JP5053038B2 - Building - Google Patents

Description

  The present invention relates to a building.

Conventionally, the Ministry of Land, Infrastructure, Transport and Tourism's “Damage Criteria for Damage Level Classification and Guidelines for Restoration Techniques” of the Ministry of Land, Infrastructure, Transport and Tourism has been used to determine whether buildings damaged by an earthquake or the like can be used (non-patent literature 1).
This estimates the damage state of a building, for example, whether it can live or not, by displacement based on the inclination angle of a pillar or the like.

Judgment criteria for earthquake damage and restoration technology guidelines (issued by Japan Building Disaster Prevention Association)

  However, in the method according to Non-Patent Document 1 as described above, since the maximum value of the deformation angle at the time of the earthquake is estimated from the distortion of the building after the earthquake disaster, the work at the site becomes complicated. In particular, when the displacement of a column or the like is small, the measurement work for the displacement becomes complicated.

  An object of the present invention is to provide a building capable of making a highly accurate determination regarding a damaged state.

The building 1 of the present invention includes displacement measuring devices 30 and 60 that measure displacements of the plurality of wall constituent members 11 in a wall 10 composed of a plurality of wall constituent members (columns) 11 during vibration, and the wall 10. And display portions 40 and 70 that are provided outside and display the measurement results of the displacement measuring devices 30 and 60, and the wall 10 is fixed to the wall 10 and is vibrated. A vibration damping device 20 that converts the displacement of the displacement portion 22 that is displaced along with the rotation of the pendulum member 23 and prevents the rotation of the pendulum member 23 by the vibration absorbing member 241 is provided, and the displacement measuring devices 30 and 60 are provided. Is characterized by measuring a displacement of the pendulum member 23 of the vibration damping device 20 at the time of maximum rotation .

  Here, as the wall 10 which comprises the building 1 of this invention, what is called a wall panel which attached the face material to the frame material, concrete, mortar, a timber, a tile, metal, resin, etc., the wall-shaped thing It can be illustrated. Moreover, as the wall structural member 11, a pillar, a beam, a window frame, etc. can be illustrated. Further, examples of the displacement measured by the displacement measuring devices 30 and 60 include those based on the inclination, deformation, and horizontal movement of the wall constituting member 11.

According to the present invention, when the wall 10 or the like vibrates due to an earthquake or the like, the empirical maximum displacement of the wall constituting member 11 is measured by the displacement measuring devices 30 and 60, and the measurement result is displayed on the wall 10 by the display units 40 and 70. Displayed externally.
For this reason, even if the displacement of the wall constituent member 11 at the time of vibration is small, the measured value is displayed outside the wall 10, so that the wall constituent member 11 is not required to carry out a complicated measurement operation. Can be accurately recognized. Therefore, the determiner can make a highly accurate determination on the damaged state of the building 1 corresponding to the displacement of the wall constituting member 11.
Further, according to the present invention, the displacement portion 22 is displaced along with the vibration of the wall 10, and the displacement of the displacement portion 22 is amplified and converted into rotation of the pendulum member 23. Then, the displacement measuring devices 30 and 60 measure the displacement of the pendulum member 23 when the pendulum member 23 rotates to the maximum as the displacement of the amplified wall component member 11.
For this reason, for example, the relationship between the amount of rotation of the pendulum member 23 and the displacement of the wall constituent member 11 is obtained in advance by experiments or the like, so that even if the displacement of the wall constituent member 11 is small, the pendulum member 23 Based on the amplified rotation amount, the displacement of the wall constituting member 11 can be easily and reliably measured. Therefore, it is possible to make a more accurate determination regarding the damaged state of the building 1.

And in the building 1 of this invention, the said displacement measuring devices 30 and 60 hold | maintain the rod 311 and 613 which contact | abuts the rotation end part of the said pendulum member 23, and this rod 311 and 613 so that it can advance / retreat to an axial direction. Rod holding portions 323 and 612 to be measured, measuring portions 33 and 62 for measuring the amount of movement when the rods 311 and 613 are pushed by the pendulum member 23, and the rod holding portions 323 and 612 to the vibration damping device 20 And a positioning part 35 for positioning with respect to each other.
According to the present invention, the rods 311 and 613 move by an amount corresponding to the rotation amount of the pendulum member 23 when pushed by the rotation end of the pendulum member 23.
For this reason, the displacement of the wall constituent member 11 can be easily performed by a simple method of simply confirming the amount of movement of the rod 311 by, for example, visual observation or by simply converting the amount of movement of the rod 613 into an electrical signal. It can be measured. In addition, the structure of the displacement measuring devices 30 and 60 can be simplified.

