JP7013834B2 - Abnormality inspection device - Google Patents

Description

The present invention relates to an abnormality inspection device used for visual inspection work at a high place.

Electric power companies have realized large-capacity transmission by multiplex radio (microwave radio) using radio waves in frequency bands (microwave band) such as 6.5 GHz band, 7.5 GHz band, and 12 GHz band. Antenna facilities such as parabolic antennas, radio towers, and waveguides used for microwave radio are regularly inspected for appearance, such as once every five years.

Conventionally, the appearance inspection has been carried out to check whether foreign matter has adhered to the tower members and attached hardware, small animals such as birds have not nested, the coating film is in good condition, and there is no obstruction in the radio wave passage. This was done by the operator who was involved in the inspection work visually. The appearance of the parabolic antenna installed at a height of about 20 m to 100 m above the ground was inspected by wearing a pole safety belt in order to avoid the risk of a crash.

As a related technique, specifically, conventionally, for example, the cumulative value of the amount of solar-ultraviolet solar radiation energy during the usage period of the radome is calculated for one target area among a plurality of areas obtained by dividing the surface of the radome. There was a technique related to a radome resin film deterioration estimation method in which the film thickness of the resin film in the target area was estimated from the calculated cumulative value and the degree of deterioration of the resin film in the target area was estimated from the estimated film thickness (for example). See Patent Document 1 below.).

Japanese Unexamined Patent Publication No. 2015-136604

However, in the conventional technology described above, the radome of a parabolic antenna must be in a position to lean out from a steel tower or antenna in order to look into the front of the antenna, and a safety belt is attached to perform an appearance inspection. However, there was room for improvement in worker safety.

In addition, instead of visually inspecting the appearance of the radome, when the appearance is inspected using an image taken by a small camera attached to the tip of the rod-shaped member, the rod-shaped member may be projected or the small camera for the radome may be used. In order to confirm the position, it was necessary to take a posture to lean out from the steel tower and the antenna, and there was room for improvement in the safety of the operator.

As a countermeasure, if the appearance is inspected using a drone equipped with a small camera, the safety of the operator can be ensured, but the parabolic antenna installed at the top of the wireless tower, that is, at a high place. Gusts and strong winds may occur around the area, making it difficult to secure an environment that allows the drone to float (hover) in the air at all times. There was a problem.

In addition, when conducting an appearance inspection using a drone equipped with a small camera, in order to fly over a densely populated area, it is necessary to ensure safety and obtain a flight permit based on the Aviation Law. There was a problem that the procedure for obtaining permission was complicated and the workability was inferior.

It is an object of the present invention to provide an abnormality inspection device capable of ensuring the safety of workers involved in visual inspection work and improving workability in order to solve the problems caused by the above-mentioned prior art.

In order to solve the above-mentioned problems and achieve the object, the abnormality inspection device according to the present invention has a fixing fulcrum portion removably attached to the center of a conical or hemispherical radome, and a fixing fulcrum portion having one end thereof. The other end has a rod shape extending in a direction away from the fixing fulcrum portion, and the other end moves on the circumference centering on the fixing fulcrum portion. It is characterized by including a rotating member that can be rotated, an image pickup device that can move along the rotating member, and an output means that outputs information about an image captured by the image pickup device.

Further, in the above invention, the abnormality inspection device according to the present invention includes a control means for controlling the rotation amount of the rotating member and the position of the image pickup device in the rotating member, and the output means controls the control. It is characterized in that it outputs information about the image in which information about the rotation amount controlled by the means and the position of the image pickup apparatus is associated with each other.

Further, in the above-mentioned invention, the abnormality inspection device according to the present invention is capable of swinging in a direction in which a hammer having a handle and a head attached to one end of the handle and the head are brought into contact with and separated from the redome. It is composed of a swing mechanism that supports the hammer, a microphone that is positioned in the vicinity of the hammer, and is provided with a tapping sound inspection unit that is movably provided along the rotating member. The position of the tapping sound inspection unit in the member and the swinging operation of the hammer by the rocking mechanism are controlled, and the output means controls the position of the tapping sound inspection unit and the microphone controlled by the control means. It is characterized in that it outputs information about the image including audio information collected by.

Further, in the above-mentioned invention, in the abnormality checking device according to the present invention, the control means performs frequency analysis based on the voice information collected by the microphone, and the output means is controlled by the control means. It is characterized by outputting information about the image including the position of the tapping sound inspection unit and at least one of the voice information collected by the microphone and the analysis result by the frequency analysis performed by the control means.

Further, the abnormality inspection device according to the present invention is characterized in that, in the above invention, the image pickup device is an infrared thermography camera.

Further, the abnormality inspection device according to the present invention is characterized in that, in the above invention, a fixing portion having one end fixed to the fixing fulcrum portion and having a rod shape longer than the radial dimension of the radome is provided.

Further, the abnormality inspection device according to the present invention is characterized in that, in the above invention, the fixing portion can be expanded and contracted in the length direction.

Further, the abnormality checking device according to the present invention is characterized in that, in the above invention, the abnormality checking device includes a storage unit for storing information related to the image, and the output means outputs information related to the image stored in the storage unit. And.

