JP6509761B2 - Inspection stand and nondestructive inspection device - Google Patents

Description

  The present invention relates to an inspection rack used for nondestructive inspection which inspects the filling condition of an adhesive between an anchor and a hole of a structure in which the fixing portion is embedded, and a nondestructive inspection apparatus provided with the inspection rack. is there.

  When attaching a ceiling panel, wall panel, frame material, etc. to a reinforced concrete structure such as a ceiling or a wall, a construction anchor is fixed with an adhesive to a hole bored in the structure, and the head of the anchor bolt It is known to fix a panel or the like to a part (see Patent Document 1).

  Since the post-installed anchor is to be joined to the structure via the adhesive, the holes are filled with the adhesive so that the filling rate is equal to or higher than the predetermined filling rate in order to secure the desired withdrawal resistance (extraction force). It is required to be done.

  Since the filling condition of the adhesive can not be visually confirmed, estimation of the filling rate is performed by nondestructive inspection. In patent document 1, the soundness of a post-construction anchor is evaluated from the response energy of the impact at the time of hitting a head of an anchor with a hammer.

  On the other hand, Patent Document 2 discloses an inspection system in which the filling condition of urethane foam is detected by an electromagnetic wave radar after repairing a cavity of concrete with urethane foam.

  Further, Patent Document 3 discloses a cavity detection system which detects a cavity of a tunnel wall by nondestructive inspection by using an electromagnetic wave radar. Further, Patent Document 4 also discloses a concrete inspection method using an electromagnetic wave.

JP, 2015-114119, A JP, 2015-86555, A JP 2002-71827 A JP 2005-43197 A

  However, since the electromagnetic waves used in the electromagnetic wave radar device for nondestructive inspection have high straightness at high frequencies, they must be installed right above the hole in order to detect the cavity of the anchor hole accurately. On the other hand, since the head of the anchor projecting from the surface of the structure becomes an obstacle, it is difficult to install the electromagnetic wave radar transceiver at a desired position for inspection.

  Then, this invention aims at providing the non-destructive inspection apparatus provided with the test | inspection mount for making it possible to detect correctly the filling condition of the adhesive material of the hole which fixed the anchor.

  In order to achieve the above object, the inspection rack of the present invention is an inspection rack used for nondestructive inspection which inspects the filling condition of the adhesive between the anchor and the hole of the structure in which the fixing portion is embedded. A body portion formed into a solid frusto-conical shape from a material of the same quality as the structure, and a cylindrical portion provided at the center of the body portion for inserting the head of the anchor It is characterized by

  Here, the main body portion can have a multi-layered structure in which the height can be freely changed. Moreover, it can be set as the structure provided with the fixing jig for fixing to the head of the said anchor.

  Furthermore, the invention of the nondestructive inspection device is a nondestructive inspection device for inspecting the filling condition of the adhesive between the anchor and the hole of the structure in which the fixing portion is embedded, and the inspection rack according to any one of the above. And an electromagnetic wave radar transmitter-receiver that travels on the inclined peripheral surface of the main body.

  The inspection stand of the present invention thus configured is a cylindrical portion for inserting a head portion of the anchor and a body portion formed into a solid frusto-conical shape by the same material as the structure for fixing the anchor. It has a department.

  For this reason, by inserting the head of the anchor into the cylindrical portion, the inspection by the electromagnetic wave radar transceiver can be performed without the head becoming a hindrance. In addition, if the electromagnetic wave radar transmitter-receiver is disposed on the inclined surface of the main body, the electromagnetic wave going straight to the side of the hole of the anchor can be made to enter, so the inspection accuracy is improved and the adhesive filling condition Will be detected correctly.

  Further, in the case of the main body having a multilayer structure in which the height can be freely changed, the electromagnetic wave can be made to be incident on the location where the position in the depth direction is different by changing the angle of the inclined surface. The filling situation can be checked accurately.

  If a fixing jig for fixing to the head of the anchor is provided, even if the ceiling surface or wall surface is the surface of the structure to be inspected, keep the inspection rack stable during the inspection. Can.