In the building 1 of the present invention, the displacement measuring device 30 includes a return blocking unit 34 that prevents the rod 311 from returning after the rod 311 is pushed and moved by the pendulum member 23. preferable.
According to the present invention, when the rod 311 is pushed by the pendulum member 23 and moved, the return blocking portion 34 prevents the rod 311 from returning.
Here, in the case of the configuration in which the return blocking unit 34 is not provided, for example, if a second earthquake smaller than this earthquake occurs after the first earthquake, the rod 311 may return due to the second earthquake. is there. For this reason, there is a possibility that the amount of movement of the rod 311 may be an amount corresponding to the second earthquake that is smaller than the first earthquake. On the other hand, in the present invention, since the rod 311 is prevented from returning by the return blocking portion 34, the rod 311 does not return even if a small second earthquake occurs. For this reason, the movement amount of the rod 311 becomes an amount corresponding to the first earthquake, and a determination with higher accuracy can be made.

Furthermore, in the building 1 of the present invention, the measurement unit 33 indicates a scale portion 331 provided on one of the rod 311 and the rod holding portion 323 and a predetermined position of the scale portion 331 provided on the other side. The display unit 40 is a window provided at a position where the measurement unit 33 can be seen through a measurement opening (wall opening) 12A formed in the wall 10. A configuration including the portion 42A is preferable.
According to the present invention, since the measuring unit 33 is composed of the scale unit 331 and the scale instruction unit 332, the displacement of the wall constituting member 11 is measured even when power cannot be supplied due to a power failure at the time of a disaster, for example. Can improve convenience. Further, the measurement result can be visually observed through the window portion 42A, and the configuration of the displacement measuring device 30 can be simplified as compared with the configuration in which the display result is displayed as an image.

In the building 1 of the present invention, the measurement unit 62 includes an electric signal output unit 621 that outputs an electric signal corresponding to the position of the rod 613 with respect to the rod holding unit 612, and an electric signal output from the electric signal output unit 621. A configuration including a movement amount calculation unit 622 that calculates the movement amount of the rod 613 based on a signal is preferable.
According to the present invention, since the position of the rod 613 relative to the rod holding portion 612, that is, the amount of movement of the rod 613, is calculated based on the electrical signal, it can be measured more precisely and more accurately than, for example, a configuration that is measured visually. High judgment can be made.

And in the building 1 of this invention, the said wall 10 is provided with the operation opening part (wall opening part) 12A formed in the position corresponding to the said displacement measuring apparatus 30, The said displacement measuring apparatus 30 is A configuration provided with an operation contact portion 315A provided integrally with the rod 311 and operable from the outside of the wall 10 through the operation opening 12A is preferable.
According to the present invention, after measuring the displacement of the wall constituting member 11, the rod 311 can be easily returned to the measurement reference position by operating the operation contact portion 315A from the outside of the wall 10. Therefore, it is possible to improve the efficiency of the preparation work for restarting the measurement.

Furthermore, in the building 1 of the present invention, it is preferable that a plurality of the operation contact portions 315 </ b> A are arranged in parallel along the moving direction of the rod 311.
Here, when there is only one operation contact portion 315A, when the amount of movement of the rod 311 increases, the operation contact portion 315A moves to a position where the operation is difficult, and the movement work of the rod 311 is not performed. May be difficult. On the other hand, in the present invention, the plurality of operation contact portions 315A are juxtaposed along the movement direction of the rod 311. Therefore, even if the amount of movement of the rod 311 increases, at least any The single operation contact portion 315A can be positioned at an easily operable position, and the rod 311 can be easily moved from the outside of the wall 10.

  According to the present invention described above, there is an effect that it is possible to provide a building capable of making a highly accurate determination regarding a damaged state.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

[First Embodiment]
First, a first embodiment of the present invention will be described.
FIG. 1 is an exploded perspective view of an outer wall panel constituting the building according to the first embodiment. FIG. 2 is a perspective view showing a main part of the outer wall panel. FIG. 3 is an exploded perspective view from the indoor side of the displacement measuring device. FIG. 4 is a front view showing the display unit and the measurement unit. FIG. 5 is a cross-sectional view showing the return blocking portion.