Further, the abnormality inspection device according to the present invention is characterized in that, in the above invention, the output means outputs information about the image to a predetermined terminal device by wireless communication.

Further, the abnormality inspection device according to the present invention is characterized in that, in the above invention, the rotation assisting member provided on the side opposite to the fixing fulcrum portion of the rotating member is provided.

According to the abnormality inspection device according to the present invention, there is an effect that the safety of the operator involved in the appearance inspection work can be ensured and the workability can be improved.

It is explanatory drawing which shows the appearance structure of the abnormality inspection apparatus of embodiment which concerns on this invention. It is explanatory drawing which shows the disassembled state of the abnormality inspection apparatus of embodiment which concerns on this invention. It is explanatory drawing which shows the hardware composition of the abnormality inspection apparatus of embodiment which concerns on this invention. It is explanatory drawing (the 1) which shows an example of a parabolic antenna. It is explanatory drawing (2) which shows an example of a parabolic antenna. It is explanatory drawing (3) which shows an example of a parabolic antenna. It is explanatory drawing (the 1) which shows the work procedure of the abnormality inspection using the abnormality inspection apparatus of embodiment which concerns on this invention. It is explanatory drawing (the 2) which shows the work procedure of the abnormality inspection using the abnormality inspection apparatus of embodiment which concerns on this invention.

Hereinafter, preferred embodiments of the abnormality inspection device according to the present invention will be described in detail with reference to the accompanying drawings.

(Appearance structure of abnormality inspection device)
First, the external structure of the abnormality inspection device according to the embodiment of the present invention will be described. FIG. 1 is an explanatory diagram showing an external structure of an abnormality inspection device according to an embodiment of the present invention. FIG. 2 is an explanatory diagram showing an exploded state of the abnormality inspection device according to the embodiment of the present invention.

In FIGS. 1 and 2, the abnormality checking device 100 according to the embodiment of the present invention includes a fixing fulcrum portion 110, a fixing portion 120, a rotating member 130, and an image pickup device 140. The fixing fulcrum 110 is detachably attached to the center of a conical or hemispherical radome (see FIGS. 5 and 6).

Specifically, the fixing fulcrum portion 110 can be realized by, for example, a chuck device called a vacuum chuck or the like, which sucks and fixes an object with a vacuum. By realizing the fixing fulcrum portion 110 by the vacuum chuck, the abnormality inspection device 100 can be reliably fixed to the radome work formed by using a non-magnetic material.

When the fixing fulcrum 110 is realized by a vacuum chuck, a compressor that generates a negative pressure is required. In recent years, there is a compressor that has been miniaturized to a size that can be carried by both hands of an adult, and even when the fixing fulcrum 110 is realized by a vacuum chuck, it is possible to suppress the increase in size and weight of the abnormality inspection device 100. Can be done. The power source of the compressor may be obtained by connecting a generator or the like installed on the ground to the compressor.

When the fixing fulcrum portion 110 is realized by a vacuum chuck, the compressor may be separated from the abnormality inspection device 100 and connected to the abnormality inspection device 100 at the site where the abnormality inspection device 100 is installed. In this case, by securing a tube and a power line connecting the abnormality inspection device 100 and the compressor, the abnormality inspection device 100 can be operated without transporting the compressor and the power source for operating the compressor to the upper part of the wireless tower. can. The fixing fulcrum portion 110 may be realized by a suction cup. The diameter of the suction cup can be appropriately set according to the weight of the fixing fulcrum 110, the length and weight of the rotating member 130, the weight of the image pickup device 140, and the like.

The fixing portion 120 has a rod shape. One end of the fixing portion 120 in the length direction is fixed to the fixing fulcrum portion 110. The positional relationship between the fixing portion 120 and the fixing fulcrum portion 110 is fixed. The other end of the fixing portion 120 in the length direction extends in a direction away from the fixing fulcrum portion 110. The length of the fixed portion 120 is longer than the radial dimension of the largest radome among the radomes to be inspected.

The fixing portion 120 may be expandable and contractible in the length direction. In the telescopic structure, for example, cylindrical members having similar cross sections are stacked in the order according to the length of the diameter, and the cylindrical member having a smaller diameter is arranged along the length direction with respect to the tubular member having a larger diameter. It can be realized by forming a structure that slides in a so-called telescopic structure. The appearance of the fixed portion 120 may be a prism shape as shown in FIGS. 1 and 2, or may be a cylindrical shape.

In the abnormality inspection work, the other end side of the fixing portion 120 may be fixed to an object to be attached such as a steel tower member constituting the wireless steel tower by using a rope or the like. Alternatively, the other end side of the fixing portion 120 may be provided with a mounting mechanism portion for fixing the position of the other end of the fixing portion 120 with respect to the radome. The mounting mechanism can be realized, for example, by a gripping metal fitting that grips the edge of the parabolic antenna. Alternatively, the mounting mechanism unit may be composed of, for example, a gripping metal fitting that grips an object to be mounted such as a steel tower member constituting a wireless steel tower, and an arm that connects the gripping metal fitting and the fixing portion 120.

The rotating member 130 has a rod shape. One end of the rotating member 130 in the length direction is connected to the fixing fulcrum portion 110. The other end of the rotating member 130 in the length direction extends in a direction away from the fixing fulcrum portion 110. The rotating member 130 is rotatably connected to the fixing fulcrum portion 110 so that the other end of the fixing fulcrum portion 110 moves on the circumference centered on the fixing fulcrum portion 110.