  Then, it is possible to grasp the filling condition of the adhesive at various positions in the circumferential direction and at various depths in the axial direction only by running the electromagnetic wave radar transceiver on the inclined circumferential surface of the inspection stand such as these. it can.

It is a sectional view explaining the composition of the nondestructive inspection device provided with the inspection stand of this embodiment. It is a perspective view explaining the structure of the inspection stand of this embodiment. It is a perspective view showing the appearance of a spacecraft. It is sectional drawing explaining the inspection method by nondestructive inspection device. It is a perspective view explaining the composition of the inspection stand of an example. It is a sectional view explaining the inspection method by the nondestructive inspection device of an example. It is sectional drawing explaining the inspection condition by the inspection stand which changed height.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a view for explaining the state of nondestructive inspection for inspecting the filling state of the adhesive 5 performed using the nondestructive inspection device 1 of the present embodiment.

  In the present embodiment, an anchor B driven into a reinforced concrete structure M will be described as an example. The anchor B is a so-called "post-installed anchor" which is installed after the construction M is constructed.

  The structure M corresponds to a tunnel lining, a ceiling slab (or floor slab) of a building, a wall, and the like. Although the case where the surface M1 of the structure M is an upper surface is described as an example in the present embodiment, the present invention is not limited to this. The same inspection can be performed even when the surface M1 is the lower surface or the vertical surface.

  The anchor B is fixed from the surface M1 toward the deep part of the structure M in the anchor hole M2 as a hole drilled in a direction substantially orthogonal to the surface M1. The anchor B is mainly configured by a fixing portion B1 embedded in the anchor hole M2 and a head B2 protruding from the anchor hole M2.

  In the fixing portion B1 of the anchor B, the adhesive 5 is filled in the gap between the anchor bolt and the hole wall of the anchor hole M2. The adhesive 5 may be an organic adhesive such as epoxy resin or acrylic resin, or a cement (inorganic) adhesive such as cement milk or mortar.

  Although it is desirable that the adhesive 5 be filled in the anchor holes M2 without gaps, in actuality, the gaps 51A and 51B may be present and the filling rate may not be 100%. Then, the filling condition of the adhesive 5 is inspected using the nondestructive inspection device 1 of the present embodiment.

  The nondestructive inspection apparatus 1 mainly includes an inspection stand 3 mounted on a head B2 of the anchor B and a searcher 2 as an electromagnetic wave radar transmitter-receiver that travels on the inspection stand 3.

  As shown in FIGS. 1 and 2, the inspection rack 3 is a cylindrical portion provided at the center of the main body portion 31 for inserting the main body portion 31 formed in a frustoconical shape and the head portion B2 of the anchor B. Mainly composed of

  The main body portion 31 is solidly formed of a material of the same quality as that of the structure M. For example, it is made of cement-based material such as concrete or mortar. In addition, the main body portion 31 is formed in a “solid” shape in which the portion other than the cylindrical portion 32 is filled with a hollow and the like.

  The electromagnetic wave 25 is propagated equally to the structure M in the main body portion 31 which is formed in a solid shape by a material of the same quality as the structure M. Therefore, the electromagnetic wave 25 can be made to go straight without being refracted at the boundary between the structure M and the main body 31.

  The frusto-conical main body portion 31 is a curved surface in which the circumferential surface 311 is inclined. That is, an inclined surface is formed extending from the upper end of the cylindrical portion 32 to which the head portion B2 of the anchor B is fixed to the bottom surface 312 opposed to the surface M1 of the structure M.

  As the cylindrical portion 32, a hollow in which the anchor B can be inserted may be formed at the center of the main body portion 31. For example, the cylindrical portion 32 can be formed by embedding a cylindrical tube. Alternatively, the cylindrical portion 32 can be formed using a mold, and the mold can be removed after the main body 31 is cured.

  The diameter of the tubular portion 32 is preferably set to allow insertion of various anchors B. By setting the height of the cylindrical portion 32 to such a height that the tip of the head portion B2 of the anchor B can project, the head portion B2 and the main body portion 31 can be connected by the fixing jig 4 .