[Configuration of external wall panel]
As shown in FIG. 1, the wall 10 has an outer wall panel, a pair of pillars 11 as wall constituent members, an outer surface material 12 provided in a state of bridging the outdoor sides of the pair of pillars 11, and a chamber of the pillars 11. An inner surface material (not shown) provided in a state of bridging the inside is formed in a panel shape, and in this embodiment, the structural material of the building 1 is configured. The wall 10 includes a vibration damping device 20 that prevents vibration of the wall 10, a displacement measuring device 30 that measures the displacement of the column 11 based on the operating state of the vibration damping device 20, and a measurement result of the displacement measuring device 30. And a display unit 40 for displaying.

[Configuration of vibration control device]
The vibration damping device 20 includes a rectangular frame 21 fixed between the pair of pillars 11, a pair of displacement portions 22 provided in the frame 21, and a pendulum supported by the one displacement portion 22. A member 23 and a pair of damping boxes 24 provided on the frame body 21 are provided.

  The frame body 21 has a rectangular frame shape that includes a pair of left and right vertical frames 211 fixed to the inner peripheral surface of the pillar 11 and a pair of upper and lower horizontal frames 212 provided in a state of bridging the pair of vertical frames 211. It is formed by assembling. Two opposing plates 212A are provided upright at both ends of the horizontal frame 212, respectively. The end of the vertical frame 211 is inserted between the two opposing plates 212A, and the plate 212A and the vertical frame 211 are connected by a bolt 213 and a nut (not shown). The horizontal frame 212 is provided with a pair of fixing members 214 for fixing the vibration damping box 24.

  The pair of displacement portions 22 are each formed with a pair of support plates 221 that are formed in a substantially isosceles triangle shape and whose apexes are located in the approximate center of the frame body 21. The pair of support plates 221 are fixed to the vertical frame 211 sandwiched therebetween by bolts 222.

The pendulum member 23 is formed in an elongated substantially rhombus plate shape, and is provided in a state where the longitudinal direction thereof coincides with the vertical direction of the frame body 21. The pendulum member 23 has a left half portion sandwiched between a pair of support plates 221 of one displacement portion 22 and a right half portion sandwiched between a pair of support plates 221 of the other displacement portion 22. Yes. In addition, two holes (not shown) are formed in the central portion of the pendulum member 23 so as to be separated from each other on the left and right, and one of the holes is a long hole that is long on the left and right. A shaft member 231 such as a bolt is inserted into each hole formed in the pendulum member 23 and each support plate 221 of the pair of displacement portions 22, and a nut (not shown) is screwed to the end portion. ing.
And since the pendulum member 23 is formed in the shape of a long hole whose one hole is long to the left and right, and is supported by the displacement portion 22 by the shaft member 231, the pair of displacement portions 22 is accompanied with the inclination of the column 11 due to vibration. Is displaced to the left and right about the approximate center in the longitudinal direction.

  The pair of vibration damping boxes 24 are formed in a rectangular box shape with an upper surface and a lower surface opened, and are respectively provided in a state of being sandwiched between a pair of fixing members 214. A pair of vibration absorbing members 241 formed of, for example, a viscoelastic material is fixed to the inner surface of the vibration damping box 24. These vibration absorbing members 241 are vibration damping rubbers, and are fixed in a state where the connecting plate 242 is sandwiched therebetween. One end side of the connecting plate 242 is connected to the end of the pendulum member 23 through the plate 243. And if the pendulum member 23 rotates, the damping box 24 will attenuate this rotation by the vibration absorption member 241.

[Configuration of displacement measuring device]
As shown in FIGS. 1 and 2, the displacement measuring device 30 is provided in a vibration damping box 24 on the lower side of the vibration damping device 20, and measures the displacement when the pendulum member 23 is rotated at the maximum.
As shown in FIGS. 2 and 3, the displacement measuring device 30 includes a measurement contact portion 31 that contacts the rotating end portion of the pendulum member 23 and a measurement holding portion that holds the measurement contact portion 31 movably. 32, a measurement unit 33 that measures the amount of movement of the measurement contact unit 31, and a return blocking unit 34 that prevents the measurement contact unit 31 from moving in the direction opposite to the direction pushed by the pendulum member 23 (return direction). And a positioning part 35 for positioning the measurement holding part 32 with respect to the vibration damping device 20.

