JP2020159890A - Method for inspecting inside of outer wall - Google Patents

Abstract

To provide a method for inspection which can inspect the inside of the outer wall of a building without leaving a scratch in the wall.SOLUTION: The present invention includes: a first arranging step (step S11) for arranging an X-ray detector 2 in the inner side than an outer wall panel 1 so that an X-ray can be emitted to an inspection target part in the outer wall panel 1; a second arrangement step (step S12) for arranging an X-ray film 3 in the outer side than the outer wall panel 1 so that an X-ray emitted from the X-ray detector 2 to the inspection target part can be detected; and an X-ray irradiation step (step S13) for emitting an X-ray from the X-ray detector 2 to the inspection target part.SELECTED DRAWING: Figure 1

Description

The present invention relates to a technique for inspecting the inside of an outer wall of a building.

Conventionally, a technique for inspecting the inside of an outer wall of a building has been known.

Patent Document 1 describes a panel frame formed by combining upper, lower, left and right frame materials in a square ring shape, an exterior surface material provided on the front side (outdoor side) of the panel frame, and a back surface of the panel frame. An outer wall panel including an interior surface material provided on the side (indoor side) and a heat insulating material placed in the panel frame is described.

In order to inspect internal defects (rust on the frame, etc.) that cannot be judged from the appearance of such an outer wall panel, the exterior or interior surface material of the outer wall panel may be peeled off, or a fiberscope (external or interior material) may be used. It is necessary to make a hole for inserting the camera), and there is a problem that the outer wall panel is damaged.

Japanese Unexamined Patent Publication No. 2003-105919

The present invention has been made in view of the above circumstances, and the problem to be solved is to provide an inspection method capable of examining the internal state of the outer wall of a building without damaging the outer wall. is there.

The problem to be solved by the present invention is as described above, and next, the means for solving this problem will be described.

That is, in claim 1, the method for inspecting the inside of the outer wall of a building is to direct the X-ray generator toward the inspected portion in the outer wall on either the indoor side or the outdoor side of the outer wall. The X-ray detector is irradiated from the X-ray generator toward the inspected portion on either the indoor side or the outdoor side of the outer wall in the first arrangement step in which the X-rays can be irradiated. It includes a second arrangement step of arranging the X-rays so as to be detectable, and an X-ray irradiation step of irradiating the X-ray generator toward the portion to be inspected.

In claim 2, the outer wall is composed of an outer wall panel, the outer wall panel is provided with a panel frame for accommodating a heat insulating material inside, and the inspected portion is a lower end constituting the lower end portion of the panel frame. It includes a frame.

In claim 3, the inspected portion includes the outdoor side end portion of the lower end frame.

In claim 4, the lower end frame includes a bottom surface, an indoor side rising portion that rises upward from the indoor side end portion of the bottom surface, and an outdoor side rising portion that rises upward from the outdoor side end portion of the bottom surface. Then, in the first arrangement step, the X-rays emitted from the X-ray generator on the indoor side of the outer wall panel are irradiated on the inspected portion without passing through the indoor rising portion. The X-ray generator is arranged in the room.

In claim 5, in the first arrangement step, the angle of the X-rays emitted from the X-ray generator with respect to the horizontal direction is the lower end of the outdoor side rising portion of the lower end frame and the indoor rising portion. The X-ray generator is arranged so as to be larger than the angle of the line connecting the upper end of the portion with respect to the horizontal direction.

As the effect of the present invention, the following effects are exhibited.

In claim 1, the state of the inside of the outer wall of the building can be examined without damaging the outer wall.

In claim 2, the presence or absence of defects inside the outer wall can be grasped by examining the state of the lower end frame in which defects (rust, corrosion, etc.) are most likely to occur due to the water that invades the inside of the outer wall and flows downward. can do.

In claim 3, the state of the outdoor side end of the lower end frame where defects (rust, corrosion, etc.) are most likely to occur due to water (rainwater) that invades the inside of the outer wall from the outdoor side and flows downward is investigated. Therefore, it is possible to grasp the presence or absence of defects inside the outer wall.

In claim 4, since the inspected portion can be photographed without overlapping the indoor rising portion of the lower end frame, the state of the inspected portion can be easily determined.

In claim 5, the inspected portion can be easily prevented from overlapping the indoor rising portion of the lower end frame in the X-ray irradiation direction, and the state of the inspected portion can be easily determined. ..