  The fixing jig 4 can be, for example, in the form of a cap fitted to the head B2. If the protrusion amount of the head B2 is not long, the cap-like fixing jig 4 is fitted from above into the opening 321 of the head B2 or the cylindrical portion 32, and the collar portion 41 of the main body 31 is pressed down. be able to.

  Moreover, when the protrusion amount of head B2 becomes long, the nut-shaped fixing jig 4 can also be used. Also in this case, the fixing jig 4 can be screwed into the head portion B2, and the collar portion 41 of the main body portion 31 can be pressed by the collar portion 41.

  By connecting the main body 31 and the anchor B via the fixing jig 4 as described above, the inspection rack 3 can be fixed to the structure M. When the surface M1 is the upper surface as shown in FIG. 1, the fixing jig 4 may be omitted, but when the surface M1 is the lower surface or the vertical surface, the inspection jig 3 can be used by using the fixing jig 4. Can be prevented from shifting during the examination.

  The spacecraft 2 is a device capable of detecting the position and size of a cavity inside the structure M using an electromagnetic wave radar. High-frequency search can be performed by outputting an electromagnetic wave 25 of high frequency of about 1600 MHz.

  The search device 2 using the electromagnetic wave radar detects the position and size of the cavity by emitting the electromagnetic wave 25 and receiving the electromagnetic wave 25 reflected by the cavity or the interface with the anchor B whose material changes. can do.

  The probe 2 has a vehicle-like appearance, as shown in FIG. A plurality of wheels 21 can be provided as traveling means, and the examiner can grip the grip portion 23 and freely travel the place where inspection is desired.

  An operating unit 24 such as a switch or a button is provided at the tip of the gripping unit 23. Further, settings such as inspection conditions and detection results are output to the display unit 22 configured of a liquid crystal screen or the like.

  Next, the method of nondestructive inspection which inspects the filling situation of adhesives 5 using nondestructive inspection device 1 of this embodiment, and the operation of inspection stand 3 and nondestructive inspection device 1 are explained.

  First, as a premise of nondestructive inspection, the head B2 of the anchor B fixed by the adhesive 5 is in a state of protruding from the surface M1 of the structure M. The nondestructive inspection can be performed immediately after the construction of the anchor B, or can be performed to check the state of the anchor B after the construction month.

  Here, for the sake of explanation, it is assumed that two spaces 51A and 51B where the adhesive 5 is not filled exist in the anchor holes M2. The presence, position and size (shape) of the air gaps 51A and 51B are detected by nondestructive inspection.

  The position of the hole of the cylindrical portion 32 exposed to the bottom surface 312 of the inspection rack 3 is aligned with the head portion B2 of the anchor B projecting from the surface M1 of the structure M, and the head portion B2 is passed through the cylindrical portion 32.

  Then, the inspection rack 3 is lowered until the bottom surface 312 of the main body portion 31 contacts the surface M1 of the structure M. The upper end of the anchor B is projected from the opening 321 of the cylindrical portion 32 of the inspection rack 3 disposed in this manner.

  The inspection rack 3 is fixed by the anchor B by fitting the fixing jig 4 to the head portion B2 of the anchor B which is projected. That is, the inspection stand 3 is not easily displaced or rotated about the anchor B.

  Thus, as shown in FIG. 1, the searcher 2 is placed at a position above the circumferential surface 311 of the inspection stand 3 installed with respect to the head B2 of the anchor B. The searcher 2 is installed in an inclined state (downward right in FIG. 1), and the electromagnetic wave 25 emitted from the bottom propagates inside the main body 31 of the inspection gantry 3 and the structure M, and the side surface of the anchor hole M2 It is incident on

  Then, the first air gap 51A is detected by the electromagnetic wave 25 incident from the side surface of the anchor hole M2. The position and size (shape) of the air gap 51A are output to the display unit 22 of the probe 2.

  Since the search device 2 has the wheels 21 and so on, the search device 2 can grip the grip portion 23 and travel in the circumferential direction along the circumferential surface 311. By traveling in the circumferential direction while emitting the electromagnetic wave 25, the filling condition of the adhesive 5 in the circumferential direction of the anchor hole M2 can be confirmed.