  The measurement contact portion 31 is formed of a resin, for example, in a substantially round bar shape, and includes a rod 311 that contacts the rotating end portion of the pendulum member 23. One end surface (hereinafter referred to as a front end surface) 311A of the rod 311 abuts on the connecting plate 242, that is, the rotating end portion of the pendulum member 23. In addition, a disc-shaped rod positioning portion 312 having a diameter larger than that of the rod 311 is integrally provided at the other end (hereinafter referred to as a base end) of the rod 311. Furthermore, an approximately rectangular plate-like upward extension extends outwardly along the radial direction of the rod 311 (hereinafter, this extending direction is referred to as “upward”) on the outer circumferential surface of the rod 311 in the substantially axial direction. A protruding portion 313 and a laterally extending portion 314 having a substantially rectangular plate shape extending in a direction substantially orthogonal to the upward extending portion 313 from the tip of the upward extending portion 313 are integrally provided.

When the side extending portion 314 is held by the measurement holding portion 32, the lower surface 314 </ b> A is substantially in sliding contact with an upper end surface 321 </ b> A of the holding base portion 321, which will be described later, and the distal end surface 314 </ b> B and one side surface 321 </ b> B of the holding base portion 321. Are formed in a shape located on substantially the same plane. On the upper surface of the laterally extending portion 314, a rod operating portion 315 having a substantially right triangular plate shape that is slightly thinner than the laterally extending portion 314 is provided.
The rod operation unit 315 has one side out of a pair of sides that form a right angle on the side edge of the side extending portion 314 on the tip surface 311A side of the rod 311 and the other side in the axial direction of the rod 311. The portion corresponding to the oblique side is provided in a state of being inclined with respect to the distal end surface 314B of the side extending portion 314. Further, four operation contact portions 315 </ b> A formed in a step shape that is separated from the distal end surface 314 </ b> B toward the proximal end side of the rod 311 are provided at a portion corresponding to the oblique side of the rod operation portion 315.

The measurement holding unit 32 includes a holding base 321 formed in a rectangular plate shape from a deformable material such as a resin. The center in the short side direction (vertical direction) on the other side opposite to the one side 321B of the holding base 321 is substantially orthogonal to the other side of the holding base 321 from one side edge (right side edge) to the substantially center in the longitudinal direction. A connecting portion 322 extending in the direction is integrally provided.
A rod holder 323 that integrally holds the rod 311 so as to be able to advance and retreat in the left-right direction of the holding base 321 is integrally provided at the distal end of the connecting portion 322.
The rod holding portion 323 is formed in a substantially cylindrical shape having a substantially C-shaped cross section that can be inserted through the rod 311 and opened to the upper edge side of the holding base portion 321.

As shown in FIGS. 2 and 4, the measurement unit 33 includes a scale portion 331 provided on the laterally extending portion 314 of the measurement contact portion 31 and a scale portion 331 provided on the holding base portion 321 of the measurement holding portion 32. And a scale instruction unit 332 for instructing a predetermined position.
The scale portion 331 is provided on the distal end surface 314B of the laterally extending portion 314 so that the measurement value increases from the proximal end side of the rod 311 toward the distal end side.
The scale instruction part 332 is provided at the approximate center in the left-right direction in the vicinity of the upper edge of the one side 321B of the holding base 321. Specifically, the scale instruction unit 332 indicates a position of 0 cm (centimeter) of the scale unit 331 when the rod 311 is inserted until the rod positioning unit 312 contacts the right end of the rod holding unit 323. Is provided.

As shown in FIG. 5, the return blocking portion 34 includes a plurality of annular rod-side grooves 341 provided on the outer peripheral surface from a position slightly proximal to the distal end side of the substantially center of the rod 311, and a rod holding portion. A plurality of annular holding side grooves 342 provided on the inner peripheral surface on the left end side of the H.323, and a holding portion tightening member 343 provided on the outer peripheral surface on the left end side of the rod holding portion 323 are provided.
The holding part fastening member 343 is formed in a substantially C shape having an inner diameter dimension slightly smaller than the outer diameter dimension of the rod holding part 323, for example, by an elastically deformable material such as a wire.
When the holding portion tightening member 343 is provided so as to substantially cover the rod holding portion 323, the inner diameter dimension of the holding portion tightening member 343 is slightly smaller than the outer diameter size of the rod holding portion 323. Due to the elastic force of the member 343, the left end side of the rod holding portion 323, that is, the holding side groove portion 342 side is deformed so as to be thin. When the rod 311 is inserted into the rod holding portion 323 in such a deformed state, the rod 311 is tightened by the holding side groove portion 342 side of the rod holding portion 323, and the rod side groove portion 341, the holding side groove portion 342, and Are substantially engaged. This substantially engagement prevents the rod 311 from moving in the returning direction.

