heating of the surface of the inspection object is started, and imaging of the surface of the inspection object is started.
- control unit 35 sets n to an initial value 1 at this time (S32).
- step S33 is performed.
- the operation in step S33 is the same as that in steps S22 and S12 described above. Thereby, acquisition of thermal image data is started.
- control unit 35 determines whether or not the heating time t has reached the measurement time n ⁇ S from the start of heating (S34), and if the heating time t has not reached n ⁇ S, Returning to S33, the acquisition of the thermal image data is continued.
- the defect depth is measured using the thermal image data measured by the time nxS (S35).
- the defect depth measurement (S35) is the same as the above-described step S26, that is, the defect depth measurement operation in FIG.
- control unit 35 displays the measurement result of the defect depth on the display unit 36 in real time when the measurement of the defect depth is completed at each stage of the measurement depth nxS (S36).
- control unit 35 increases n by 1 in order to change the depth of the measurement target (S37).
- the control unit 35 determines whether or not the measurement depth n ⁇ Sm exceeds the maximum measurement depth Lm, or whether or not the measurement time n ⁇ S exceeds the maximum heating time Tm (S28). If n ⁇ Sm does not exceed Lm and n ⁇ S does not exceed Tm, the process returns to step S33, and measurement is performed step by step with respect to the measurement depth n ⁇ Sm while acquiring thermal image data. Measurement of the depth of defects existing up to the depth n ⁇ Sm is performed in real time.
- step S38 when n ⁇ Sm exceeds Lm or n ⁇ S exceeds Tm, the control unit 35 determines that the heating time t has exceeded the maximum heating time Tm, and is described above. Similar to steps S24 and S14, imaging of the surface of the inspection object is terminated, heating of the surface of the inspection object is terminated (S14), and the defect detection process is terminated.
- the theoretical formula of the above formula (1) is fitted to the temperature curve obtained from the thermal image data actually measured during heating, so that it is acquired in a relatively short heating time from the start of heating.
- the defect depth can be obtained from the obtained thermal image data. Therefore, the heating time of the surface of the inspection object and the measurement time from the heating to the measurement of the defect depth can be shortened.
- the defect depth information measured in real time step by step at the measurement depth interval Sm with respect to the maximum measurement depth Lm can be displayed in real time step by step.
- the theoretical formula of Formula (1) obtained from the heat conduction equation is used as a theoretical formula for fitting to the temperature curve of the temperature change of the actually measured surface of the inspection object.
- the theoretical formula of the following formula (1a) is used instead of the formula (1).
- a function with a hat symbol “ ⁇ ” in the formula indicates that a function without a hat is a Laplace transform function with respect to time t.
- thermohydrodynamics there are three heat transfer phenomena in thermohydrodynamics: heat conduction, heat conduction, and heat radiation.
- Thermal conduction refers to a phenomenon in which heat moves inside a solid from a high temperature side to a low temperature side.
- Heat transfer refers to a phenomenon in which heat is transferred between a solid wall and a fluid (eg, air).
- Thermal radiation refers to a phenomenon in which heat is released from a solid.
- FIG. 17A is a schematic diagram for explaining heat conduction.
- F 0 a constant heat flux
- F 0 a constant heat flux
- L the depth of the defect 101 from the front surface 102 to the back surface 103 of the inspection object 100.
- the position x of the back surface 103 is 0, and the position x of the front surface 102 is L.
- FIG. 17B and FIG. 17C are schematic diagrams for explaining heat transfer. As shown in FIG. 17B, heat transfer occurs in which heat is transferred from the surface 102 of the inspection object 100 to the air in contact with the surface 102 with heat flux h 1 T (L, s) (hat symbol omitted). Further, as shown in FIG. 17B, heat transfer occurs in which heat is transferred from the surface 102 of the inspection object 100 to the air in contact with the surface 102 with heat flux h 1 T (L, s) (hat symbol omitted). Further, as shown in FIG.
- heat transfer is generated in which heat is transferred from the back surface 103 of the inspection object 100 to the air in contact with the back surface 103 with a heat flux h 2 T (L, s) (hat symbol omitted).
- h 1 and h 2 are heat transfer coefficients (heat transfer coefficients) [W / (m 2 ⁇ K)].
- a theoretical equation for temperature change is derived in consideration of only heat transfer on the surface 102 of the inspection object 100.
- the above equation (13a) is the same as the above equation (13).
- the heat flux of heat transfer on the surface 102 of the inspection object 100 H 1 T (L, s)
- the following equation (15a) is derived as a theoretical equation (s function) in the step response. Is done.
- the configurations of the defect detection device 30 and the defect detection system 1 of the present embodiment are basically the same as those of the first embodiment described with reference to FIG. 1, and the function of the control unit 30 of the defect detection device 30.
- the operation is basically the same as that of the first embodiment described with reference to FIGS.
- the control unit 30 of the defect detection apparatus 30 uses the theoretical expressions (1a) to (3a) instead of the theoretical expressions (1) to (3) in steps S151 and S152 of FIG. Different from that.