  In addition, the probe 2 is lowered gradually while traveling in the circumferential direction, in other words, by traveling the probe 2 in a spiral, as shown in FIG. Move.

  The electromagnetic wave 25 emitted from the moved probe 2 propagates inside the main body 31 and the structure M and is incident near the tip (lower end) of the anchor hole M2, and the second air gap 51B is detected. Become. Then, the position and the size (shape) of the air gap 51B are output to the display unit 22 of the probe 2.

  The inspection rack 3 of the present embodiment configured in this way has a main body 31 formed into a solid frusto-conical shape from a cement-based material of the same quality as the concrete structure M to which the anchor B is fixed; And a tubular portion 32 for inserting the head B2 of the anchor B.

  Therefore, by inserting the head B2 of the anchor B into the cylindrical portion 32, the inspection by the searcher 2 can be performed without the head B2 becoming an obstacle. In addition, if the probe 2 is disposed on the circumferential surface 311 which is the inclined surface of the main body portion 31, the electromagnetic wave 25 going straight to the side surface of the anchor hole M2 can be made incident, so the inspection accuracy is improved. Thus, the filling condition of the adhesive 5 can be accurately detected.

  That is, when the probe 2 travels 360 degrees along the circumferential surface of the main body 31 at various heights, the electromagnetic wave 25 emitted straight from the probe 2 is made to enter all sides of the entire length of the anchor hole M2. be able to.

  As a result, highly accurate inspection can be performed over the entire length of the anchor hole M2. In short, just by running the probe 2 on the inclined circumferential surface 311 of the inspection rack 3, the filling states of the adhesive 5 at various positions in the circumferential direction of the anchor hole M 2 and at various depths in the axial direction are obtained. be able to.

  And if the filling condition of the adhesive 5 can be grasped with high accuracy, the frequency of the pullout test of the anchor B can be reduced or omitted. In order to conduct the pull-out test of the anchor B, a reaction force exceeding the anchoring force of the anchor B is required, but as the sound anchor B is larger, the necessary reaction force becomes larger and the test equipment also becomes larger.

  In addition, in the case of the anchor B having a large diameter used in recent years, the fixing power is further increased, and in high places or narrow places, it may not be possible to conduct a pull-out test. In such a case, if the filling condition of the adhesive 5 can be confirmed by highly accurate nondestructive inspection, the soundness of many anchors B can be evaluated in a short time and at low cost.

  Moreover, if the fixing jig 4 for fixing to the head B2 of the anchor B is provided, even if the ceiling surface or wall surface is the surface M1 of the structure M to be inspected, the inspection rack 3 is It can be held stable.

  Hereinafter, an inspection stand 6 and a nondestructive inspection device 1A which are different from the embodiment described above will be described with reference to FIGS. 5 to 7. The same or equivalent parts as the contents described in the above embodiment will be described with the same terms or the same reference numerals.

  The inspection stand 6 of the nondestructive inspection apparatus 1A described in the present embodiment has a multilayer structure in which the height can be freely changed as shown in FIGS. In the present embodiment, the inspection rack 6 having a two-layer structure will be described.

  The inspection rack 6 is mainly formed of a main body 60 formed in a frusto-conical shape in a stacked state, and a cylindrical portion 63 provided at the center of the main body 60 for inserting the head B2 of the anchor B. Configured

  That is, in the main body 60, the overall outer shape of the upper layer 61 disposed on the upper side and the lower layer 62 disposed on the lower side is formed in a frusto-conical shape. The upper layer portion 61 and the lower layer portion 62 are solidly formed of a material of the same quality as that of the structure M. For example, it is made of cement-based material such as concrete or mortar.

  Further, the lower layer portion 62 is formed in a frusto-conical shape, and at the center thereof, a cylindrical portion 63 in which a cavity into which the anchor B can be inserted is formed is provided. For example, the cylindrical portion 63 can be formed by burying the lower portion of the cylindrical tube.