A vertical cross-sectional view showing an outer wall panel to be inspected by the inspection method according to the embodiment of the present invention, and a view showing a state of inspecting the inside of the outer wall panel. The flowchart of the inspection method which concerns on one Embodiment of this invention.

Hereinafter, the configuration of the outer wall panel 1 to be inspected by the inspection method according to the first embodiment will be described with reference to FIG. In FIG. 1, the front side shows the outdoor side and the rear side shows the indoor side.

The outer wall panel 1 constitutes an outer wall (outer shell) of a building such as a house. In this embodiment, the structure of the building is a lightweight steel structure. The outer wall panel 1 mainly includes a panel frame 10, a heat insulating material 20, an exterior surface material 30, and an interior surface material 40.

The panel frame 10 is composed of a plurality of frame materials connected to each other. The panel frame 10 houses the heat insulating material 20 described later inside. The outer shape of the panel frame 10 is formed in a substantially rectangular parallelepiped shape. The panel frame 10 includes an upper end frame 11 and a lower end frame 12.

The upper end frame 11 constitutes the upper end portion of the panel frame 10. The upper end frame 11 is arranged so that the longitudinal direction is directed to the left and right. The upper end frame 11 is formed in a substantially U-shape (substantially U-shape) in a side view, and is arranged with the open side facing downward.

The lower end frame 12 constitutes the lower end portion of the panel frame 10. The lower end frame 12 is arranged so that the longitudinal direction is directed to the left and right. The lower end frame 12 is formed in a substantially U-shape (substantially U-shape) when viewed from the side, and is arranged with the open side facing upward. The lower end frame 12 includes a bottom portion 12a, an outdoor side rising portion 12b, and an indoor side rising portion 12c.

The bottom portion 12a constitutes the lower portion (bottom portion) of the lower end frame 12. The bottom portion 12a is formed in a plate shape with the plate surface facing in the vertical direction.

The outdoor side rising portion 12b constitutes a front end portion (outdoor side end portion) of the lower end frame 12. The outdoor side rising portion 12b is formed so as to rise upward from the front side (outdoor side) end portion of the bottom portion 12a.

The indoor side rising portion 12c constitutes the rear end portion (indoor side end portion) of the lower end frame 12. The indoor side rising portion 12c is formed so as to rise upward from the rear (indoor side) end of the bottom portion 12a.

At the left and right ends of the panel frame 10, a frame material extending in the vertical direction is provided so as to connect the upper end frame 11 and the lower end frame 12. The frame material and the upper end frame 11 and the lower end frame 12 are fixed to each other by welding or the like. As a result, the panel frame 10 is formed in the shape of a substantially rectangular parallelepiped frame.

The heat insulating material 20 is for insulating the outdoor side and the indoor side of the outer wall panel 1. As the heat insulating material 20, for example, glass wool is used. The heat insulating material 20 is formed in a substantially rectangular parallelepiped shape. The heat insulating material 20 is housed in the space inside the panel frame 10.

The exterior surface material 30 constitutes the front side (outdoor side) of the outer wall panel 1. The exterior surface material 30 is formed in the shape of a rectangular plate when viewed from the front. The exterior surface material 30 is fixed to the front side (outdoor side) surface of the panel frame 10 and the heat insulating material 20 via an appropriate member.

The interior surface material 40 constitutes the rear side (indoor side) of the outer wall panel 1. The interior surface material 40 is formed in the shape of a rectangular plate when viewed from the rear. The interior surface material 40 is fixed to the rear side (indoor side) surface of the panel frame 10 and the heat insulating material 20 via an appropriate member.

Hereinafter, a method of inspecting the inside of the outer wall panel 1 configured in this way will be described with reference to FIGS. 1 and 2.

The inspection method according to the present embodiment inspects (inspects) the internal state of the outer wall panel 1, and mainly inspects defects (rust, corrosion, etc.) in the lower end frame 12 of the outer wall panel 1. When water has entered the inside of the outer wall panel 1, the infiltrated water tends to collect at the lower end of the outer wall panel 1. In addition, water (rainwater) often infiltrates from the outdoor side. Therefore, it is considered that the outdoor side end portion of the lower end frame 12 is most likely to rust inside the outer wall panel 1. Therefore, in the inspection method according to the present embodiment, the outdoor side end portion of the lower end frame 12 which is considered to be the most rusty is set as the inspected portion (inspection target). Note that the "outdoor end of the lower end frame 12" is not construed as being limited to the outermost end of the lower end frame 12 on the outdoor side, but is on the outdoor side (front side) of the front and rear center of the lower end frame 12. It shows the part of.