- step S151 in FIG. 9 the control unit 35 fits the theoretical formula of the formula (1a) obtained from the heat conduction equation to the temperature curve 200 of the actually measured temperature change of the test object surface, and thereby the surface of the test object.
- the theoretical curve 201 showing the change with time of the temperature is obtained (see FIG. 4).
- step S152 the control unit 35 obtains the defect depth L of the inspection object using the equation (3s) from the value of the parameter b in the theoretical equation of the equation (1a) corresponding to the theoretical curve 201.
- the theoretical formula of the formula (1a) is fitted to the temperature curve obtained from the thermal image data measured during heating, so that it was acquired in a relatively short heating time from the start of heating. Defect depth can be determined from thermal image data. Therefore, the heating time of the surface of the inspection object and the measurement time from the heating to the measurement of the defect depth can be shortened.
- the measured temperature curve is fitted to obtain a theoretical curve, and the value of the parameter b in the theoretical formula corresponding to the theoretical curve
- the depth of the defect of the inspection object is obtained from the above, there are the following problems. That is, when the depth of the defect of the inspection object is deepened, the depth of the defect is measured deeper than the actual depth as the heating time (number of measurement data) increases (see Example 3 described later).
- the heat flux (h 2 T (0, s)) of heat transfer on the back surface 103 of the inspection object 100 is taken into consideration as compared with the above equations (13) and (13a). (Hat symbol omitted).
- the above equation (14b) is the same as the above equation (14a).
- the configurations of the defect detection device 30 and the defect detection system 1 of the present embodiment are basically the same as those of the first embodiment described with reference to FIG. 1, and the function of the control unit 30 of the defect detection device 30.
- the operation is basically the same as that of the first embodiment described with reference to FIGS.
- the control unit 30 of the defect detection apparatus 30 uses the theoretical expressions (1b) to (5b) instead of the theoretical expressions (1) to (3) in steps S151 and S152 of FIG. Different from that.
- step S151 in FIG. 9 the control unit 35 fits the theoretical equation of the equation (1b) obtained from the heat conduction equation to the temperature curve 200 of the temperature change of the actually measured inspection object surface, and thereby the surface of the inspection object.
- the theoretical curve 201 showing the change with time of the temperature is obtained (see FIG. 4).
- step S152 the control unit 35 obtains the defect depth L of the inspection object from the value of the parameter b in the theoretical formula of the formula (1b) corresponding to the theoretical curve 201 using the formula (3b).
- the theoretical formula of Formula (1b) is fitted to the temperature curve obtained from the thermal image data measured during heating, and therefore, obtained in a relatively short heating time from the start of heating. Defect depth can be determined from thermal image data. Therefore, the heating time of the surface of the inspection object and the measurement time from the heating to the measurement of the defect depth can be shortened.
- the inspection object 100 in addition to the above-described expression (13b), in addition to the heat flux (h 2 T (0, s)) of heat transfer on the back surface 103 of the inspection object 100, the inspection object 100 The heat flux ( ⁇ (T 1 4 (0, s) ⁇ T 0 4 )) of heat radiation on the back surface 103 is taken into consideration (hat symbol omitted).
- T 0 is an initial temperature (temperature before heat radiation)
- T 1 (0, s) is a temperature after heat radiation (hat symbol omitted).
- Equation (13c) is similar to Equation (13b).
- h ′ 2 T (0, s) indicates the heat flux of heat transfer and heat radiation on the back surface 103 of the inspection object 100 (hat symbol omitted), and h ′ 2 indicates heat transfer of these heat transfer and heat radiation.
- the rate [W / (m 2 ⁇ K)] is shown.
- the heat conduction F 0 / s and the heat flux (h 1 T (L, s)) of heat transfer on the surface 102 of the inspection object 100 are obtained.
- the heat flux ( ⁇ (T 1 4 (L , s) -T 0 4)) of the thermal radiation at the surface 102 of the inspection object 100 is considered (circumflex omitted).
- T 1 (L, s) is the temperature after heat radiation (hat symbol omitted).
- the configurations of the defect detection device 30 and the defect detection system 1 of the present embodiment are basically the same as those of the first embodiment described with reference to FIG. 1, and the function of the control unit 30 of the defect detection device 30.
- the operation is basically the same as that of the first embodiment described with reference to FIGS.
- the control unit 30 of the defect detection apparatus 30 uses the theoretical expressions (1c) to (5c) in place of the theoretical expressions (1) to (3) in steps S151 and S152 of FIG. Different from that.
- step S151 in FIG. 9 the control unit 35 fits the theoretical equation of the equation (1c) obtained from the heat conduction equation to the temperature curve 200 of the actually measured temperature change of the object to be inspected, and thereby the surface of the object to be inspected.
- the theoretical curve 201 showing the change with time of the temperature is obtained (see FIG. 4).
- step S152 the control unit 35 obtains the defect depth L of the inspection object using the equation (3c) from the value of the parameter b in the theoretical equation of the equation (1c) corresponding to the theoretical curve 201.
