JP2019105523A - Sound shielding board inspection method and sound shielding board inspection apparatus - Google Patents

Abstract

To provide a sound shielding board inspection method capable of grasping a state of deterioration without removing a sound shielding board.SOLUTION: The sound shielding board inspection method irradiates a light shielding board 10 with light 111 including a wavelength range of infrared rays, photographs the sound shielding board 10 irradiated with the light by a camera 120 for detecting the wavelength range of infrared rays, and senses reflected light 121. Further, a distance to the sound shielding board 10 may be measured so that deterioration can be determined based on the intensity of the infrared rays sensed by the camera 120 and the measured distance.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a sound insulation board inspection method and a sound insulation board inspection apparatus.

  As a sound insulation board of a road, the sound insulation board which consists of translucent resin, for example is used. In general, resin products are deteriorated by ultraviolet light and the like, and therefore need to be replaced when the deterioration progresses. Since the state of deterioration of the sound insulation board varies depending on the installed environment, in order to grasp the replacement time of the sound insulation board, it is necessary to remove the sound insulation board from the site along the road and conduct a spectral analysis and strength test.

  Patent document 1 performs the accelerated deterioration test which irradiates an ultraviolet-ray from a super accelerated weathering machine to the polycarbonate board which shows the yellowing degree proportional to the irradiation amount of ultraviolet rays, and irradiates the ultraviolet-ray to the said polycarbonate board and the said polycarbonate The yellowing degree of the same polycarbonate plate as that used in the accelerated deterioration test which is obtained by acquiring the correlation of the yellowing degree of the board and arranged for a long time in a plurality of specific places of the outdoor structure based on the acquired correlation From the above, a simple method for measuring the amount of ultraviolet light is disclosed, which measures the amount of ultraviolet light for a long period of time at the specific place.

JP, 2009-250699, A

  As mentioned above, in order to inspect the situation of deterioration of the sound insulation board, when removing the sound insulation board arranged along the road, it is necessary to control the traffic of the road, so the social economic activity is affected. It was great.

  The present invention has been made in view of the above-mentioned circumstances, and an object thereof is to provide a sound insulation board inspection method and a sound insulation board inspection apparatus capable of grasping the state of deterioration without removing the sound insulation board.

  In the sound insulation board inspection method according to one aspect of the present disclosure, the light insulation board (10) is irradiated with light including a wavelength range of infrared light, and the light is irradiated by the camera (120) that senses the wavelength area of infrared light The sound insulation board inspection method for photographing the sound insulation board to be

  With the above-described configuration, in the sound insulation board inspection method, the state of deterioration can be grasped without removing the sound insulation board.

It is a figure shown about a sound insulation board inspection device concerning one embodiment of this indication. It is a flowchart explaining the sound-insulation board test | inspection process in the sound-insulation board test | inspection apparatus of FIG. It is a figure shown about a sound insulation board inspection device concerning other embodiments of this indication. It is a figure shown about an example at the time of applying slit-like irradiation light to three different places to a sound insulation board. It is a flowchart explaining the sound-insulation board test | inspection process in the sound-insulation board test | inspection apparatus of FIG. It is a graph shown about the example of a test result.

  Hereinafter, the configuration and function of the sound insulation board inspection apparatus 100 of the present invention will be described with reference to the drawings. The present invention means the invention described in the claims or in the section of means for solving the problems, and is not limited to the following embodiments. Further, configurations and methods described in the dependent claims of the claims, configurations and methods of embodiments corresponding to the configurations and methods described in the dependent claims, and configurations and methods described only in the embodiments without description in the claims. The method is any configuration and method in the present invention. The problem described in the problem to be solved by the invention is not a known problem, but is the fact found by the inventor uniquely, and affirming the inventive step of the invention together with the means of the present invention.

  FIG. 1 is a view showing a sound insulation board inspection apparatus 100 according to an embodiment of the present disclosure. As shown in this figure, the sound insulation board inspection apparatus 100 has a light source 110 and a camera 120. The light source 110 irradiates the sound insulation plate 10 with light including a wavelength range of infrared light. The camera 120 senses the infrared wavelength region and captures an image of the sound insulation board 10 to which light is emitted. Here, the light emitted by the light source may include some infrared wavelength regions, and may further include visible light and ultraviolet wavelength regions. The light emitted by the light source may include only the infrared region, not including the visible light region. In this case, even in the nighttime examination, the examination can be performed without emitting bright visible light which causes inconvenience to surrounding houses and the like. Also, the camera may be able to sense some infrared wavelength regions, and may also sense visible light or ultraviolet wavelength regions. The camera is preferably one capable of measuring the light intensity according to the frequency in the infrared region.