A rotation motor 131 and an encoder (see FIG. 3) are provided in the vicinity of the rotation center position of the rotation member 130. The rotary motor 131 is fixed to the fixed portion 120 and is connected to the rotary member 130 via a predetermined train wheel 131a composed of one or a plurality of gears. As a result, the rotating member 130 can be rotated around the fixing fulcrum portion 110.

A rotation assisting member may be provided at the tip of the rotating member 130. The rotation assisting member can be realized by, for example, a roller that can rotate around the axis parallel to the axis direction of the rotation member 130, or a slide shoe. By providing the rotation assisting member, the rotation of the rotating member 130 can be smoothed. The rollers and slide shoes can be formed by using, for example, hard silicon rubber.

The encoder includes a light emitting element such as an LED, a lens, a rotating slit disk (chord wheel), a light receiving element, and the like (all of which are not shown). The rotary slit disk is provided with a plurality of holes provided at equal intervals over one circumference, and rotates in conjunction with the rotation of the rotating member 130.

The encoder collects the confusion light emitted by the light emitting element with a lens and tilts it into the rotating slit disk, and after the light passing through the multiple holes of the rotating slit disk is incident on the photodiode on the light receiving element. By photoelectric conversion, two systems of square waves, A phase and B phase, are output. By providing the encoder, the amount of rotation and the direction of rotation of the rotating member 130 can be accurately specified.

The image pickup apparatus 140 is provided so as to be movable along the rotating member 130. The image pickup apparatus 140 reciprocates linearly along the rotating member 130. Specifically, for example, a screw shaft 132a provided in parallel with the rotating member 130 and a nut 132b screwed to the screw shaft 132a are provided, and an image is taken on the nut 132b of the ball screw 132 that converts the rotary motion into a linear motion. By connecting the devices 140, the image pickup device 140 can be linearly reciprocated along the rotating member 130. A ball (not shown) for smoothing the movement of the nut 132b with respect to the screw shaft 132a may be provided between the screw shaft 132a and the nut 132b in the ball screw 132.

A drive shaft of the moving motor 133 is connected to one end of the screw shaft 132a of the ball screw 132. As the mobile motor 133, for example, a stepping motor that rotates by a constant angle according to the pulse power can be used. By using the stepping motor, the position of the image pickup apparatus 140 can be controlled with high accuracy. An encoder that detects the rotation of the screw shaft 132a in the ball screw 132 may be provided.

The abnormality inspection device 100 may further include a linear motion guide (not shown) that guides the movement of the image pickup apparatus 140. In this case, the linear motion guide uses the rotating member 130 as a rail, and connects the block meshed with the rail to the image pickup apparatus 140. A ball is provided between the rail and the block to smooth the movement of the block with respect to the rail.

The image pickup apparatus 140 can be realized by, for example, a visible light camera that captures light rays (visible light) visible to the human eye. The image pickup device 140 includes a lens, an image pickup element in which light incident on the lens is imaged, an image processing circuit that generates and stores image information based on an electric signal output from the image pickup element, and the like. The image pickup device can be realized by, for example, a CCD (Charge Coupled Device) that outputs an electric signal obtained by photoelectrically converting light and darkness according to incident light into an amount of electric charge.

When the image sensor is realized by a CCD, the image processing circuit is an AFE (Analog Front) composed of a CDS (Correlated Double Sampling) circuit, an AGC (Automatic Gain Control) circuit, and an ADC (Analog / Digital Controller). It can be configured by End), DSP (Digital Signal Processor), or the like.

AFE generates a digital signal obtained by digitizing an analog signal based on an optical signal imaged on an image pickup device (CCD). The DSP generates a YUV signal based on the digital signal generated by the AFE. Since the configuration and processing of the image processing circuit can be easily realized by using known techniques, the description thereof will be omitted.

Alternatively, the image pickup apparatus 140 may be, for example, an infrared thermography camera that detects infrared radiant energy emitted from an object, converts it into an apparent temperature, and captures an image of the temperature distribution. Images captured by an infrared thermography camera are displayed in different colors according to temperature. The abnormality inspection device 100 may include both a visible light camera and an infrared thermography camera.

Further, the abnormality inspection device 100 includes an inspection start switch for instructing the rotation of the rotating member 130 and the start of image pickup by the image pickup device 140. The inspection start switch can be provided, for example, at the other end of the fixing portion 120. The rotation of the rotating member 130 and the instruction to start imaging by the imaging device 140 may be given based on a control signal output from a predetermined external device such as a tablet terminal operated by the operator.

Further, the abnormality inspection device 100 includes a power supply. As the power source, for example, a large-capacity battery using a lithium ion battery can be used. The power supply can be provided in the control box 150 provided at the other end of the fixed portion 120. In addition to the power supply, the control box 150 is provided with a control board, a memory, various operation switches, and the like on which a CPU that controls the operation of the abnormality inspection device 100 is mounted (see FIG. 3).