  The bottom surface 622 of the lower layer portion 62 is a circular flat surface whose entire surface is in contact with the surface M1 of the structure M, and the circumferential surface 621 is an inclined curved surface. The inner surface of the recess 612 of the upper layer 61 is brought into contact with the circumferential surface 621.

  That is, although the upper layer portion 61 has a frusto-conical outer appearance formed by the circumferential surface 611, the back side is recessed so that the lower layer portion 62 can be accommodated. When the upper layer portion 61 is stacked on the lower layer portion 62, the inner surface of the recess 612 and the circumferential surface 621 are in close contact (see FIG. 6).

  At the center of the upper layer portion 61, an insertion hole 613 is formed in which the upper portion of the cylindrical portion 63 can be inserted. For example, the insertion hole 613 can be formed by embedding a cylindrical tube. Alternatively, the insertion hole 613 may be formed using a mold, and the mold may be removed after the upper layer portion 61 is cured.

  FIG. 6 shows the state of nondestructive inspection by the inspection gantry 6 in a state in which the upper layer portion 61 and the lower layer portion 62 are stacked. The peripheral surface 611 of the inspection rack 6 at this time has a large inclination angle, and the electromagnetic wave 25 is incident on the upper part of the anchor hole M2, and therefore, it is suitable for the upper inspection.

  On the other hand, FIG. 7 shows the state of nondestructive inspection by the inspection gantry 6 in a state in which the upper layer portion 61 is removed to leave only the lower layer portion 62. The circumferential surface 621 of the inspection rack 6 at this time has a small inclination angle, and is suitable for inspecting the lower part of the anchor hole M2.

As described above, in the case of the main body portion 60 having a multilayer structure in which the height can be freely changed, the upper layer portion 61 is fitted and removed, and the angle is changed to the peripheral surfaces 611 and 621 to be inclined surfaces. Since the electromagnetic wave 25 can be made to be incident on the position where the position in the depth direction is different, the filling condition of the full length of the fixing part B1 can be inspected accurately.
In addition, about another structure and an effect, since it is substantially the same as the said embodiment, description is abbreviate | omitted.

  As mentioned above, although the embodiment of the present invention has been described in detail with reference to the drawings, the specific configuration is not limited to the embodiment and the example, and a design change which does not deviate from the scope of the present invention. Is included in the present invention.

  For example, although the case where the fixing jig 4 is attached to the head portion B2 of the anchor B has been described in the embodiment and the examples, the present invention is not limited to this. A clearance between the cylindrical portion 32 and the head portion B2 The inspection racks 3 and 6 can also be fixed by filling them.

  Moreover, in the said Example, although the test | inspection gantry 6 of 2 layer structure was demonstrated, it is not limited to this, It can also be set as the test | inspection gantry of 3 or more-layer multilayer structure.

B anchor B1 anchorage part B2 head M structure M2 anchor hole (hole)
1 Nondestructive inspection device 2 Probe (electromagnetic wave radar transceiver)
21 wheels (running means)
25 electromagnetic wave 3 inspection stand 31 main body 311 circumferential surface 32 cylindrical portion 4 fixing jig 5 bonding material 51A, 51B air gap (filling condition)
1A Nondestructive inspection device 6 inspection rack 60 main body 61 upper layer 611 peripheral surface 62 lower layer 621 peripheral surface 63 cylindrical portion

Claims (4)

It is an inspection stand used for nondestructive inspection which inspects a filling situation of an adhesive between an anchor and a hole of a structure in which the fixing portion is embedded,
A solid frusto-conical shaped body portion of the same material as said structure;
And a cylindrical portion provided at the center of the main body for inserting the head of the anchor.   The inspection rack according to claim 1, wherein the main body portion has a multi-layered structure in which the height can be freely changed.   The inspection rack according to claim 1 or 2, further comprising a fixing jig for fixing to a head of the anchor. A nondestructive inspection device for inspecting the filling condition of an adhesive between an anchor and a hole of a structure in which the fixing portion is embedded,
The inspection gantry according to any one of claims 1 to 3.
A nondestructive inspection device comprising: an electromagnetic wave radar transceiver for causing the inclined peripheral surface of the main body portion to travel.