  In the figure, the light emitted from the light source 110 to the sound insulation board 10 is the irradiation light 111, and the light from the sound insulation board 10 photographed by the camera 120 is the reflected light 121. In this figure, the side surface of the sound insulation board 10 is drawn, and the sound insulation board 10 extends in the direction perpendicular to the paper surface and is assumed to be rectangular in a front view. The sound insulation board 10 can be made of transparent resin. The sound insulation board 10 is made of, for example, polycarbonate or acrylic, and deterioration of transparency due to deterioration causes the transmitted light to decrease and the reflected light 121 to increase. Therefore, the deterioration due to the change of the reflected light 121 should be measured. Can. However, the sound insulation board inspection apparatus 100 may be used for the inspection of the sound insulation board 10 of another material that causes a change in the reflected light 121 due to deterioration.

  FIG. 2 is a flow chart for explaining a sound insulation board inspection process S10 as a sound insulation board inspection method using the sound insulation board inspection apparatus 100 of FIG. As shown in the flowchart, in the sound insulation plate inspection process S10, first, the light source 110 irradiates the sound insulation plate 10 with light including an infrared wavelength region in step S11. Subsequently, in step S12, the camera 120, which senses the infrared wavelength region, captures an image of the sound blocking plate 10 to which light is emitted. Finally, in step S13, a determination on deterioration is made based on the captured information. If the output from the camera 120 is an image showing the intensity of light, it may be determined using that image, or if it is a value showing the intensity of light according to the frequency, a graph etc. It is good also as using and judging. By performing such processing, the state of deterioration can be grasped without removing the sound insulation board 10.

  FIG. 3 is a view showing a sound insulation board inspection apparatus 100 according to another embodiment of the present disclosure. As shown in this figure, the sound insulation board inspection apparatus 100 includes a light source 110, a camera 120, a distance meter 130, an information processing unit 140, a position acquisition unit 150, and a vehicle 160. Here, the light source 110, the camera 120, and the sound insulation plate 10 are the same as the configuration of FIG.

  The information processing unit 140 includes a determination unit 145 as one of the functions. The determination unit 145 determines the deterioration of the sound insulation board 10 based on the intensity of the infrared light sensed by the camera 120. Here, the hardware configuration of the information processing unit 140 mainly includes, for example, a semiconductor device, and a volatile storage unit such as a central processing unit (CPU) or a random access memory (RAM), and a nonvolatile memory such as a hard disk or a flash memory. It can be a so-called computer device having a storage unit, a network interface connected to a communication network, and the like.

  The distance meter 130 measures the distance to the sound insulation board 10. The distance meter 130 can use a distance meter using a laser, an ultrasonic wave, or the like. The position acquisition unit 150 acquires position information of the photographed position. The position acquisition unit 150 can acquire, for example, a position obtained by positioning using a GPS (Global Positioning System) or other satellite positioning system.

  The vehicle 160 mounts at least the light source 110 and the camera 120. In this case, the irradiation of the irradiation light 111 by the light source 110 and the photographing by the camera 120 can be performed while the vehicle 160 is traveling. By performing irradiation and photographing while traveling in this manner, the efficiency of the inspection can be enhanced and the inspection can be performed without traffic regulation. Here, the traveling speed of the vehicle 160 conforms to the traffic rules of the road on which it is traveling, and is preferably 40 km / h or 60 km / h, for example, 80 km / h if the road can travel at high speed.

  Here, the irradiation light 111 irradiated by the light source 110 can be a rectangular slit-like light extending in the vertical direction. FIG. 4 shows an example of the case where the slit-shaped irradiation light 111 is applied to the noise isolation plate 10 at three different places. Since deterioration of the sound insulation board 10 generally progresses with the whole sound insulation board 10, it can be determined about degradation by testing about the reflected light 121 reflected in a part of sound insulation board 10. FIG. Therefore, for example, processing for judging by acquiring and judging data of a plurality of places from one place with a slit-shaped irradiation light 111 extending in the height direction per one sound insulation board 10 having a width of about 2 m to 4 m. Resources can be saved and processed at high speed, and degradation states can be provided more efficiently. Although the irradiation light 111 can be irradiated to arbitrary numbers of places, about three places are preferable. The slit-like irradiation light 111 can be formed, for example, by expanding a point light source 110 such as a laser light in a sheet shape in the vertical direction with a cylindrical lens or the like. The slit-like irradiation light 111 can be, for example, about 2 m in height and about 2 cm in width. In addition, the plurality of slit-like irradiation lights 111 may be sequentially irradiated. For example, while the vehicle 160 is traveling as described above, by irradiating and photographing the slit-like irradiation light 111 while flickering, it is possible to inspect a plurality of places on one sound insulation board 10. Thereby, the sound insulation board test | inspection apparatus 100 can provide the state of degradation more efficiently. The determination unit 145 can perform determination by removing an error or noise from the information of the plurality of slit-shaped reflected lights 121 captured by the camera 120 by, for example, statistical processing.