The power supply may be separate from the abnormality inspection device 100. In this case, the abnormality inspection device 100 includes, for example, a fixed portion 120 or the like, which is provided with a connector for connecting to a generator or the like installed on the ground. As a result, the abnormality inspection device 100 can be operated without worrying about the power supply capacity.

Through holes 122 and 134 through which the power cord 121, the tube of the vacuum chuck, and the like are inserted are provided on one end side of the fixing portion 120 and one end side of the rotating member 130. The through holes 122 and 134 may have, for example, an elliptical shape. As a result, the degree of freedom of the power cord 121 and the tube can be secured, and the power cord 121 and the tube can be prevented from being entangled.

(Hardware configuration of abnormality inspection device 100)
Next, the hardware configuration of the abnormality inspection device 100 will be described. FIG. 3 is an explanatory diagram showing a hardware configuration of the abnormality inspection device 100 according to the embodiment of the present invention. In FIG. 3, the abnormality checking device 100 includes a CPU (Central Processing Unit) 301, a memory 302, a rotary motor 131, an encoder 303, a mobile motor 133, an image pickup device 140, a communication I / F 304, and the like. It is equipped with an operation switch 305. Each of these parts is connected by a bus 300.

The CPU 301 is in charge of overall control of the abnormality inspection device 100. In this embodiment, the control means according to the present invention can be realized by the CPU 301, the memory 302, the communication I / F 304, and the like. The memory 302 stores various programs and data related to the control of the abnormality inspection device 100. Further, the memory 302 stores information about the image captured by the image pickup device 140.

The memory 302 can be realized by, for example, a non-volatile storage medium such as a flash ROM (Read-Only Memory). Such a memory 302 may be integrated with the abnormality inspection device 100, or may be a detachable separate body. Alternatively, only the memory 302 for storing the information related to the image may be provided separately from the abnormality checking device 100. The memory 302 may include a RAM used as a work area of the CPU 301.

The CPU 301 drives and controls the motors to rotate forward and backward by outputting a pulse signal (pulse power) to the rotary motor 131 and the mobile motor 133. By controlling the rotation amount and rotation direction of the rotation motor 131 and the movement motor 133 by the CPU 301, the rotation member 130 can be rotated and the image pickup device 140 can be reciprocated along the rotation member 130. The CPU 301 specifies the rotation direction, rotation position, rotation speed, and the like of the rotation motor 131, that is, the rotation member 130, based on the two square waves output by the encoder 303.

The CPU 301 drives and controls the image pickup device 140 to perform image pickup, and stores information about the image captured by the image pickup device 140 in the memory 302. Information related to the image includes, in addition to pixel information representing information such as RGB and transparency, the rotation angle of the rotating member 130 at the timing of capturing the image, the position of the image pickup device 140 with respect to the rotating member 130 (driving amount of the stepping motor), and so on. Includes information indicating the date and time of imaging. The imaging date and time can be acquired based on the time measured by the real-time clock provided in the CPU 301.

The communication I / F 304 controls the interface between the inside of the abnormality checking device 100 and the external device. Specifically, the communication I / F 304 controls the input / output of data between the inside of the abnormality inspection device 100 and an external device such as a tablet terminal carried and operated by an operator. The communication I / F 304 can perform wireless communication using a wireless LAN or the like. The input / output of data by the communication I / F 304 is controlled by the CPU 301.

The CPU 301 outputs information about an image imaged by, for example, an image pickup device 140 and stored in the memory 302 to an external device such as a tablet terminal via the communication I / F 304. In this embodiment, the output means according to the present invention can be realized by the CPU 301, the memory 302, the communication I / F 304, and the like.

The CPU 301 may determine the presence or absence of an abnormality based on the image captured by the image pickup device 140. The presence or absence of an abnormality is determined, for example, by identifying an edge whose density or color changes sharply in an image captured by the image pickup apparatus 140, and determining whether or not the image corresponds to a crack pattern based on the specific result. be able to. In this case, the CPU 301 may output information about an image including a determination result of presence / absence of abnormality (presence / absence of crack) and information indicating the position of crack. Alternatively, the CPU 301 may output information about the image only when it is determined that an abnormality has occurred (there is a crack).

(An example of a parabolic antenna)
Next, an example of a parabolic antenna that is a target of an abnormality inspection work using the abnormality inspection device 100 according to the embodiment of the present invention will be described. 4 to 6 are explanatory views showing an example of a parabolic antenna. As shown in FIG. 4, the parabolic antenna 400 is attached to the radio tower 401. Specifically, the parabolic antenna 400 is mounted at a position 20 to 100 meters above the ground, for example.

As shown in FIGS. 5 and 6, the parabolic antenna 400 includes an antenna portion 510 and a radome 520. FIG. 6 shows a part of a cross section of the parabolic antenna 400, which passes through the center of the parabolic antenna 400 and is cut along the opposite direction of the antenna portion 510 and the radome 520.

The antenna unit 510 includes a primary radiator 511 and a reflector 512. The primary radiator 511 transmits microwaves to space and receives microwaves in space. The reflector 512 is a concave mirror whose reflecting surface is the inner surface of a rotating parabolic surface obtained by rotating a parabola, and is provided to focus a bundle of light rays incident parallel to the axis of rotation at the focal point without aberration. The primary radiator 511 is provided at the focal point in the reflector 512.