- the theoretical formula of formula (1c) is fitted to the temperature curve obtained from the thermal image data measured during heating, and thus was acquired in a relatively short heating time from the start of heating. Defect depth can be determined from thermal image data. Therefore, the heating time of the surface of the inspection object and the measurement time from the heating to the measurement of the defect depth can be shortened.
- the theoretical formula of the equation (1c) that considers heat radiation is also used. Then, fitting to the actually measured temperature curve is performed to obtain a theoretical curve, and from the value of the parameter b in the theoretical formula corresponding to the theoretical curve, the defect depth of the inspection object obtained using the equation (3c) is obtained. . Thereby, even if the depth of the defect of the inspection object becomes deep, the defect depth L can be obtained with higher accuracy.
- Embodiments 1 to 3 have been described as examples of the technology disclosed in the present application.
- the technology in the present disclosure is not limited to this, and can also be applied to an embodiment in which changes, replacements, additions, omissions, and the like are appropriately performed.
- the method and apparatus for measuring the depth of defects inside the inspection object have been described.
- the idea of the present disclosure can be applied not only to the measurement of the depth of defects inside the inspection object but also to a method and apparatus for measuring the thickness of the measurement object.
- the distance from the surface of the inspection object to the internal defect (cavity, separation) is obtained as the depth of the defect.
- measuring the distance from the surface of the inspection object to the internal cavity or peeling is the same as measuring the thickness of the measurement object. Therefore, it is clear that the method for measuring the defect depth of the inspection object shown in the first to sixth embodiments can be applied to the method for measuring the thickness of the measurement object.
- the heating device 10 such as a halogen lamp
- heat reflection occurs on the back surface of the measurement object 100.
- the change depends on the thickness of the measurement object 100. From this, also in thickness measurement, if the surface of the measuring object 100 is imaged by the imaging device 20 such as an infrared camera while the surface of the inspection object 100 is heated by the heating device 10, the first embodiment will be described.
- the thickness can be determined in the same way as the defect detection method.
- “defect detection device”, “defect detection system”, “inspection object”, “defect depth”, “defect detection operation, defect depth measurement operation”, The “maximum measurement depth” may be read as “thickness measurement device”, “thickness measurement system”, “measurement object”, “thickness”, “thickness measurement operation”, and “maximum measurement thickness”, respectively.
- Example 1 Using the defect detection system 1 of Embodiment 1, the depth from the front surface to the back surface of the mortar plate (275 mm ⁇ 210 mm, thickness 11.1 mm) was measured as the defect depth.
- an earthquake-proof dimmable work lamp CTW-050 manufactured by CUSTOM KOBO was used.
- FIG. 14 (a) shows a temperature curve obtained from actually measured thermal image data and a theoretical curve obtained from the theoretical formula of the above equation (1).
- a broken line 210 is a temperature curve of a temperature change of the surface of the inspection object obtained from the actually measured thermal image data
- a solid line 211 is an inspection obtained by curve fitting the theoretical expression of the above equation (1) to the temperature curve 210. It is a theoretical curve of the temperature change of the target object surface.
- FIG. 14B shows the defect depth L of the inspection object obtained from the value of the parameter b in the theoretical formula corresponding to the theoretical curve 211 using the formula (3).
- a white triangle mark 411 is a measurement result of the depth L of the defect when the irradiation distance of the heating device 10 to the mortar plate is 30 cm
- a white square mark 412 has an irradiation distance of 40 cm.
- the black mark 413 is the measurement result of the defect depth L when the irradiation distance is 50 cm.
- FIG. 14B shows the measurement result of the defect depth L when the heating time is changed from 30 seconds to 300 seconds in increments of 30 seconds at each irradiation distance.
- the solid line 410 indicates the actual thickness of 11.1 mm.
- the defect depth L can be accurately obtained while reducing the measurement time by setting the heating time to about 60 seconds without depending on the irradiation distance, that is, the heating intensity.
- FIG. 14B shows a temperature curve 310 of the healthy part and a temperature curve 311 of the defective part obtained from the theoretical formula of the expression (1).
- Example 2 Using the defect detection system 1 of the first embodiment, the thickness of an aluminum plate (30 mm ⁇ 165 mm, thickness 15 mm) was measured.
- the heating device 10 the same one as in Example 1 was used.
- the irradiation distance of the heating device 10 to the aluminum plate was 30 cm, and the heating time was 60 seconds.
- FIG. 15A shows a temperature curve 220 obtained from the actually measured thermal image data and a theoretical curve obtained from the theoretical formula of the above formula (1).
- the broken line 220 is a temperature curve of the temperature change of the surface of the inspection object obtained from the measured thermal image data
- the solid line 221 is an inspection obtained by curve fitting the theoretical expression of the above equation (1) to the temperature curve 220. It is a theoretical curve of the temperature change of the target object surface.
- the thickness L can be accurately obtained while shortening the measurement time by setting the heating time to about 60 seconds. Recognize.