As shown in FIGS. 2 to 4, the positioning unit 35 includes a connecting plate 351 formed in a rectangular plate shape from metal, for example. One end (upper end) side in the longitudinal direction of the connecting plate 351 is screwed to one side 321B of the holding base 321 by four screws 352. In addition, a screw insertion hole 351A through which the screw 353 is inserted is provided at approximately the center and the lower end side in the vertical direction of the connecting plate 351.
The screw 353 inserted into the screw insertion hole 351A is screwed into a screw hole (not shown) provided in the lower vibration damping box 24, so that the tip surface 311A of the rod 311 is the rotation end of the pendulum member 23. The connecting plate 351 is fixed to the vibration damping box 24 in a state where it can abut against the vibration control box 24. Further, when the column 11 is not inclined due to vibration or the like, the longitudinal direction of the pendulum member 23 substantially coincides with the vertical direction, and when the rod 311 comes into contact with the rotating end portion of the pendulum member 23 in this state, the scale indicating portion 332 indicates 0 cm of the scale portion 331. Thereby, when the column 11 is inclined and the rod 311 is moved, the scale indicating unit 332 indicates a position other than 0 cm, and the visually inspected position indicates that the building 1 is damaged based on the inclination of the column 11. Can be determined.

[Configuration of display section]
The display unit 40 is exposed to the outside on the lower end side of the outer surface material 12 and, as shown in FIG. 1, through a measurement opening formed in the outer surface material 12 and a wall opening 12A as an operation opening. In order to make the measurement result of the displacement measuring device 30 visible, that is, to display the measurement result. As shown in FIGS. 1 and 4, the display unit 40 is formed in a substantially rectangular frame-shaped display frame 41 and a substantially rectangular plate shape slightly smaller than the display frame 41, and can be attached to and detached from one surface of the display frame 41. Window surface member 42.
The display frame 41 is attached around the wall opening 12A in a state where the longitudinal direction substantially coincides with the horizontal direction. An engagement groove 41A is provided in the approximate center of the upper and lower frames of the display frame 41.
The window surface member 42 includes a substantially transparent window portion 42A provided in a horizontally long rectangular shape at a substantially central position. The window part 42 </ b> A is provided at a position where the scale part 331 and the scale instruction part 332 of the displacement measuring device 30 can be seen from the outside of the building 1. Moreover, the part surrounding window part 42A in the window surface member 42 is made into the joint joint part 42B of the color in harmony with the outer surface material 12, for example. Furthermore, an engagement claw portion 42 </ b> C that engages with the engagement groove 41 </ b> A of the display frame 41 is provided at the approximate center of the upper edge and the lower edge of the window surface member 42.

[Decision work for building damage using displacement measuring device]
Next, the determination work of the damage state of the building 1 using the displacement measuring device 30 will be described.
When the scale instruction unit 332 of the displacement measuring device 30 indicates 0 cm, for example, when the building 1 having the wall 10 is deformed by an earthquake or the like and the pillar 11 is inclined, the frame 21 of the vibration damping device 20 is The vertical frame 211 is inclined at an angle substantially equal to that of the pillar 11, and the horizontal frame 212 is displaced so as to be shifted to the left and right to be deformed into a substantially parallelogram shape. When the frame body 21 is deformed into a substantially parallelogram shape in this way, the pair of displacement portions 22 are displaced so as to be separated from each other diagonally up and down. Then, due to the displacement of the displacement portion 22, the pendulum member 23 rotates about the substantially center between the displacement portions 22, and the displacement of the displacement portion 22 is amplified at the end of the pendulum member 23.

  When the pendulum member 23 rotates, the rod 311 is pushed and moves to a position corresponding to the displacement of the pendulum member 23 at the time of maximum rotation. Then, the scale part 331 moves together with the rod 311, and the scale indicating part 332 indicates the position indicating the maximum displacement of the pendulum member 23 in the scale part 331. Further, since the return blocking portion 34 prevents the rod 311 from moving in the returning direction, the rod 311 returns as long as the displacement of the pendulum member 23 does not increase even if a small earthquake occurs thereafter. Does not move in the direction.

  Then, the determiner visually confirms the position indicated by the scale instruction unit 332 and confirms the measurement result, and estimates the displacement of the column 11 based on the measurement result. Thereafter, the determiner determines the damage state of the building 1 based on the displacement of the pillar 11, that is, the inclination angle.