  FIG. 5 is a flow chart for explaining a sound insulation board inspection process S20 as a sound insulation board inspection method using the sound insulation board inspection apparatus 100 of FIG. 3. As shown in this flowchart, first, in step S21, for example, the traveling of the vehicle 160 on the road on which the sound insulation board 10 for performing measurement is disposed is started. By setting the traveling speed to, for example, a speed determined on the road on which the vehicle travels and a speed that does not interfere with the flow of another vehicle, inspection can be performed without traffic restriction or the like. Here, the inspection may be performed at night when there is no influence of sunlight. By performing the inspection at night, the sound insulation board inspection apparatus 100 can perform highly accurate determination without the influence of sunlight.

  Next, in step S22, the position acquisition unit 150 acquires position information of the photographed position. The acquired position information may be stored in the information processing unit 140. In step S23, the distance meter 130 measures the distance to the sound insulation board 10. The measured distance may be stored in the information processing unit 140. In step S24, the light source 110 irradiates the sound insulation plate 10 with light including an infrared wavelength range. Here, the light source 110 may control the intensity of light to be emitted based on the distance measured by the distance meter 130. As a result, even if the intensity of the reflected light 121 is changed due to the distance to the sound shielding plate 10, the light emitted from the light source 110 is such that there is no change in the intensity of the light irradiated to the sound shielding plate 10. Because the strength can be controlled, a more accurate state of degradation can be provided.

  In step S25, the camera 120, which senses the infrared wavelength region, captures an image of the sound blocking board 10 to which light is emitted. The photographed data may be stored in the non-volatile storage unit of the information processing unit 140. In step S <b> 26, the determination unit 145 performs a determination process of determining the deterioration of the sound insulation board 10 based on the intensity of the infrared rays detected by the camera 120. For example, determination processing is performed based on the intensity of infrared light at a specific wavelength, the sum or average value of the intensities of infrared light at a plurality of specific wavelengths, and the integral value of the intensity of infrared light between specific wavelengths.

  In the determination process, the determination unit 145 may classify the captured information into, for example, three or five stages of deterioration based on a predetermined reference or the like. Thereby, the determination unit 145 can output the state of deterioration more easily. Alternatively, the determination unit 145 may make the determination based on a waveform indicating the intensity of infrared light in the infrared wavelength region. Thereby, the determination unit 145 can more accurately output the state of deterioration based on the predetermined reference waveform.

  Further, the determination unit 145 can make the determination based on the difference in the intensity of infrared light in the predetermined wavelength region. Thus, when the predetermined reference or the like is, for example, due to the unevenness of the waveform in the predetermined wavelength region, the determination unit 145 may output a more accurate state of deterioration based on the difference in intensity. Can. Also, the determination is based on the captured information and the feature amount extracted by mathematical processing such as statistical processing using the degree of deterioration, and based on machine learning such as SVM (Support Vector Machine) and deep learning. It can be judged.

  Further, the determination unit 145 may determine the deterioration based on the intensity of the infrared light and the distance measured by the distance meter 130. As a result, even if the intensity of the reflected light 121 changes due to the distance to the sound shielding plate 10, the determination unit 145 can correct the intensity of the reflected light 121 based on the distance, so that it is more accurate. The state of degradation can be provided.

  In addition, the determination unit 145 may associate the position information acquired by the position acquisition unit 150 with the determination result. Thereby, the state of deterioration of the reflecting plate 10 installed in a predetermined place can be grasped | ascertained. Further, the sound insulation board inspection apparatus 100 can easily indicate at which position the reflecting plate 10 or the like which is determined to be particularly required to be replaced.

