KR20240012998A - Object distance setting type camera for structure - Google Patents

Abstract

The present invention relates to an imaging device used for diagnosis and inspection of various structures. A protruding rod 20 equipped with a detection unit 25 at the tip is installed at each vertex of the tripod plate 10, and the tripod plate ( 10) A transparent hole 15 is formed in the center so that the lens 41 of the smartphone 40 camera mounted on the back of the tripod plate 10 is exposed through the transparent hole 15, so that the shooting distance is constant. This is so that it can be set.
Through the present invention, not only is it possible to easily, precisely, and accurately photograph a subject even in situations where the direct proximity of an inspector is limited, but it is also possible to determine the exact dimensions of the subject in the acquired image, making it possible to use the captured image in the diagnosis and inspection of structures. Utilization can be dramatically improved.

Description

Photographing distance setting type structure photographing device {OBJECT DISTANCE SETTING TYPE CAMERA FOR STRUCTURE}

The present invention relates to an imaging device used for diagnosis and inspection of various structures. A protruding rod 20 equipped with a detection unit 25 at the tip is installed at each vertex of the tripod plate 10, and the tripod plate ( 10) A transparent hole 15 is formed in the center so that the lens 41 of the smartphone 40 camera mounted on the back of the tripod plate 10 is exposed through the transparent hole 15, so that the shooting distance is constant. This is so that it can be set.

Photographing structures is a basic task performed first in safety diagnosis and inspection, and is used to identify and record various phenomena that can be confirmed externally, such as cracks, surface peeling, and peeling, as well as deformation and deterioration formed in the subject. It can be useful.

As high-resolution digital cameras become smaller and lighter due to the advancement of digital camera technology, small digital cameras are being actively used for photographing structures. In particular, close-up photography of objects that are difficult for inspectors to directly access, such as high-altitude structures or narrow sections of structures, is being used. Various technologies that can assist are being developed.

This close-up assistive structure imaging device mainly has a small camera mounted on the distal end of a rod body, and related prior art includes Patent No. 2157308.

Through conventional close-up shooting assistance devices, including Patent No. 2157308, it has become possible to easily and safely shoot high-altitude or narrow structures where it is difficult for an inspector to approach directly, but it is necessary to allow the inspector to directly confirm the shooting point as well as the shooting situation. There were bound to be significant restrictions on actual control over the overall situation, so the use of the captured video information was also limited.

In other words, when an inspector is directly close to the subject and takes pictures with a camera he carries, he photographs the subject and simultaneously checks with the naked eye to check for cracks, deformation, deterioration, peeling, or delamination formed on the subject. In addition to being able to directly or indirectly determine the actual size of When taking pictures using an auxiliary device, it is impossible to secure not only the actual dimensions but also approximate dimensions.

In consideration of the above-mentioned problems, the present invention allows the subject to be photographed with the shooting distance accurately set even when shooting using an auxiliary device in conditions where the inspector cannot be close, thereby providing an accurate picture of the subject in the acquired image. It was created to determine the size. In the structure imaging device, a triangular plate 10 is installed at the top of the extension rod 50, and a protruding rod 20 protrudes forward at the entire vertex of the triangle plate 10. ) are formed respectively, a sensing unit 25 is mounted on the tip of the entire protruding rod 20, a transparent hole 15 is cut in the center of the triangular plate 10, and the rear surface of the triangular plate 10 is formed. The smartphone 40 is mounted so that the camera lens 41 of the smartphone 40 is exposed to the front through the transparency hole 15, and the entire sensing unit 25 is electrically connected to the lower part of the extension rod 50. It is a structure photographing device with a set shooting distance, which is equipped with a controller 60 connected and equipped with an output unit 63, and operates the output unit 63 when the entire sensing unit 25 touches the surface of the subject.

In addition, in the present invention, the protruding rod 20 formed on the triangular plate 10 is coupled to enable axial movement, and a plurality of locking grooves 27 are recessed on the outer peripheral surface of the protruding rod 20, and the triangular plate 10 Inside the coupling portion of the protruding bar 20 of (10), an arc plate 28 is installed so that one end is freely rotatable with respect to the triangular plate 10, and the other end of the arc plate 28 is connected to a locking groove 27. ) is a structure imaging device with a set shooting distance, characterized in that the protruding rod 20 is fixed as it is coupled to the.

Through the present invention, not only is it possible to easily, precisely, and accurately photograph a subject even in situations where the direct proximity of an inspector is limited, but it is also possible to determine the exact dimensions of the subject in the acquired image, making it possible to use the captured image in the diagnosis and inspection of structures. Utilization can be dramatically improved.