Further, in the inspection method according to the present embodiment, a radiation transmission test (RT) is used. Hereinafter, a specific description will be given.

First, the X-ray generator 2 is arranged (step S11 shown in FIG. 2). The X-ray generator 2 irradiates X-rays from the irradiation port 2a. As the X-ray generator 2, for example, a portable X-ray generator or a battery-powered pulse X-ray generator can be used. The X-ray generator 2 is arranged on the indoor side (indoor) of the outer wall panel 1. The X-ray generator 2 is arranged on the floor F in the room via a tripod or the like. As a result, the irradiation port 2a of the X-ray generator 2 is located above the lower end frame 12 to be inspected. The X-ray generator 2 is arranged so as to be able to irradiate X-rays toward the outdoor side end portion (inspected portion) of the lower end frame 12.

Hereinafter, the X-ray irradiation direction (direction of the irradiation port 2a) of the X-ray generator 2 will be described in more detail. The X-ray generator 2 is arranged with the irradiation port 2a facing forward and downward so that the outdoor side end portion (inspected portion) of the lower end frame 12 is irradiated with X-rays.

Here, the distance in the front-rear direction from the inner side surface (the surface facing rearward) of the outdoor side rising portion 12b of the lower end frame 12 to the surface (the surface facing rearward) of the interior surface material 40 is A, and the distance from the surface of the interior surface material 40. The distance in the front-rear direction to the irradiation port 2a of the X-ray generator 2 is B, the vertical distance (height) from the floor F to the irradiation port 2a of the X-ray generator 2 is C, and the bottom portion 12a of the lower end frame 12 The vertical distance (height) from the upper surface (upward facing surface) to the floor F is D, and the inner side surface of the outdoor side rising portion 12b (rear facing surface) of the lower end frame 12 to the indoor side rising portion 12c. The distance in the front-rear direction to (front facing surface) is a, and the vertical distance (height) from the upper surface (upward facing surface) of the bottom 12a of the lower end frame 12 to the upper end of the indoor rising portion 12c is b. To do. The X-ray generator 2 is arranged so that the distances B and C indicating the positions of the irradiation ports 2a satisfy the following equation 1. The distances A, D, a and b are calculated from the design drawings and the like.
(Equation 1) b / a <(C + D) / (A + B)

In other words, the angle of the X-ray irradiation direction (line L1 connecting the irradiation port 2a and the lower end of the outdoor side rising portion 12b (the intersection of the bottom portion 12a and the outdoor side rising portion 12b)) with respect to the horizontal direction (floor F). E, When the angle of the line L2 connecting the lower end of the outdoor side rising portion 12b of the lower end frame 12 and the upper end of the indoor side rising portion 12c with respect to the horizontal direction (bottom 12a) is e, the X-ray generator 2 is an irradiation port. The angle E indicating the direction of 2a is arranged so as to satisfy the following equation 2. The angle e is calculated from a and b calculated from the design drawings and the like.
(Equation 2) e <E

By arranging the X-ray generator 2 in this way, the X-ray irradiation direction (line L1 connecting the irradiation port 2a and the lower end of the outdoor side rising portion 12b) overlaps with the indoor side rising portion 12c of the lower end frame 12. do not do. In other words, the outdoor side end portion (inspected portion) of the bottom portion 12a of the lower end frame 12 can be irradiated with X-rays without passing through the indoor side rising portion 12c.

Next, the X-ray film 3 is arranged (step S12 shown in FIG. 2). The X-ray film 3 is arranged so as to be in close contact with the surface (the surface facing forward) of the exterior surface material 30 on the outdoor side of the outer wall panel 1. More specifically, the X-ray film 3 can receive (detect) X-rays emitted from the X-ray generator 2 toward the outdoor side end portion (inspected portion) of the lower end frame 12 at a substantially central portion thereof. Placed in position. The X-ray film 3 is arranged in a state of being attached to the cassette.

Next, X-rays are irradiated from the X-ray generator 2 (step S13 shown in FIG. 2). In this step, X-rays are emitted from the X-ray generator 2 arranged in step S11. The irradiated X-rays pass through the lower end frame 12 and the like to expose the X-ray film 3.