In addition, the determiner performs an operation of adjusting the indication position of the scale indication unit 332 to 0 cm as necessary. Specifically, the scale member is instructed by removing the window member 42 and operating the operation contact portion 315A of the rod operation portion 315 to move the rod 311 until the rod positioning portion 312 contacts the rod holding portion 323. The indicated position of the part 332 is set to 0 cm. Here, since the four operation contact portions 315A are arranged substantially along the axial direction of the rod 311, for example, even when the amount of movement of the rod 311 increases, at least one The operation contact portion 315A is located at a position where it can be seen through the display portion 40, and the rod 311 can be easily moved from the outside.
Thereafter, the determiner attaches the window member 42 to the display frame 41 and finishes the operation.

[Effects of First Embodiment]
According to the first embodiment, the following effects can be obtained.
(1) When the wall 10 of the building 1 vibrates due to an earthquake or the like, the displacement measuring device 30 measures the displacement of the column 11 and causes the display unit 40 to display the measurement result on the outside of the wall 10.
For this reason, even if the displacement of the column 11 at the time of vibration is small, the determiner can confirm the displacement of the column 11 without performing complicated measurement work from the outside of the wall 10, and the damaged state of the building 1. Can be determined with high accuracy.

(2) The pendulum member 23 amplifies the displacement of the displacement portion 22 due to the vibration of the wall 10 and converts it into rotation, and the displacement measuring device 30 measures the displacement at the maximum rotation of the pendulum member 23.
For this reason, the relationship between the amount of rotation of the pendulum member 23 and the displacement of the column 11 is obtained in advance through experiments or the like, so that the amount of rotation amplified by the pendulum member 23 even when the displacement of the column 11 is small. Based on the above, the displacement of the column 11 can be easily and reliably measured. Therefore, it is possible to make a more accurate determination regarding the damaged state of the building 1.

(3) The rod 311 is moved by an amount corresponding to the amount of rotation of the pendulum member 23 by pushing the rod 311 at the rotation end of the pendulum member 23.
For this reason, the displacement of the column 11 can be easily measured by a simple method of simply confirming the amount of movement of the rod 311 by visual observation, for example. Further, the structure of the displacement measuring device 30 can be simplified.

(4) The return blocking portion 34 prevents the rod 311 from returning after being pushed by the pendulum member 23 and moved.
Even if a second earthquake that is smaller than the first earthquake occurs, the rod 311 can be prevented from returning, and the amount of movement of the rod 311 can be set to an amount corresponding to the first earthquake, so that the determination is more accurate. Can be defeated.

(5) Since the measurement unit 33 includes the scale unit 331 and the scale instruction unit 332, the displacement of the pillar 11 can be measured even when power cannot be supplied due to a power failure during a disaster, for example. Convenience can be improved. In addition, since the measurement result can be visually observed through the window portion 42A, the configuration of the displacement measuring device 30 can be simplified.

(6) The rod 311 is provided with an operation contact portion 315A that can be operated through the wall opening 12A of the wall 10.
For this reason, after measuring the displacement of the column 11, by operating the operation contact portion 315A from the outside, the rod 311 can be easily returned to the measurement reference position, and the efficiency of the preparation work for resuming the measurement can be improved. Can be planned.

(7) Since the four operation contact portions 315A are juxtaposed along the movement direction of the rod 311, at least one operation is performed even when the movement amount of the rod 311 increases. The contact portion 315A can be positioned at a position where the operation is easy, and the rod 311 can be easily moved from the outside of the wall 10. Moreover, since the rod 311 can be moved without exposing the operation contact portion 315A to the outside of the wall 10, the design can be improved as compared with the configuration in which the operation contact portion 315A is exposed to the outside.

(8) When the rod 311 is inserted until the rod positioning unit 312 comes into contact with the right end of the rod holding unit 323, the scale instruction unit 332 indicates the 0 cm position (measurement reference position) of the scale unit 331. Provided.
For this reason, the indication position of the scale indication unit 332 can be adjusted to 0 cm by a simple method of moving the rod 311 until the rod positioning unit 312 comes into contact with the rod holding unit 323, and the measurement resumption preparation work is made more efficient. Can be achieved.

[Second Embodiment]
Next, a second embodiment of the present invention will be described.
In the second embodiment, the configurations of the displacement measuring device 60 and the display unit 70 are different from those of the first embodiment, and other configurations are the same as those of the first embodiment. In addition, about the determination operation | work of the damage state of the building 1 using the displacement measuring apparatus 60, since it is the same as that of 1st Embodiment, description is abbreviate | omitted.
FIG. 6 is a diagram illustrating a schematic configuration of the displacement measuring device and the display unit.