The radome 520 has a conical or hemispherical shape, has an opening diameter of about 3 to 5 meters, and has a reflecting surface in the primary radiator 511 and the reflector 512 in order to protect the antenna portion 510 from wind, rain, and snowfall. It is provided to cover it. By providing the radome 520, deterioration of the primary radiator 511 and the reflecting surface can be alleviated, and the life of the antenna portion 510 can be extended. The radome 520 is formed by using a material that easily transmits radio waves, such as a fluororesin such as polytetrafluoroethylene called glass fiber or Teflon (registered trademark).

(Work procedure for abnormality inspection)
Next, a work procedure for abnormality inspection using the abnormality inspection device 100 according to the embodiment of the present invention will be described. 7 and 8 are explanatory views showing a work procedure of abnormality inspection using the abnormality inspection device 100 according to the embodiment of the present invention. In the work of abnormality inspection, the operator first transports the abnormality inspection device 100 to the installation location of the parabolic antenna 400 in the wireless steel tower 401.

Next, the other end of the fixing portion 120 is gripped, and the fixing fulcrum portion 110 is positioned at the center of the radome 520. When the fixing fulcrum 110 is realized by using the vacuum chuck, after confirming that the vacuum chuck is connected to the compressor and the power supply device, the vacuum chuck switch is turned on and the fixing fulcrum 110 is realized. Is fixed to the radome 520.

Next, the inspection start operation is performed by the inspection start switch among the operation switches 305 provided in the abnormality inspection device 100, or by an external device such as a tablet terminal. As a result, the rotation of the rotating member 130 and the imaging by the imaging device 140 are started. The abnormality checking device 100 stores information about the image captured by the image pickup device 140 in the memory 302 (see FIGS. 7 and 8). Further, when the operation for starting the inspection is performed based on the control signal output from the external device having a communication function such as the tablet terminal 801, the abnormality inspection device 100 outputs the information related to the image to the tablet terminal 801. You may.

When storing the information related to the image in the memory 302, the operator visually confirms the state of the entire surface of the redome 520 by displaying the information related to the image stored in the memory 302 on the tablet terminal 801 provided with the display screen. be able to. Then, the presence or absence of an abnormality in the radome 520 can be visually determined.

When the information related to the image is output to an external device such as the tablet terminal 801, by displaying the information related to the image on the tablet terminal 801 the operator can display the state of the entire surface of the radome 520 at a place away from the abnormal terminal device. It can be visually confirmed and the presence or absence of an abnormality in the radome 520 can be visually determined.

In the above-described embodiment, the abnormality inspection device 100 having a function of visually confirming the appearance state of the entire surface of the radome 520 by using the image pickup device 140 attached to the rotating member 130 has been described. The abnormality inspection device 100 according to the present invention is not limited to the one for visually confirming the appearance state. The abnormality inspection device 100 according to the present invention may have a function of inspecting the presence or absence of an abnormality in the entire radome 520, which is difficult to detect from the appearance state, in addition to the appearance state.

Such an abnormality inspection device 100 includes a tapping sound inspection unit in addition to the image pickup device 140. The abnormality inspection device 100 may include a tapping sound inspection unit instead of the image pickup device 140. The tapping sound inspection unit includes a hammer, a swing mechanism, and a microphone (all of which are not shown). The hammer comprises a handle and a head attached to one end of the handle.

The swing mechanism supports the hammer so that it can swing in the direction in which the head comes into contact with the radome 520. The swing mechanism supports the hammer swingably by, for example, axially supporting a part of the handle. Further, the swing mechanism includes a swing motor, a contactor that rotates with the rotation of the swing motor and comes into contact with the tip of the handle only at a predetermined rotation angle. Such a swing mechanism can swing the hammer by intermittently bringing the contactor into contact with the tip of the handle as the swing motor rotates.

The microphone is located near the hammer. Specifically, it is preferable that the microphone is positioned in the vicinity of the position where the head abuts on the radome 520 due to the swing of the hammer. A hood may be provided around the microphone to collect the hitting sound of the hammer with high accuracy. Similar to the above, the tapping sound inspection unit is provided so as to be movable along the rotating member 130 via the nut 132b of the ball screw 132, for example.

In the abnormality inspection device 100 including the image pickup device 140 and the tapping sound inspection unit, the image pickup device 140 and the tapping sound inspection unit may be provided at opposite positions with the rotating member 130 in between. As a result, the image pickup apparatus 140 and the tapping sound inspection unit can be reciprocated over the entire length direction of the rotating member 130, and the presence or absence of an abnormality can be accurately inspected over the entire radome 520.

The CPU 301 in the abnormality inspection device 100 provided with such a tapping sound inspection unit outputs a pulse signal (pulse power) to the rotary motor 131, the mobile motor 133, and the swing motor, and rotates the rotary member 130. Alternatively, the image pickup device 140 and the tapping sound inspection unit are reciprocated along the rotating member 130. As a result, both the image pickup apparatus 140 and the tapping sound inspection unit can move over the entire length direction of the rotating member 130, and detailed inspection can be performed.

The CPU 301 drives and controls the image pickup device 140 to perform imaging, and also drives and controls the tapping sound inspection unit to acquire the sound of the radome 520 with a microphone. Then, information about the image including the image captured by the image pickup apparatus 140, the sound acquired by the microphone, and the voice information such as the position where the sound is acquired is stored in the memory 302.