In particular, even when photographing high-altitude or narrow structures where it is difficult for inspectors to approach, the photographing distance, which is the distance between the subject and the objective lens, can be accurately set to capture the exact dimensions of cracks, deterioration, peeling, or peeling in the acquired image. It can be detected, thereby improving the reliability of structural exterior inspection and improving the convenience and efficiency of performing related tasks.

1 is a perspective view and a rear perspective view of the present invention.
Figure 2 is a rear perspective view of the main part of the present invention
Figure 3 is a front perspective view of the main part of the present invention
Figure 4 is a diagram illustrating the method of use of the present invention
5 is an exemplary circuit diagram of the present invention.
Figure 6 is a perspective view of the main portion of an adjustable embodiment of the present invention

The detailed configuration and operation of the present invention will be described through the attached drawings as follows.

First, Figure 1 is a perspective view showing the overall structure and appearance of the present invention. The right side of the drawing shows a front perspective view of the present invention, and the left side shows a rear perspective view of the present invention, where the front refers to the side facing the subject. And the back side is the side facing the user.

As shown in Figure 1, the present invention is basically a device configured with a photographing means at the upper end of an extension rod 50, and is a device that assists and supports photographing subjects that cannot be directly approached by inspectors, such as high-altitude structures or narrow structures. , while the inspector holds the lower end of the extension rod 50, photography is performed by remotely operating the photography means at the top of the extension rod 50.

As shown in FIGS. 1 to 3, the present invention, which is a structure imaging device, is composed of a tripod plate 10, an extension rod 50, a smartphone 40, and a controller 60, and FIG. 2 shows the detailed configuration. And as shown in FIG. 3, a triangular plate 10 is installed at the top of the extension rod 50, and protruding rods 20 protruding forward are formed at all vertices of the triangular plate 10, and the entire protrusion A sensing unit 25 is mounted on the tip of the rod 20.

In addition, as shown in FIG. 3, a transparent hole 15 is cut in the center of the triangular plate 10, and a smartphone 40 is mounted on the back of the triangular plate 10 to use the camera lens of the smartphone 40. (41) is exposed to the front through the transparent hole (15), and a controller (60) electrically connected to the entire sensing unit (25) and equipped with an output unit (63) is installed at the lower part of the extension rod (50). Thus, when the entire sensing unit 25 comes into contact with the surface of the subject, the output unit 63 is activated.

That is, as shown in FIGS. 2 and 3, at three vertices of the triangular plate 10 having the shape of an equilateral triangle, protruding rods 20 of the same shape and length project forward in the direction perpendicular to the triangular plate 10. The central point of the coupling portion of these protruding rods 20 also forms the vertex of an equilateral triangle on the triangular plate 10, and a sensing unit 25 of the same shape and structure is mounted at the tip of all protruding rods 20. When the sensing unit 25 touches an object, an electrical signal such as electricity is generated.

In the present invention, a camera mounted on the smartphone 40 is applied as a means of photographing a subject that is inspected for exterior inspection in the diagnosis or inspection of a structure. Most of the smartphones 40 currently on the market are used for exterior inspection of structures. Not only is it equipped with a high-performance camera that can meet the required image quality such as resolution and sensitivity, but it is also equipped with short-distance wireless communication functions such as Bluetooth, making remote operation via the remote control (49) easy, and captured images through its own display. Not only is it possible to immediately check, but it is also easy to store and transmit image information to other information devices, so significant advantages can be obtained through application of the smartphone 40.

In particular, while manufacturing the present invention requires a considerable amount of cost if a separate dedicated camera module is installed, by using a commercially available smartphone 40, not only can the manufacturing cost be significantly reduced, but the smartphone ( 40) is an information device frequently used in daily life, so it is also advantageous in terms of user convenience in operation.

In the present invention, the smartphone 40 may be installed in a way that it is directly attached to the back of the tripod plate 10, but as shown in Figures 2 and 3, it is attached to the top of the extension bar 50 or the tripod plate 10. A holder (30) can be mounted on the back and the smartphone (40) can be freely attached and detached from the holder (30). This allows the smartphone (40) carried by the inspector to be used in the holder (30) when photographing the structure. The method of mounting and utilizing it can also be applied.