  In step S27, it is determined whether the inspection of the sound insulation board 10 is to be continued, and if it is to be continued, the process returns to step S22 to continue the process. When not continuing, the inspection of the sound insulation board 10 is complete | finished. By performing the above-described sound insulation board inspection, it is possible to grasp the state of deterioration without removing the sound insulation board 10. The determination result can be displayed on the screen of a display device (not shown). In this case, it may be displayed together with position information of the measured position.

  FIG. 6 is a graph showing an example of the inspection result. In the graph, the horizontal axis represents wavelength (nm) and the vertical axis represents relative reflectance (%). As the light source 110, a halogen lamp was used, and as the camera 120, an imaging system including a hyperspectral camera capable of spectral analysis in a wavelength region of 900 to 1700 nm was used. The samples are transparent plates each made of polycarbonate, and the deterioration changes in the order of sample 1, sample 2 and sample 3, and sample 3 is the sound insulation plate 10 with the most deterioration.

  As shown in this graph, as the deterioration progresses, the relative reflectance, which is the ratio of the intensity of the irradiated light to the reflected light, increases, and it can be seen that the transmitted light decreases and the reflected light 121 increases. Therefore, deterioration of the polycarbonate plate can be determined by determining the relative reflectance. In the waveform of relative reflectance near the wavelength region of 1100 to 1200 nm, while the waveform of the shallow concave portion is observed in the sample 1 with little deterioration, the waveform having the deeper concave portion is observed in the sample 3 of which the deterioration is advanced Ru. The determination unit 145 may determine the deterioration based on the depth of the concave portion of the waveform, that is, the difference in the intensity of the reflected light 121.

  The sound insulation board inspection apparatus and the sound insulation board inspection method according to the embodiment of the present invention have been described above.

  The above-described information processing unit 140 may be configured to control hardware of any of the light source 110, the camera 120, the distance meter 130, and the position acquisition unit 150. At this time, the information processing unit 140 is not limited to an integrated information processing apparatus, but may be, for example, a plurality of information processing apparatuses connected to a communication network.

  The deterioration of the sound insulation board includes not only the deterioration of the optical characteristics but also the deterioration of a specific physical condition. Since the deterioration of the optical characteristics is correlated with the deterioration of the physical characteristics, it is possible to evaluate the deterioration of the physical characteristics of the sound insulation plate, for example, the strength, by the sound insulation plate inspection apparatus and the sound insulation plate inspection method of the present invention. Thereby, when a vehicle or other object collides with the sound insulation board, it is also possible to prevent damage such as personal injury caused by damage to the sound insulation board.

  The sound insulation board inspection apparatus and the sound insulation board inspection method of the present invention can be applied to the inspection of a sound insulation board.

DESCRIPTION OF SYMBOLS 10 sound insulation board, 100 sound insulation board inspection apparatus, 110 light source, 111 irradiation light, 120 camera, 121 reflected light, 130 distance meter, 140 information processing part, 145 determination part, 150 position acquisition part, 160 vehicle

Claims (11)

Irradiate the light shielding plate with light including the infrared wavelength range,
The sound-insulation board inspection method which image | photographs the sound-insulation board with which the said light is irradiated with the camera which detects the wavelength range of the said infrared rays. Further determining the degradation of the sound insulation board based on the intensity of the infrared radiation sensed by the camera;
The sound insulation board inspection method according to claim 1. The determination is performed based on a waveform indicating the intensity of the infrared light in the wavelength range of the infrared light.
The noise insulation board inspection method according to claim 2. The determination is made based on the difference in the intensity of the infrared light in a predetermined wavelength range,
The noise insulation board inspection method according to claim 2 or 3. Further measuring the distance to the sound insulation board,
Controlling the intensity of the light to be emitted based on the measured distance;
The noise insulation board inspection method according to any one of claims 1 to 4. Further measuring the distance to the sound insulation board,
Determining the deterioration based on the intensity of the infrared light and the measured distance,
The noise insulation board inspection method according to any one of claims 1 to 4. Further acquire the position information of the photographed position,
Relating the position information to the result of the determination;
The noise insulation board inspection method according to any one of claims 1 to 6. The light is a rectangular slit-like light extending in the vertical direction.
The noise insulation board inspection method according to any one of claims 1 to 7. Performing the irradiation and the imaging while traveling on a vehicle
The noise insulation board inspection method according to any one of claims 1 to 8. The sound insulation board is made of transparent resin,
The noise insulation board inspection method according to any one of claims 1 to 9. A light source that emits light including a wavelength range of infrared light to the sound insulation board;
A camera that senses the wavelength range of the infrared light and captures an image of a sound insulation board irradiated with the light;
Sound insulation board inspection device provided with.