- Example 3 Using the defect detection system 1 of the fourth embodiment, the depth from the front surface to the back surface of three mortar plates (275 mm ⁇ 210 mm, thickness 11.1 mm, 22.1 mm, 30.5 mm) having different thicknesses is determined as the defect depth. As measured. As the heating device 10, the same one as in Example 1 was used.
- 18A to 18C show the temperature curve obtained from the thermal image data obtained by actually measuring the plate material of each thickness, and the theory of the formula (1a) in consideration of heat conduction and heat transfer (heat radiation) on the surface (heating surface) of the plate material.
- the theoretical curve obtained from the equation is shown.
- the broken line 230 is a temperature curve of the temperature change of the surface (heating surface) of the plate material obtained from the actually measured thermal image data, and the solid line 231 is obtained by curve fitting the theoretical expression of the above equation (1a) to the temperature curve 230. It is the theoretical curve of the temperature change of the surface (heating surface) of the calculated
- FIG. 19A shows the theoretical curve obtained by fitting the measured temperature curve using the formula (1a), and the value of the parameter b in the theoretical formula corresponding to the theoretical curve, using the formula (3). Defect depth L is shown.
- FIG. 19B uses the equation (1) that does not consider the heat transfer (heat radiation) on the surface (heating surface) of the plate material instead of the equation (1a), and similarly fits the measured temperature curve.
- the theoretical curve is obtained and the depth L of the defect of the plate material obtained using the equation (3) from the value of the parameter b in the theoretical formula corresponding to the theoretical curve is shown.
- a black circle mark 431 is a measurement result of a defect depth L of a plate material having a thickness (defect depth) of 11.1 mm
- a black triangle mark 432 is a thickness (defect depth) 22.
- This is a measurement result of a defect depth L of a plate material of 1 mm
- a black square mark 433 is a measurement result of a defect depth L of a plate material having a thickness (defect depth) of 30.5 mm.
- the solid lines 431r, 432r, and 433r indicate actual thicknesses of 11.1 mm, 22.1 mm, and 30.5 mm, respectively.
- the value of the measurement result increases as the heating time becomes longer as a whole.
- the measurement result (431) of the defect depth L of the plate material having a thickness of 11.1 mm it is saturated to a value close to 11.1 mm in the vicinity of the heating time of 200 s (asymptotic to the solid line 431r indicating 11.1 mm). , Become flat characteristics). From this, the depth L of the defect can be obtained from the value of the heating time zone that is saturated in the measurement result (431).
- the measurement result (431) of the defect depth L of the plate material having a thickness of 11.1 mm is saturated to a value close to 11.1 mm in the vicinity of the heating time of 200 s to 300 s. (It becomes asymptotic to a solid line 431r indicating 11.1 mm and has a flat characteristic). Also, the measurement result (432) of the defect depth L of the plate material having a thickness of 22.1 mm is saturated to a value close to 22.1 mm in the vicinity of the heating time of 300 s to 500 s (in the solid line 432r indicating 22.1 mm). Asymptotic and flat characteristics).
- the measurement result (433) of the defect depth L of the plate material having a thickness of 30.5 mm is saturated to a value close to 30.5 mm in the vicinity of the heating time of 400 s to 600 s (indicated by a solid line 433r indicating 30.5 mm). Asymptotic and flat characteristics). As a result, even when the depth of the defect is deeper than 22.1 mm, the depth L of the defect can be obtained from the saturated heating time zone value in the measurement result, and the depth of the defect can be determined with high accuracy. It can be measured.
- Example 4 Using the defect detection system 1 of the fifth embodiment, the depth from the front surface to the back surface of three mortar plates (275 mm ⁇ 210 mm, thickness 11.1 mm, 22.1 mm, 30.5 mm) having different thicknesses is determined as the defect depth. As measured. As the heating device 10, the same one as in Example 1 was used.
- FIGS. 20A to 20c show temperature curves obtained from thermal image data obtained by actually measuring plate materials of various thicknesses, heat conduction, heat transfer (heat radiation) on the surface (heating surface) and back surface (defect side) of the plate material, and heat.
- a theoretical curve obtained from the theoretical formula (1c) in consideration of radiation is shown.
- a broken line 240 is a temperature curve of a temperature change of the surface (heated surface) of the plate material obtained from actually measured thermal image data, and a solid line 241 is obtained by curve fitting the theoretical expression of the equation (1c) to the temperature curve 240. It is a theoretical curve of the temperature change of the surface (heated surface) of the plate material.
- FIG. 21 shows the theoretical curve obtained by fitting the measured temperature curve using the formula (1c), and the value of the parameter b in the theoretical formula corresponding to the theoretical curve, using the formula (3).
- Defect depth L is shown.
- a black circle mark 441 is a measurement result of a defect depth L of a plate material having a thickness (defect depth) of 11.1 mm
- a black triangle mark 442 is a thickness (defect depth) of 22.1 mm.
- This is a measurement result of the defect depth L of the plate material
- a black square mark 443 is a measurement result of the defect depth L of the plate material having a thickness (defect depth) of 30.5 mm.