Next, the X-ray film 3 is developed (step S14 shown in FIG. 2). When the lower end frame 12 is rusted, the rusted portion (defective portion) is thicker than the non-rusted portion (healthy portion). When X-rays pass through the lower end frame 12 and the like, a small amount of X-rays are transmitted in the defective portion as compared with the healthy portion, and the X-ray film 3 is exposed to weaker light. Therefore, when the X-ray film 3 is developed, a portion having a large amount of X-ray transmission appears blacker, and a transmission photograph having a difference in shade can be obtained. By observing this transparent photograph, the internal state of the outer wall panel 1 (rust on the lower end frame 12) can be grasped.

As described above, according to the inspection method according to the present embodiment, by applying the radiation transmission test (RT) to the outer wall panel 1 (outer wall) of the building, the internal state (panel) of the outer wall panel 1 cannot be judged from the appearance. Rust on the frame 10) can be inspected without destroying the outer wall panel 1.

Further, in the inside of the outer wall panel 1, as described above, the outdoor side (front side) end of the lower end frame 12 is the most defective due to the water (rainwater) that invades the inside of the outer wall panel 1 from the outdoor side and flows downward. Rust, corrosion, etc.) are likely to occur. By examining the state of this portion, it is possible to grasp the presence or absence of defects inside the outer wall panel 1.

Further, if the X-ray generator 2 is arranged lower than in the present embodiment so that the direction of the irradiation port 2a is closer to horizontal, the inspected portion (photographed object) is arranged in the X-ray irradiation direction. The outdoor side end portion of the bottom portion 12a of a certain lower end frame 12 overlaps with the indoor side rising portion 12c of the lower end frame 12. If there are many overlapping parts, it is difficult to determine the state of the part to be inspected. On the other hand, in the inspection method according to the present embodiment, X-ray irradiation is performed by irradiating the inspected portion (the outdoor side end portion of the bottom portion 12a of the lower end frame 12) without passing through the indoor side rising portion 12c. Since the overlapping portion with the inspected portion can be reduced in the direction, it is possible to easily determine the state of the inspected portion.

As described above, the inspection method of the outer wall panel 1 (outer wall) according to the present embodiment is the inspection method of the inside of the outer wall panel 1 (outer wall) of the building, and X-rays are generated on the indoor side of the outer wall panel 1. The first arrangement step (step S11) in which the vessel 2 is arranged so that X-rays can be irradiated toward the portion to be inspected in the outer wall panel 1, and the X-ray film 3 (X) on the outdoor side of the outer wall panel 1. The second arrangement step (step S12) of arranging the X-ray detector) so that the X-rays emitted from the X-ray generator 2 toward the inspected portion can be detected, and the X-ray generator 2 to the subject. It includes an X-ray irradiation step (step S13) of irradiating an inspection unit with X-rays.
With this configuration, the internal state of the outer wall panel 1 of the building can be examined without damaging the outer wall panel 1.

Further, the outer wall is composed of an outer wall panel 1, the outer wall panel 1 includes a panel frame 10 for accommodating a heat insulating material 20 inside, and the inspected portion constitutes a lower end portion of the panel frame 10. The lower end frame 12 is included.
With this configuration, by investigating the state of the lower end frame 12 in which defects (rust, corrosion, etc.) are most likely to occur due to the water that invades the inside of the outer wall panel 1 and flows downward, the outer wall panel 1 It is possible to grasp the presence or absence of internal defects.

Further, the portion to be inspected includes the outdoor side end portion of the lower end frame 12.
With this configuration, the outdoor side end of the lower end frame 12 is most likely to cause defects (rust, corrosion, etc.) due to water (rainwater) that invades the inside of the outer wall panel 1 from the outdoor side and flows downward. By examining the state of the above, it is possible to grasp the presence or absence of defects inside the outer wall panel 1.

Further, the lower end frame 12 has a bottom portion 12a (bottom surface), an indoor side rising portion 12c that rises upward from the indoor side end portion of the bottom portion 12a, and an outdoor side rising portion that rises upward from the outdoor side rising portion of the bottom portion 12a. 12b, and in the first arrangement step (step S11), X-rays radiated from the X-ray generator 2 on the indoor side of the outer wall panel 1 cause the indoor side rising portion 12c. The X-ray generator 2 is arranged so that the portion to be inspected is irradiated without intervention.
With this configuration, the inspected portion (outdoor side end of the lower end frame 12) can be photographed without overlapping with the indoor rising portion 12c of the lower end frame 12, so that the state of the inspected portion can be easily determined. can do.