As shown in FIG. 4, the imaging device of the present invention performs imaging with the entire sensing unit 25 at the tip of the protruding rod 20 in contact with the surface of the subject, as shown in the enlarged excerpt of the same drawing. An image that can confirm the actual size of the subject can be obtained. This is because the entire sensing unit 25, which forms a three-point contact point, is in contact with the surface of the subject, so the shooting distance, which is the distance between the subject and the lens 41, is set constant. This is because shooting can be performed in the and maintained state, and the magnification of the image thus obtained is set and maintained at a constant level.

That is, as all three sensing units 25 forming a three-point contact point on the surface of the subject generate a contact signal, the output unit 63 of the controller 60 is activated, and the user who confirms this operates the remote control 49, etc. By manipulating the smartphone 40 to take pictures, the generation of the contact signal of the entire sensing unit 25 and the operation of the output unit 63 can be performed through the circuit configuration as shown in FIG. 5.

As shown in FIGS. 2 and 5, the three sensing units 25 in the present invention can be of a simple contact switch type as well as various electrical means for checking whether contact is made, such as a contact sensor, and the controller 60 The output unit 63 configured in can be applied with a visual display means such as a light bulb or diode and an audible display means such as a bell or speaker. When the entire sensing unit 25 is in contact with the surface of the subject, these sensing units 25 and The output unit 63 of the electrically connected controller 60 operates by emitting light or generating sound.

In particular, as shown in Figure 5, which illustrates the simplest embodiment of the electrical configuration within the present invention as a circuit diagram, the power supply unit 61 built into the controller 60 and the output unit 63 mounted on the controller 60. And the main switch 65, and all three detection units 25 are connected in series to operate the output unit 63 according to the contact of all detection units 25.

In this way, through the present invention, it is possible to obtain image information from which precise actual dimensions can be extracted by setting the shooting distance to a constant level even with an extremely simple configuration and having the user confirm whether the appropriate shooting distance is established.

Meanwhile, Figure 6 shows that the shooting distance can be freely adjusted as needed by adjusting the length of the protruding portion on the front side of the triangle plate 10 of the protruding rod 20, so that the captured image can be adjusted according to field conditions or diagnostic work requirements. You can adjust the magnification.

That is, as shown in FIG. 6, the protruding bar 20 formed on the triangular plate 10 is coupled to penetrate the apex of the triangular plate 10, and is configured to enable axial movement of the protruding bar 20. A plurality of locking grooves 27 are recessed on the outer peripheral surface of the rod 20, and on the inside of the joint of the protruding rod 20 of the triangular plate 10, one end is connected to the triangular plate 10 so as to be freely rotatable. The template 28 is installed, and the other end of the arc template 28 is coupled to the locking groove 27, thereby fixing the protruding rod 20.

Here, the arc-shaped plate 28 is an arc-shaped plate, and as shown in the enlarged excerpt of FIG. 6, the surface of the triangular plate 10 and the arc-shaped plate 28 are installed parallel to each other, and the arc-shaped plate 28 One end is connected to the triangular plate 10 and the rotating shaft and rotates freely, and when the ring-shaped portion of the arc-shaped plate 28 is coupled to the locking groove 27 of the protruding rod 20, the protruding rod 20 moves in the axial direction. This is suppressed, and the arc-shaped plate 28 is rotated to separate the annular portion of the arc-shaped plate 28 from the locking groove 27, thereby allowing the axial movement of the protruding rod 20.

In this way, by adjusting the extension of the front side of the triangle plate 10 of the protruding bar 20, it is possible to adjust the shooting distance according to the situation and the magnification of the captured image, thereby expanding the application of the photographing device of the present invention in investigating the exterior of the structure. and the usability of the acquired images can also be improved.

10: triangle plate
15: Perspective hole
20: protruding bar
25: detection unit
27: Locking groove
28: arc plate
30: Holder
40: Smartphone
41: lens
49: remote control
50: extension rod
60: controller
61: power unit
63: output unit
65: Juice switch

Claims (1)

In the structure imaging device,
A triangular plate 10 is installed at the top of the extension rod 50, and protruding rods 20 that protrude forward are formed at all vertices of the triangular plate 10, and at the ends of all the protruding rods 20. A detection unit 25 is mounted;
A transparent hole 15 is cut in the center of the triangular plate 10, and a smartphone 40 is mounted on the back of the triangular plate 10 so that the camera lens 41 of the smartphone 40 is connected to the transparent hole 15. ) is exposed to the front through;
A controller 60 is installed at the lower part of the extension rod 50, which is electrically connected to the entire sensing unit 25 and equipped with an output unit 63. When the entire sensing unit 25 touches the surface of the subject, the output unit (63) A structure imaging device with a set shooting distance, characterized in that it operates.

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