Further, the CPU 301 may perform frequency analysis of the sound acquired by the microphone. Specifically, for example, in the CPU 301, frequency analysis can be realized by performing spectral analysis based on the Fourier transform. By the spectral analysis based on the Fourier transform, it is possible to analyze what kind of frequency component is distributed and how much in the voice information by the tapping sound of the radome 520.

Thereby, based on the tapping sound of the radome 520, it is possible to determine whether or not there is a frequency component that occurs when an abnormality such as a crack occurs. As a result, the presence or absence of an abnormality in the radome 520 can be quickly detected, and the workability of the appearance inspection work can be improved.

When performing frequency analysis, the CPU 301 may store the analysis result of the frequency analysis in the memory 302 as voice information. In this case, the sound acquired by the microphone may be stored in the memory 302 together. Then, in this case, the CPU 301 outputs the information stored in the memory 302 (voice information acquired by the microphone, analysis result by frequency analysis, etc.) to an external device such as a tablet terminal via the communication I / F 304. do.

Even when both the voice information acquired by the microphone and the analysis result by the frequency analysis are stored in the memory 302, at least one of them may be output to an external device such as a tablet terminal. Specifically, for example, when the information stored in the memory 302 is output to an external device such as a tablet terminal by wireless communication, the voice information acquired by the microphone stored in the memory 302 and the analysis result by frequency analysis are obtained. Of these, at least one may be output.

As a result, the amount of communication can be suppressed, and the consumption of battery-operated electric devices such as tablet terminals can be suppressed. When the voice information acquired by the microphone is output, the presence or absence of an abnormality in the radome 520 can be determined by performing frequency analysis or the like on an external device such as a tablet terminal that has received the voice information.

In the abnormality inspection by the abnormality inspection device 100, the image pickup device 140 and the tapping sound inspection unit may be moved over the entire surface of the radome 520 to inspect the entire surface of the radome 520 for abnormalities. The tapping sound position by the tapping sound inspection unit may be determined in advance, and imaging and tapping sound inspection may be performed only at the determined position.

Further, the abnormality inspection device 100 according to the present invention may have a function of repairing a deteriorated portion on the surface of the radome 520 in addition to the function of visually confirming the appearance state of the entire surface of the radome 520. Such an abnormality inspection device 100 includes a repair mechanism unit in addition to the image pickup device 140. The abnormality inspection device 100 may include a repair mechanism unit instead of the image pickup device 140.

The repair mechanism is composed of a tank that houses the liquid, a spray head that sprays the liquid contained in the tank onto the surface of the radome 520, a head motor that operates the spray head, and a link mechanism that links the head motor and the spray head. (Both are not shown). The tank is filled with an FRP solvent such as a styrene monomer in which a fiber reinforced plastic called FRP (Fiber-Reinforced Plastics) is dispersed. Similar to the image pickup device 140 and the tapping sound inspection unit, the repair mechanism unit is provided so as to be movable along the rotating member 130 via the nut 132b of the ball screw 132, for example.

The CPU 301 in the abnormality inspection device 100 provided with such a repair mechanism unit drives and controls the rotation motor 131, the movement motor 133, and the head motor to rotate the rotation member 130, and the image pickup device 140 and the repair mechanism unit. It is reciprocated along the rotating member 130. Then, based on the information about the image, the repair mechanism unit is operated at the portion of the radome 520 determined to have cracks, and the FRP solvent is sprayed on the portion determined to be cracked.

As a result, if there is a slight crack, the radome 520 can be repaired without removing and repairing the radome 520, replacing the radome 520, or having the operator build a separate scaffold to repair the radome 520. You can do it. As a result, the life of the radome 520 can be extended.

The CPU 301 may be provided with a function of determining the presence or absence of an abnormality based on the result of an abnormality inspection using the image pickup apparatus 140 or the tapping sound inspection unit. Then, in this case, when it is determined that there is an abnormality such as a crack, the repair mechanism unit may be controlled to spray the FRP solvent.

As described above, the abnormality checking device 100 according to the embodiment of the present invention has a fixing fulcrum portion 110 removably attached to the center of a conical or hemispherical shape redo 520, and a fixing fulcrum portion 110 at one end. The other end has a rod shape extending in a direction away from the fixing fulcrum 110, and the other end moves on the circumference centered on the fixing fulcrum 110. It is characterized in that it includes a rotating member 130 that can be rotated and an image pickup device 140 that can move along the rotating member 130, and outputs information about an image captured by the image pickup device 140.

According to the abnormality inspection device 100 of the embodiment according to the present invention, the image pickup device is rotated along the fixing fulcrum portion 110 while rotating the rotating member 130 around the fixing fulcrum portion 110 attached to the center of the radome 520. By moving the 140, an image of the entire surface of the radome 520 can be obtained.

As a result, the operator who performs the appearance inspection work can visually check the state of the entire surface of the radome 520 without leaning out from the steel tower or the antenna for a long time. As a result, it is possible to ensure the safety of the worker involved in the appearance inspection work and improve the workability.