Further, in the first arrangement step (step S11), the angle E of the X-ray irradiation direction (line L1) emitted from the X-ray generator 2 with respect to the horizontal direction is the rising portion of the lower end frame 12 on the outdoor side. The X-ray generator 2 is arranged so as to be larger than the angle e of the line L2 connecting the lower end of the 12b and the upper end of the indoor rising portion 12c with respect to the horizontal direction.
With this configuration, the portion to be inspected (the outdoor side end portion of the lower end frame 12) can be easily prevented from overlapping with the indoor side rising portion 12c of the lower end frame 12 in the X-ray irradiation direction. As a result, it is possible to easily determine the state of the inspected portion.

The outer wall panel 1 according to the present embodiment is a form of the outer wall.
Further, the X-ray film 3 according to the present embodiment is an embodiment of the X-ray detector.

Although one embodiment of the present invention has been described above, the present invention is not limited to the above configuration, and various modifications can be made within the scope of the invention described in the claims.

For example, in the present embodiment, a lightweight steel-framed building is targeted for inspection, but the structure of the building is not limited to this, and heavy-duty steel-framed structures, wooden structures, reinforced concrete structures, and steel-framed / reinforced concrete structures. It may have other structures such as.

Further, in the present embodiment, the outer wall panel 1 is targeted for inspection, but it does not necessarily have to be in the shape of a panel, and may be an outer wall that constitutes the outer shell of the building.

Further, in the present embodiment, the X-ray generator 2 is arranged on the indoor side (indoor) of the outer wall panel 1 (step S11), and the X-ray film 3 is arranged on the outdoor side of the outer wall panel 1. However, the X-ray generator 2 may be arranged on the outdoor side of the outer wall panel 1, and the X-ray film 3 may be arranged on the indoor side of the outer wall panel 1.

Further, in the present embodiment, the lower end frame 12 of the panel frame 10 is included in the inspected portion (imaging range), but the upper end frame 11 and the lower end frame 12 are connected to the inspected portion (imaging range). A frame material, a heat insulating material 20, a crosspiece (not shown), and the like may be included. This makes it possible to check for rust on the frame material, wetting of the heat insulating material 20, corrosion of the crosspiece, and the like.

Further, in the present embodiment, the X-ray film 3 is used as the X-ray detector, but an imaging plate (IP) may be used. When an imaging plate is used, the imaging result can be output as a digital image by reading the X-ray image data recorded on the imaging plate with a reading device. A flat panel detector can also be used as the X-ray detector.

1 Outer wall panel 2 X-ray generator 3 X-ray film 10 Panel frame 12 Lower end frame 12a Bottom 12b Outdoor side rising part 12c Indoor side rising part

Claims (5)

It is a method of inspecting the inside of the outer wall of a building.
The first arrangement step of arranging the X-ray generator on either the indoor side or the outdoor side of the outer wall so as to irradiate the X-ray toward the inspected portion in the outer wall.
A second arrangement step in which an X-ray detector is arranged on either the indoor side or the outdoor side of the outer wall so as to be able to detect X-rays emitted from the X-ray generator toward the inspected portion. ,
An X-ray irradiation step of irradiating an X-ray from the X-ray generator toward the inspected portion,
Equipped with
How to inspect the inside of the outer wall. The outer wall is composed of an outer wall panel.
The outer wall panel
Equipped with a panel frame to house the heat insulating material inside
The inspected portion includes a lower end frame constituting the lower end portion of the panel frame.
The method for inspecting the inside of an outer wall according to claim 1. The inspected portion includes the outdoor side end portion of the lower end frame.
The method for inspecting the inside of an outer wall according to claim 2. The lower end frame is
It is provided with a bottom surface, an indoor side rising portion that rises upward from the indoor side end portion of the bottom surface, and an outdoor side rising portion that rises upward from the outdoor side end portion of the bottom surface.
In the first placement step
The X-ray generator is arranged indoors from the outer wall panel and so that the X-rays emitted from the X-ray generator irradiate the inspected portion without passing through the indoor rising portion. To do,
The method for inspecting the inside of an outer wall according to claim 3. In the first placement step
The angle of the X-rays emitted from the X-ray generator with respect to the horizontal direction in the irradiation direction is greater than the angle with respect to the horizontal direction of the line connecting the lower end of the outdoor side rising portion and the upper end of the indoor side rising portion of the lower end frame. The X-ray generator is arranged so that
The method for inspecting the inside of an outer wall according to claim 4.

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