- the solid lines 441r, 442r, and 443r indicate actual thicknesses of 11.1 mm, 22.1 mm, and 30.5 mm, respectively.
- the whole in the measurement result (441) of the defect depth L of the plate material having a thickness of 11.1 mm, the whole is saturated to a value close to 11.1 mm regardless of the heating time (11. It becomes asymptotic to a solid line 441r indicating 1 mm, and has a flat characteristic).
- the measurement result (442) of the defect depth L of the plate material having a thickness of 22.1 mm it is saturated to a value close to 22.1 mm after a heating time of 400 s or more (asymptotic to the solid line 442r indicating 22.1 mm). , Become flat characteristics).
- the defect depth L of the plate material having a thickness of 30.5 mm is saturated to a value close to 30.5 mm after a heating time of 600 s or more (asymptotic to a solid line 433r indicating 30.5 mm). , Become flat characteristics).
- the depth L of the defect can be obtained from the saturated heating time zone value in the measurement result, and the depth of the defect can be determined with high accuracy. It can be measured.
- the defect depth exceeding about 15 mm indicates that the heat conduction and the inspection object do not take into account heat transfer (heat radiation) and heat radiation on the back surface (defect side) of the inspection object. It can be seen that the depth of the defect can be measured with relatively high accuracy by using the theoretical formula of the formula (1a) in consideration of heat transfer (heat radiation) on the surface (heating surface).
- the present disclosure can be applied to a thickness measurement method, a thickness measurement apparatus, and a thickness measurement system that measure the thickness of a measurement object. Further, the present disclosure is applicable to a defect detection method, a defect detection apparatus, and a defect detection system that measure the depth of a defect such as an internal peeling or a cavity of an inspection object.
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Abstract
Description
以下、実施の形態1の欠陥検出システムを図1~図9を用いて説明する。
[1-1-1.欠陥検出システム]
図1は、実施の形態1にかかる欠陥検出システム1の構成を示す図である。図1に示すように、欠陥検出システム1は、検査対象物の内部にある剥離又は空洞等の欠陥の深さを計測して、欠陥検出を行う。欠陥検出システム1は、ハロゲンランプ10と、ランプ駆動部11と、赤外線カメラ20と、欠陥検出装置30とを備える。
欠陥検出装置30は、例えばコンピュータで構成される。欠陥検出装置30は、図1に示すように、第1~第3の通信部31、32、33と、格納部34と、制御部35と、表示部36と、操作部37とを備える。
以上のように構成された欠陥検出システム1及び欠陥検出装置30について、その動作を以下に説明する。
まず、本開示の欠陥検出の概要について、図2~5を参照して説明する。
図2を参照し、検査対象物100の表面をハロゲンランプ等の加熱装置で加熱すると、検査対象物100の表面(高温側)から内部(低温側)に向けて熱伝導が生じる。その際、検査対象物100の内部に剥離又は空洞等の欠陥101があると、熱伝導が欠陥101によって妨げられ、熱反射が生じる。これにより、欠陥101が内部に存在する欠陥部110の表面温度は、欠陥が内部に存在しない健全部120の表面温度よりも高くなる。この表面の温度差を利用して欠陥検出を行う方法が知られている。
本開示の欠陥検出方法は、検査対象物100の表面を加熱装置10で加熱している間に、検査対象物100の表面温度を赤外線カメラ等の撮影装置20で撮影して、検査対象物100の表面温度に応じた熱画像データを生成する。そして、本開示の欠陥検出方法は、この熱画像データと、熱伝導方程式から得られる理論式(後述の式(1))とを用いて欠陥検出を行う。