[Configuration of displacement measuring device]
As shown in FIG. 6, the displacement measuring device 60 is provided in the vibration damping box 24 on the lower side of the vibration damping device 20, and measures the displacement when the pendulum member 23 is rotated at the maximum. Note that the displacement of the pendulum member 23 at the time of maximum rotation is an amplification of the displacement of the column 11.
The displacement measuring device 60 includes a measurement main body 61, a measurement unit 62, and a positioning unit (not shown).

The measurement main body 61 includes a case 611 having a substantially rectangular box shape. In this case 611, a cylindrical rod holding portion 612 is accommodated.
One end of the rod holding portion 612 protrudes outside the case 611, and the other part is housed inside the case 611. A rod 613 is inserted into the rod holding portion 612 so as to be movable in the axial direction.
One end surface (hereinafter referred to as a tip surface) 613A of the rod 613 contacts the connecting plate 242, that is, the rotating end portion of the pendulum member 23. In addition, a rod cover 614 that covers the rod 613 and expands and contracts as the rod 613 moves is provided in a portion from the vicinity of the tip surface 613A of the rod 613 to the protruding end of the rod holding portion 612.

The measuring unit 62 calculates an amount of movement of the rod 613 based on the electric signal output unit 621 that outputs an electric signal corresponding to the position of the rod 613 relative to the rod holding unit 612 and the electric signal from the electric signal output unit 621. A movement amount calculation unit 622.
The electric signal output unit 621 is housed in the case 611. The movement amount calculation unit 622 is provided in the display case 71 that houses the display unit 70.
When the movement amount calculation unit 622 detects that the rod 613 is larger than a set deflection reference value and exceeds a set reference value, the rod 613 The movement amount calculation process is started. Then, after the lapse of a shake end reference time appropriately set from the last displacement of the rod 613, the movement amount calculation process is ended, and the calculation result is stored for each group of vibrations of the wall 10 (for example, for each earthquake) (not shown). It memorize | stores suitably in a means. Further, the movement amount calculation unit 622 appropriately displays a graph indicating the maximum value of the movement amount, the maximum value for the past several times, or the relationship between the elapsed time and the movement amount on the display unit 70 together with the date and time.

  The positioning unit positions and fixes the case 611 and the horizontal frame 212. Specifically, the positioning unit moves the rod 613 when the tip surface 613A of the rod 613 can contact the rotating end of the pendulum member 23 and the column 11 is not inclined due to vibration or the like. The amount calculation result is fixed at 0 cm.

[Configuration of display section]
The display unit 70 is provided in a state of being exposed to the outside from a display case 71 provided on the lower end side of the outer surface material 12. Here, the display case 71 may be fitted into a hole opened in the outer surface material 12, or may be fixed to the outer surface of the outer surface material 12.
The display unit 70 displays various types of information regarding the amount of movement of the rod 613 in the movement amount calculation unit 622. The display unit 70 is a so-called touch panel, and is operated when setting a swing width reference value, the number of shake detections, a shake end reference time, and the like.
Then, the determiner estimates the displacement of the pillar 11 based on the amount of movement of the rod 613 displayed on the display unit 70 and determines the damage state of the building 1.

[Effects of Second Embodiment]
According to the second embodiment, in addition to the same effects as those of the first embodiment, the following effects can be obtained.
(9) Since the movement amount calculation unit 622 calculates the movement amount of the rod 613 based on the electrical signal, for example, it can be measured with higher precision and can be judged with higher accuracy than a configuration in which measurement is performed visually. .

[Modification of Embodiment]
Note that the present invention is not limited to the first and second embodiments described above, and includes modifications shown below within a range in which the object of the present invention can be achieved.

That is, the displacement of the column 11 was measured by bringing the rods 311 and 613 of the displacement measuring devices 30 and 60 into contact with the rotating end of the pendulum member 23 of the vibration damping device 20 and measuring the amount of rotation of the pendulum member 23. However, the rods 311 and 613 may be directly brought into contact with the column 11 to measure the displacement of the column 11.
The so-called contact-type measurement method that measures the displacement of the column 11 based on the amount of movement of the rods 311 and 613 is used. However, even if a non-contact-type measurement method such as laser light, ultrasonic waves, or image processing is used. Good.
Further, the return measuring unit 34 may not be provided in the displacement measuring device 30. Further, as the return blocking portion 34, for example, a rubber or the like having a large frictional force may be provided on the outer peripheral surface of the rod 311 or the inner peripheral surface of the rod holding portion 323, and the return of the rod 311 may be blocked by this frictional force. .
Further, the scale contact portion 31 may be provided with a scale instruction portion 332, and the measurement holding portion 32 may be provided with a scale portion 331.
The displacement measuring device 30 may not be provided with the rod operation unit 315. Further, only one operation contact portion 315A may be provided. Furthermore, as the operation contact portion, for example, a configuration that extends from the side extension portion 314 and protrudes to the outside from the wall 10 and can be operated from the outside may be applied.