The radome resin film deterioration estimation method described in Patent Document 1 described above aims to accurately estimate the degree of deterioration of the radome resin film from the amount of solar energy or the amount of solar ultraviolet radiation to the radome. It is not intended for on-site appearance inspection. Further, the radome resin film deterioration estimation method described in Patent Document 1 described above targets only the ultraviolet rays of sunlight as the cause of the deterioration of the radome, and the radome is damaged by flying objects, or the radome is damaged by wind, rain or snowfall. Deterioration is not covered.

On the other hand, according to the abnormality inspection device 100 of the embodiment according to the present invention, by actually inspecting the appearance at the site, not only the ultraviolet rays of sunlight but also the radome is damaged by flying objects, and wind, rain and snow fall. It is possible to ensure the safety and improve the workability of the operator involved in the appearance inspection work for the appearance inspection regarding the presence or absence of deterioration of the radome due to such factors.

Further, the abnormality checking device 100 according to the embodiment of the present invention controls the rotation amount of the rotating member 130 and the position of the image pickup device 140 in the rotating member 130, and controls the rotation amount of the rotating member and the position of the image pickup device 140. The feature is that the information about the image associated with the information about the image is output.

According to the abnormality checking device 100 of the embodiment according to the present invention, the information on the image in which the rotation amount of the rotating member 130 and the information on the position of the image pickup device 140 on the rotating member 130 are associated with each other is output based on the image. When an abnormality such as a crack on the surface of the redome 520 is visually recognized, the position where the abnormality occurs can be easily and surely identified.

As a result, it is possible to quickly and accurately prepare for repairing the abnormality without performing an appearance inspection again to identify the position where the abnormality has occurred. As a result, it is possible to ensure the safety of the worker involved in the appearance inspection work and improve the workability.

Further, the abnormality inspection device 100 according to the embodiment of the present invention includes a hammer provided with a handle and a head attached to one end of the handle, and a hammer that swings in a direction in which the head comes into contact with and separates from the redome 520. It is composed of a swing mechanism that swings the hammer and a microphone that is positioned in the vicinity of the hammer, and is provided with a tapping sound inspection unit that is movably provided along the rotating member 130. While controlling the position and the swinging motion of the hammer by the swinging mechanism, the position of the tapping sound inspection unit and the voice information collected by the microphone may be output.

According to such an abnormality inspection device 100, the tapping sound inspection unit is moved along the fixing fulcrum portion 110 while rotating the rotating member 130 around the fixing fulcrum portion 110 attached to the center of the radome 520. Thereby, it is possible to check whether or not an abnormality has occurred in the entire radome 520 based on the tapping sound. Further, the position where the abnormality has occurred can be easily and surely specified based on the tapping sound and the position of the tapping sound inspection unit in the rotating member 130.

As a result, it is possible to check the presence or absence of abnormalities on the surface of the radome 520 and inside the radome 520 over the entire radome 520 without leaning out from the radio tower 401 or the parabolic antenna 400. As a result, it is possible to ensure the safety of the worker involved in the appearance inspection work and improve the workability.

Further, the abnormality inspection device 100 of the embodiment according to the present invention performs frequency analysis based on the voice information collected by the microphone, the position of the tapping sound inspection unit, and the voice information or frequency collected by the microphone. Information about the image, including at least one of the analysis results from the analysis, may be output.

According to such an abnormality inspection device 100, the presence or absence of an abnormality in the radome 520 can be quickly detected by performing frequency analysis based on the voice information collected by the microphone in the abnormality inspection device 100. This makes it possible to improve the workability of the appearance inspection work.

Further, in the abnormality inspection device 100 of the embodiment according to the present invention, the image pickup device 140 may be an infrared thermography camera.

According to such an abnormality inspection device 100, by capturing an infrared image (thermal image) of the entire surface of the radome 520 using an infrared thermography camera, a normal part and a part where an abnormality has occurred on the surface of the radome 520 The state of the entire surface of the radome 520 can be visually confirmed by utilizing the difference in the thermal conductivity of the radome 520.

As a result, the inspection work can be performed regardless of the brightness of the inspection environment, so that the inspection can be performed even in the evening or at night, and the degree of freedom in the inspection work can be improved. As a result, it is possible to ensure the safety of the worker involved in the appearance inspection work and improve the workability.

Further, the abnormality inspection device 100 according to the embodiment of the present invention is characterized in that one end thereof is fixed to the fixing fulcrum portion 110 and includes a fixing portion 120 having a rod shape longer than the radial dimension of the radome 520.

According to the abnormality inspection device 100 of the embodiment according to the present invention, the work of attaching or detaching the fixing fulcrum portion 110 to the center of the radome 520 for the operator is performed by grasping the other end of the fixing portion 120. You can do it. As a result, the worker can attach / detach the fixing fulcrum 110 to the center of the radome 520 without leaning out from the tower or the antenna for a long time or using a tool such as a yatko separately. be able to. As a result, it is possible to ensure the safety of the worker involved in the appearance inspection work and improve the workability.

Further, the abnormality inspection device 100 according to the embodiment of the present invention is characterized in that the fixing portion 120 can be expanded and contracted in the length direction.