以下、本実施の形態1にかかる欠陥検出装置30の制御部35による欠陥検出動作について、図6のフローチャートを参照して説明する。
以上のように、本実施の形態において、欠陥検出方法は、検査対象物の内部の欠陥の深さを計測する欠陥検出方法である。この欠陥検出方法は、ハロゲンランプ(加熱装置)10により検査対象物の表面を加熱するステップと、赤外線カメラ(撮影装置)20により最大加熱時間間隔(所定時間間隔)Tmにおいて、加熱された検査対象物の表面を撮影して検査対象物の表面の温度に応じた熱画像データを生成するステップと、熱画像データに基づいて、検査対象物の表面の温度の経時変化を示す温度曲線200を求めるステップと、検査対象物の欠陥の深さLに関連したパラメータa、bを含む熱伝導方程式から得られる理論式(上式(1))を温度曲線200にフィッティングして、計測対象物の表面の温度の経時変化を示す理論曲線201を求めるステップと、理論曲線201に対応する熱伝導方程式に含まれるパラメータbの値に基づいて、検査対象物の欠陥の深さを求めるステップとを備える。
実施の形態1では、最大加熱時間Tmの間に取得した全ての熱画像データを用いて、最大計測深さLmにおける欠陥深さの計測を1回だけ行った。本実施の形態では、最大加熱時間Tmの間に段階的に取得した一部の熱画像データを用いて、段階的に計測する深さを変化させながら、欠陥深さ計測を行う。
実施の形態2では、最大加熱時間Tmにわたって全ての熱画像データを取得した後に、段階的に欠陥深さ計測を行った。これに対して、本実施の形態では、熱画像データの取得中に、段階的に欠陥深さ計測を行う。
実施の形態1では、実測した検査対象物表面の温度変化の温度曲線にフィッティングを行う理論式として、熱伝導方程式から得られる式(1)の理論式を用いた。本実施の形態では、式(1)に代えて次式(1a)の理論式を用いる。以下、式中においてハット記号「^」を付した関数は、ハット無しの関数を時間tについてラプラス変換した関数であることを示す。
まず、式(1a)の理論式との比較のために、式(1)の時間関数の理論式をs関数の理論式(下式(1s))で表現し直す。図17Aは、熱伝導を説明するための模式図である。図17Aに示すように、検査対象物100の表面102に一定の熱流束F0(図7参照)を与えると、検査対象物100の内部において表面102から欠陥101側の裏面103へ熱が移動する熱伝導が生じる。図17Aにおいて、検査対象物100の表面102から裏面103までの欠陥101の深さをLとする。また、裏面103の位置xを0とし、表面102の位置xをLとする。
次に、熱伝導方程式から得られる温度変化の理論式であって、検査対象物の表面(加熱面)における熱伝達(放熱)を考慮した温度変化の理論式の導出について説明する。図17B及び図17Cは、熱伝達を説明するための模式図である。図17Bに示すように、検査対象物100の表面102から、表面102に接する空気へ熱流束h1T(L,s)で熱が移動する熱伝達が生じる(ハット記号省略)。また、図17Cに示すように、検査対象物100の裏面103から、裏面103に接する空気へ熱流束h2T(L,s)で熱が移動する熱伝達が生じる(ハット記号省略)。h1、h2は熱伝達率(熱伝達係数)[W/(m2・K)]である。なお、本実施の形態では、図17Bに示すように、検査対象物100の表面102における熱伝達のみを考慮した温度変化の理論式を導出する。
また、上述の式(12)において、図17Aにおける検査対象物100の表面102の位置x=Lの境界条件として次式(14a)が導出される。
式(12)、(13a)及び(14a)よりC1、C2を求め、上述の式(11)に代入することにより、ステップ応答における理論式(s関数)として次式(15a)が導出される。
実施の形態4では、実測した検査対象物表面の温度変化の温度曲線にフィッティングを行う理論式として、熱伝導、及び検査対象物の表面(加熱面)における熱伝達(放熱)も考慮した式(1a)の理論式を用いた。本実施の形態では、式(1a)に代えて、検査対象物の裏面(欠陥側)における熱伝達(放熱)も考慮した次式(1b)の理論式を用いる。
また、上述の式(12)において、図17Cにおける検査対象物100の表面102の位置x=Lの境界条件として次式(14b)が導出される。
式(12)、(13b)及び(14b)よりC1、C2を求め、上述の式(11)に代入することにより、ステップ応答における理論式(s関数)として次式(15b)が導出される。
実施の形態5では、実測した検査対象物表面の温度変化の温度曲線にフィッティングを行う理論式として、熱伝導、及び検査対象物の表面(加熱面)及び裏面(欠陥側)における熱伝達(放熱)も考慮した式(1b)の理論式を用いた。本実施の形態では、式(1b)に代えて、熱輻射も考慮した次式(1c)の理論式を用いる。
ここで、(-h2T(0,s)-δ(T1 4(0,s)-T0 4))を(-h’2T(0,s))とすると(ハット記号省略)、式(13c)は式(13b)と同様となる。h’2T(0,s)は、検査対象物100の裏面103における熱伝達及び熱輻射の熱流束を示し(ハット記号省略)、h’2は、これらの熱伝達及び熱輻射の熱伝達率[W/(m2・K)]を示す。
ここで、(h1T(L,s)+δ(T1 4(L,s)-T0 4))を(h’1T(L,s))とすると(ハット記号省略)、式(14c)は式(13b)と同様となる。h’1T(L,s)は、検査対象物100の表面102における熱伝達及び熱輻射のトータルの熱流束を示し(ハット記号省略)、h’1は、これらの熱伝達及び熱輻射の熱伝達率[W/(m2・K)]を示す。
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、実施の形態1~3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の形態にも適用可能である。また、上記実施の形態1~3で説明した各構成要素を組み合わせて、新たな実施の形態とすることも可能である。そこで、以下、他の実施の形態を例示する。
実施の形態1の欠陥検出システム1を用いて、モルタル板材(275mm×210mm、厚み11.1mm)の表面から裏面までの深さを欠陥深さとして計測した。加熱装置10としては、耐震型調光式ワークランプCTW-050(CUSTOM KOBO製)を使用した。