Although the best configuration for carrying out the present invention has been specifically described above, the present invention is not limited to this. That is, the invention has been illustrated and described primarily with respect to particular embodiments, but may be configured for the above-described embodiments without departing from the scope and spirit of the invention. Various modifications and improvements can be made by those skilled in the art in terms of materials, quantity, and other detailed configurations.
The description limited to the shape, material, etc. disclosed above is an example for easy understanding of the present invention, and does not limit the present invention. The description by the name of the member which removes a part or all of the limitation is included in the present invention.

  The present invention can be used for buildings such as houses.

It is a disassembled perspective view of the outer wall panel which comprises the building which concerns on 1st Embodiment of this invention. It is a perspective view which shows the principal part of the outer wall panel in the said 1st Embodiment. It is a disassembled perspective view from the room inner side of the displacement measuring apparatus in the said 1st Embodiment. It is a front view which shows the display part and measurement part in the said 1st Embodiment. It is sectional drawing which shows the return prevention part in the said 1st Embodiment. It is a figure which shows schematic structure of the displacement measuring apparatus and display part which concern on 2nd Embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Building 10 ... Wall 11 ... Pillar as wall component 12A ... Wall opening as measurement opening and operation opening 20 ... Damping device 22 ... Displacement part 23 ... Pendulum member 30, 60 ... Displacement measurement device 33 , 62 ... Measuring part 34 ... Return blocking part 35 ... Positioning part 40, 70 ... Display part 42A ... Window part 241 ... Vibration absorbing member 311 613 ... Rod 315A ... Operation contact part 323, 612 ... Rod holding part 331 ... Scale Unit 332 ... Scale instruction unit 621 ... Electric signal output unit 622 ... Movement amount calculation unit

Claims (7)

A displacement measuring device for measuring a displacement at the time of vibration of the plurality of wall constituent members in a wall constituted by a plurality of wall constituent members;
A display unit that is exposed outside the wall and displays a measurement result of the displacement measuring device; and
Equipped with a,
The wall is provided with a vibration damping device that converts the displacement of the displacement portion that is fixed to the wall and that is displaced by vibration of the wall into rotation of the pendulum member, and prevents the rotation of the pendulum member by the vibration absorbing member. And
The said displacement measuring device measures the displacement at the time of the maximum rotation of the said pendulum member of the said damping device, The building characterized by the above-mentioned . In the building according to claim 1 ,
The displacement measuring device includes a rod that contacts the rotating end of the pendulum member, a rod holding portion that holds the rod so as to be movable back and forth in the axial direction, and a movement amount when the rod is pushed by the pendulum member. A building comprising: a measuring unit for measuring the position; and a positioning unit for positioning the rod holding unit with respect to the vibration damping device. In the building according to claim 2 ,
The displacement measuring device includes a return prevention unit that prevents the rod from returning after the rod is pushed and moved by the pendulum member. In the building according to claim 2 or claim 3 ,
The measurement unit includes a scale part provided on one of the rod and the rod holding part, and a scale instruction part provided on the other side and indicating a predetermined position of the scale part,
The said display part is equipped with the window part provided in the position which can visually observe the said measurement part through the measurement opening part formed by opening in the said wall. The building characterized by the above-mentioned. In the building according to claim 2 or claim 3 ,
The measuring unit outputs an electric signal corresponding to the position of the rod relative to the rod holding unit, and a moving amount calculation for calculating the moving amount of the rod based on the electric signal from the electric signal output unit A building characterized by comprising a part. In building according to claims 2 to claim 5,
The wall is provided with an operation opening formed at a position corresponding to the displacement measuring device,
The said displacement measuring device is provided with the operation contact part integrally provided in the said rod, and can be operated from the exterior of the said wall through the said operation opening part. The building characterized by the above-mentioned. In the building according to claim 6 ,
A plurality of the operation abutting portions are arranged side by side substantially along the moving direction of the rod.

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