According to the abnormality inspection device 100 of the embodiment according to the present invention, the fixing portion 120 can be expanded and contracted according to the size of the radome 520. As a result, it is possible to inspect a plurality of radomes 520 having different sizes by one abnormality inspection device 100 without carrying a plurality of abnormality inspection devices 100 having different lengths of the fixing portions 120. As a result, it is possible to improve the workability of the worker involved in the appearance inspection work.

Further, the abnormality checking device 100 according to the embodiment of the present invention is characterized in that it includes a memory 302 as a storage unit for storing information about an image, and outputs information about an image stored in the memory 302. There is.

According to the abnormality inspection device 100 of the embodiment according to the present invention, information about an image captured by the image pickup device 140 is stored in a storage unit included in the abnormality inspection device 100, and information about the stored image is output. When the image captured by the abnormality inspection device 100 is confirmed by a terminal device provided with a display separate from the abnormality inspection device 100, the image can be captured without reducing the processing speed of the abnormality inspection device 100. can. As a result, the worker can quickly check the image on the ground or other place where the scaffolding is secured, so that the safety and workability of the worker involved in the visual inspection work can be ensured. can.

Further, according to the abnormality checking device 100 of the embodiment according to the present invention, by storing the information related to the image in the storage unit, for example, data transfer between the memory 302 and the predetermined terminal device is performed via the CPU 301. DMA (Direct Memory Access) transfer can be performed directly through the bus without any problem. As a result, the worker can check the image more quickly in a place where the scaffolding is secured such as on the ground, so that the safety and workability of the worker involved in the visual inspection work can be ensured. Can be done.

Further, the abnormality checking device 100 according to the embodiment of the present invention is characterized in that information related to an image is output by wireless communication to a predetermined terminal device such as a tablet terminal 801.

According to the abnormality inspection device 100 of the embodiment according to the present invention, by outputting information about an image by wireless communication, it is not necessary to connect the abnormality inspection device 100 and the terminal device by wire, and the image is confirmed. You can increase the degree of freedom of location. As a result, the worker can check the image at a place where the scaffolding is secured, such as on the ground, so that the safety of the worker involved in the appearance inspection work can be ensured and the workability can be improved.

Further, the abnormality inspection device 100 according to the embodiment of the present invention is characterized by including a roller or a slide shoe as a rotation assisting member provided on the side opposite to the fixing fulcrum portion 110 of the rotating member 130. ..

According to the abnormality inspection device 100 of the embodiment according to the present invention, the rotation of the rotating member 130 can be smoothed. As a result, it is possible to prevent the image captured by the image pickup apparatus 140 from being blurred due to the vibration from the rotating member 130, and to perform a highly accurate appearance inspection.

As described above, the abnormality inspection device according to the present invention is useful for an abnormality inspection device used for visual inspection work at a high place, and in particular, an abnormality used for visual inspection of a radome of a parabolic antenna used for microwave radio. Suitable for inspection equipment.

100 Abnormality inspection device 110 Fixing fulcrum part 120 Fixing part 130 Rotating member 131 Rotating motor 133 Moving motor 140 Imaging device 301 CPU
302 Memory 303 Encoder 304 Communication I / F
400 Parabolic antenna 510 Antenna part 520 Radome

Claims (8)

A fixing fulcrum that is removable and attached to the apex of a conical or hemispherical radome,
One end is connected to the fixing fulcrum portion and the other end has a rod shape extending in a direction away from the fixing fulcrum portion, and the other end is a conical or hemispherical bottom surface centered on the fixing fulcrum portion. A rotating member that can rotate to move on the circumference,
An image pickup device that can move along the rotating member,
An output means for outputting information about an image captured by the image pickup device, and an output means.
An abnormality inspection device characterized by being equipped with. A control means for controlling the amount of rotation of the rotating member and the position of the image pickup device on the rotating member is provided.
The abnormality checking device according to claim 1, wherein the output means outputs information about the image in which information about the rotation amount controlled by the control means and the position of the image pickup device is associated with each other. A hammer having a handle and a head attached to one end of the handle, a swing mechanism that supports the hammer so that the head swings in a direction in which the head comes into contact with the radome, and a position near the hammer. It is provided with a hammering sound inspection unit which is composed of a microphone and is provided so as to be movable along the rotating member.
The control means controls the position of the tapping sound inspection unit in the rotating member and the swinging motion of the hammer by the swinging mechanism.
The abnormality according to claim 2, wherein the output means outputs information about the image including the position of the tapping sound inspection unit controlled by the control means and the voice information collected by the microphone. Inspection device. The control means performs frequency analysis based on the voice information collected by the microphone.
The output means includes at least one of the position of the tapping sound inspection unit controlled by the control means, the voice information collected by the microphone, or the analysis result by the frequency analysis performed by the control means. The abnormality inspection device according to claim 3, wherein information about an image is output. The abnormality inspection device according to any one of claims 1 to 4, wherein the image pickup device is an infrared thermography camera. A storage unit for storing information about the image is provided.
The abnormality checking device according to any one of claims 1 to 5 , wherein the output means outputs information about the image stored in the storage unit. The abnormality inspection device according to claim 6 , wherein the output means outputs information about the image to a predetermined terminal device by wireless communication. The abnormality inspection device according to any one of claims 1 to 7 , wherein the rotating member is provided with a rotation assisting member provided on the side opposite to the fixing fulcrum portion.

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