実施の形態1の欠陥検出システム1を用いて、アルミニウム板材(30mm×165mm、厚み15mm)の厚みを計測した。加熱装置10としては、実施例1と同一のものを使用した。アルミニウム板材に対する加熱装置10の照射距離を30cmとし、加熱時間を60秒とした。
実施の形態4の欠陥検出システム1を用いて、厚みが異なる3つのモルタル板材(275mm×210mm、厚み11.1mm、22.1mm、30.5mm)の表面から裏面までの深さを欠陥深さとして計測した。加熱装置10としては、実施例1と同一のものを使用した。
実施の形態5の欠陥検出システム1を用いて、厚みが異なる3つのモルタル板材(275mm×210mm、厚み11.1mm、22.1mm、30.5mm)の表面から裏面までの深さを欠陥深さとして計測した。加熱装置10としては、実施例1と同一のものを使用した。
実施例1及び2の結果より、約15mm以下の欠陥深さであれば、熱伝導のみを考慮した式(1)~(3)を用いても、欠陥の深さを比較的に精度よく計測することができることがわかる。また、実施例4の結果より、約15mmを超える欠陥深さは、熱伝導に加えて、検査対象物の表面(加熱面)及び裏面(欠陥側)における熱伝達(放熱)、及び熱輻射を考慮した式(1c)の理論式を用いることにより、欠陥の深さを精度よく計測することができることがわかる。しかし、実施例3の結果より、約15mmを超える欠陥深さは、検査対象物の裏面(欠陥側)における熱伝達(放熱)、及び熱輻射まで考慮せずとも、熱伝導と、検査対象物の表面(加熱面)における熱伝達(放熱)を考慮した式(1a)の理論式を用いることにより、欠陥の深さを比較的に精度よく計測することができることがわかる。
Claims (12)
- 計測対象物の厚みを計測する厚み計測方法であって、
加熱装置により前記計測対象物の表面を加熱するステップと、
撮影装置により所定時間間隔において、加熱された前記計測対象物の表面を撮影して前記計測対象物の表面の温度に応じた熱画像データを生成するステップと、
前記撮影装置により生成された熱画像データに基づいて、前記計測対象物の表面の温度の経時変化を示す温度曲線を求めるステップと、
前記計測対象物の厚みに関連したパラメータを含む熱伝導方程式から得られる理論式を前記温度曲線にフィッティングして、前記計測対象物の表面の温度の経時変化を示す理論曲線を求めるステップと、
前記理論曲線に対応する前記理論式に含まれる前記パラメータの値に基づいて、前記計測対象物の厚みを求めるステップと、
を備える厚み計測方法。 - 前記加熱装置による前記計測対象物の表面の加熱を、ステップ状に開始し、
前記計測対象物の加熱開始と同時に、前記撮影装置により、前記計測対象物の表面の撮影を開始して、前記熱画像データの生成を開始する、
請求項1に記載の厚み計測方法。 - 前記理論式は、ステップ応答に基づく式である、
請求項1又は2に記載の厚み計測方法。 - 前記理論式は、少なくとも2つの独立したパラメータを含む、
請求項3に記載の厚み計測方法。 - 前記理論曲線は、非線形最小二乗法を用いて残差が最小となるようにフィッティングを行うことにより求められる、
請求項1~5の何れか1項に記載の厚み計測方法。 - 前記理論式は、前記計測対象物の表面から、当該表面に接する流体に熱が移動する熱伝達に関する熱伝達係数を含む、
請求項1~3の何れか1項に記載の厚み計測方法。 - 計測対象物の厚みを計測する厚み計測装置であって、
所定時間間隔において、加熱された前記計測対象物の表面を撮影して生成された熱画像データを入力する入力部と、
前記熱画像データに基づいて、前記計測対象物の表面の温度の経時変化を示す温度曲線を求める第1演算部と、
前記計測対象物の厚みに関連したパラメータを含む熱伝導方程式から得られる理論式を前記温度曲線にフィッティングして、前記計測対象物の表面の温度の経時変化を示す理論曲線を求めるフィッティング部と、
前記理論曲線に対応する前記理論式に含まれる前記パラメータの値に基づいて、前記計測対象物の厚みを求める第2演算部と、
を備える厚み計測装置。 - 計測対象物の厚みを計測する厚み計測システムであって、
前記計測対象物の表面を加熱する加熱装置と、
加熱された前記計測対象物の表面を撮影して前記計測対象物の表面の温度に応じた熱画像データを生成する撮影装置と、
前記熱画像データに基づいて前記計測対象物の厚みを計測する請求項7に記載の厚み計測装置と、
を備える厚み計測システム。 - 検査対象物の内部の欠陥の深さを計測する欠陥検出方法であって、
加熱装置により前記検査対象物の表面を加熱するステップと、
撮影装置により所定時間間隔において、加熱された前記検査対象物の表面を撮影して前記検査対象物の表面の温度に応じた熱画像データを生成するステップと、
前記熱画像データに基づいて、前記検査対象物の表面の温度の経時変化を示す温度曲線を求めるステップと、
前記検査対象物の欠陥の深さに関連したパラメータを含む熱伝導方程式から得られる理論式を前記温度曲線にフィッティングして、前記計測対象物の表面の温度の経時変化を示す理論曲線を求めるステップと、
前記理論曲線に対応する前記理論式に含まれる前記パラメータの値に基づいて、前記検査対象物の欠陥の深さを求めるステップと、
を備える欠陥検出方法。 - 検査対象物の内部の欠陥の深さを計測する欠陥検出装置であって、
所定時間間隔において、加熱された前記検査対象物の表面を撮影して生成された熱画像データを入力する入力部と、
前記熱画像データに基づいて、前記計測対象物の表面の温度の経時変化を示す温度曲線を求める第1演算部と、
前記検査対象物の欠陥の深さに関連したパラメータを含む熱伝導方程式から得られる理論式を前記温度曲線にフィッティングして、前記計測対象物の表面の温度の経時変化を示す理論曲線を求めるフィッティング部と、
前記理論曲線に対応する前記理論式に含まれる前記パラメータの値に基づいて、前記検査対象物の欠陥の深さを求める第2演算部と、
を備える欠陥検出装置。 - 検査対象物の内部の欠陥の深さを計測する欠陥検出システムであって、
前記検査対象物の表面を加熱する加熱装置と、
加熱された前記検査対象物の表面を撮影して前記検査対象物の表面の温度に応じた熱画像データを生成する撮影装置と、
前記熱画像データに基づいて前記検査対象物の内部の欠陥の深さを計測する請求項10に記載の欠陥検出装置と、
を備える欠陥検出システム。
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Cited By (3)
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---|---|---|---|---|
JP6506886B1 (ja) * | 2017-12-07 | 2019-04-24 | 三菱電機株式会社 | 表示データ生成装置および表示データ生成方法 |
WO2020162121A1 (ja) | 2019-02-06 | 2020-08-13 | パナソニックIpマネジメント株式会社 | 厚み計測方法及び厚み計測装置、並びに欠陥検出方法及び欠陥検出装置 |
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Citations (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPH0566209A (ja) * | 1991-09-09 | 1993-03-19 | Nitto Chem Ind Co Ltd | 構造物の表面または内部欠陥の検知方法 |
US20070041422A1 (en) * | 2005-08-01 | 2007-02-22 | Thermal Wave Imaging, Inc. | Automated binary processing of thermographic sequence data |
Family Cites Families (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US6542849B2 (en) * | 2001-01-19 | 2003-04-01 | The University Of Chicago | Method for determining defect depth using thermal imaging |
US7220966B2 (en) * | 2003-07-29 | 2007-05-22 | Toyota Motor Manufacturing North America, Inc. | Systems and methods for inspecting coatings, surfaces and interfaces |
JP2011122859A (ja) | 2009-12-08 | 2011-06-23 | Kyoto Institute Of Technology | 欠陥診断方法および欠陥診断システム |
CN102221339B (zh) * | 2011-06-09 | 2012-09-05 | 首都师范大学 | 脉冲红外热波技术测厚方法 |
JP2014032160A (ja) | 2012-08-06 | 2014-02-20 | Japan Aerospace Exploration Agency | 探傷方法及び探傷装置 |
-
2016
- 2016-10-27 EP EP16887840.3A patent/EP3410106B1/en active Active
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Patent Citations (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPH0566209A (ja) * | 1991-09-09 | 1993-03-19 | Nitto Chem Ind Co Ltd | 構造物の表面または内部欠陥の検知方法 |
US20070041422A1 (en) * | 2005-08-01 | 2007-02-22 | Thermal Wave Imaging, Inc. | Automated binary processing of thermographic sequence data |
Non-Patent Citations (1)
Title |
---|
See also references of EP3410106A4 * |
Cited By (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP6506886B1 (ja) * | 2017-12-07 | 2019-04-24 | 三菱電機株式会社 | 表示データ生成装置および表示データ生成方法 |
WO2020162121A1 (ja) | 2019-02-06 | 2020-08-13 | パナソニックIpマネジメント株式会社 | 厚み計測方法及び厚み計測装置、並びに欠陥検出方法及び欠陥検出装置 |
CN113412424A (zh) * | 2019-02-06 | 2021-09-17 | 松下知识产权经营株式会社 | 厚度测量方法、厚度测量装置、缺陷检测方法以及缺陷检测装置 |
JPWO2020162121A1 (ja) * | 2019-02-06 | 2021-11-25 | パナソニックIpマネジメント株式会社 | 厚み計測方法及び厚み計測装置、並びに欠陥検出方法及び欠陥検出装置 |
JP7209270B2 (ja) | 2019-02-06 | 2023-01-20 | パナソニックIpマネジメント株式会社 | 厚み計測方法及び厚み計測装置、並びに欠陥検出方法及び欠陥検出装置 |
US11965735B2 (en) | 2019-02-06 | 2024-04-23 | Panasonic Intellectual Property Management Co., Ltd. | Thickness measurement method, thickness measurement device, defect detection method, and defect detection device |
RU2806259C1 (ru) * | 2020-10-16 | 2023-10-30 | Арселормиттал | Способ оценки температуры и толщины оксида полосовой стали |
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US11054252B2 (en) | 2021-07-06 |
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