JP2016109448A - Interlayer deformation angle measurement device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an interlayer deformation angle measurement device which can be easily installed in a structure.SOLUTION: An interlayer deformation angle measurement device 1A for measuring an interlayer deformation angle of a structure 11 comprises: a displacement measurement unit 4 which is installed on a floor surface (top face) 12a on a first floor slab (first structure part) 12 placed at the lower side of a story being a measurement target of an interlayer deformation angle in the structure 11 and which can measure a relative displacement amount to the floor surface 12a in the horizontal direction; and a support member 6 which is joined to a pillar part (third structure part) 14 joined to the first floor slab 12 and a second floor slab (second structure part) 13 placed at the upper side of the story, respectively and which supports the displacement measurement unit 4 movably along the floor surface 12a.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an interlayer deformation angle measuring apparatus capable of measuring an interlayer deformation angle.

  Conventionally, as a device for measuring the interlayer deformation angle, a light irradiation means such as an optical sensor is installed at the measurement point of the structure, and the light irradiated by the light irradiation means is detected at the position that becomes the reference point with respect to the measurement point There is known a device that installs a light detection means that calculates the deformation angle of a structure from the displacement of irradiation light detected by the light detection means (see, for example, Patent Document 1).

JP 2010-019748 A

  Such an apparatus is large in construction and costly, and there is a problem that it is necessary to secure a space in which irradiation light can be irradiated from the light irradiation means to the light detection means and cannot be easily installed on the structure. is there.

  Then, an object of this invention is to provide the interlayer deformation angle measuring apparatus which can be easily installed in a structure.

  In order to achieve the above object, an interlayer deformation angle measuring apparatus according to the present invention is an interlayer deformation angle measuring apparatus for measuring an interlayer deformation angle of a structure. Installed on the upper surface of the first structure portion disposed in the upper surface of the first structure portion and the floor, and a displacement measuring portion capable of measuring a horizontal relative displacement with the first structure portion. A support member that is joined to a third structure part that is joined to the second structure part, and that supports the displacement measuring part movably along the upper surface of the first structure part.

In the present invention, since the displacement measuring unit is supported by the third structure via the support member, the relative displacement amount with respect to the first structure unit measured by the displacement measuring unit is the third structure unit and the support member. This corresponds to the relative displacement in the horizontal direction between the joint portion and the first structure portion.
For this reason, the interlayer deformation angle of the floor between the first structure portion and the second structure portion can be calculated from the following equation (1).
Interlayer deformation angle θ (rad) = relative displacement σ with the first structure measured by the displacement measurement unit / height from the upper surface of the first structure to the joint between the third structure and the support member h 1.・ Formula (1)

  Since the interlayer deformation angle measuring device has a simple configuration including a displacement measuring unit installed on the upper surface of the first structure unit and a support member for supporting the displacement measuring unit on the third structure unit, Compared to the structure, the construction is easy and the installation space can be reduced. Thereby, an interlayer deformation angle measuring apparatus can be easily installed in a structure.

In the inter-layer deformation angle measuring apparatus according to the present invention, the joint portion between the third structure portion and the support member is above the center portion of the height from the first structure portion to the second structure portion. Preferably it is located.
By setting it as such a structure, the interlayer deformation angle of the floor between the 1st structure part and the 2nd structure part can be calculated more correctly.

In the interlayer deformation angle measuring apparatus according to the present invention, it is preferable that the support member is pin-bonded to the third structure portion.
By setting it as such a structure, the direction of the support member can change centering on a junction part with a 3rd structure part. For this reason, even when the first structure portion and the third structure portion are relatively displaced, the orientation of the support member is changed so that the displacement measurement portion is maintained in a state of being movable along the upper surface of the first structure portion. Therefore, the displacement measuring unit can reliably measure the horizontal relative displacement with the first structure unit without being separated from the first structure unit.

Moreover, in the interlayer deformation angle measuring apparatus according to the present invention, it is preferable to include a pressing portion that presses the displacement measuring portion toward the first structure portion.
By adopting such a configuration, the displacement measuring unit can reliably measure the horizontal relative displacement with respect to the first structure unit without being separated from the first structure unit due to earthquake vibration or the like.

  According to the present invention, the interlayer deformation angle measurement device has a simple configuration including a displacement measurement unit installed on the upper surface of the first structure unit and a support member that supports the displacement measurement unit on the third structure unit. Therefore, compared with the conventional case, the construction can be easily performed on the structure, and the installation space can be reduced. Thereby, an interlayer deformation angle measuring apparatus can be easily installed in a structure.

It is a front view which shows an example of the interlayer deformation angle measuring apparatus by 1st Embodiment of this invention. (A) is the bottom view which looked at A section of Drawing 1 from the lower part, (b) is a side view seen from the B direction of (a), and (c) is a CC line sectional view of (a). It is a flowchart explaining the displacement amount calculation method by 1st Embodiment of this invention. (A) is a front view which shows an example of the interlayer deformation angle measuring apparatus by 2nd Embodiment of this invention, (b) is a top view of (a).

(First embodiment)
Hereinafter, an interlayer deformation angle measuring apparatus according to an embodiment of the present invention will be described with reference to FIGS. 1 and 2.
As shown in FIG. 1, an interlayer deformation angle measuring apparatus 1 </ b> A according to the first embodiment includes a first floor slab (first structure portion) 12 on a floor to be measured for an interlayer deformation angle of a structure 11 and an upper floor thereof. It is arranged between the second floor slab (second structure part) 13.
Here, the floor part (floor base material, floor finishing material, etc.) formed in the upper part of the 1st floor slab 12 shall be fixed to the 1st floor slab 12, and the floor surface (1st structure part) indoors. The upper surface) 12a behaves together with the first floor slab 12. In FIGS. 1 and 2, the upper surface of the first floor slab 12 is shown as a floor surface 12a.
Moreover, the column part (3rd structure) 14 between a 1st floor slab and a 2nd floor slab shall be joined to the 1st floor slab 12 and the 2nd floor slab 13, respectively.

  An interlayer deformation angle measuring apparatus 1A according to the first embodiment includes a support 2 that is movable along a floor surface 12a, a support member 6 that is joined to a pillar portion 14 of a structure 11, and the support 2 and the support member 6. And an urging portion 3 for urging the support 2 toward the floor 12a, and a horizontal relative displacement amount of the support 2 and the floor 12a installed on the support 2 respectively. Three possible displacement measuring units 4, 4, 4, a switch unit 5 for driving the three displacement measuring units 4, 4, 4, and the support 2 measured by the three displacement measuring units 4, 4, 4, respectively. And a processing unit (not shown) for processing the data of the relative displacement amount between the floor surface 12a and the interlayer deformation angle of the structure 11 from the data of the relative displacement amount between the support 2 and the floor surface 12a processed by the processing unit. Power can be supplied to the interlaminar deformation angle calculation unit (not shown) that calculates the angle and the three displacement measurement units 4, 4, and 4. It includes a battery (not shown).

  As shown in FIG. 2, the support 2 has a first plate part 21 whose plate surface is directed in the vertical direction and formed in a substantially equilateral triangular shape in plan view, and a first plate part 21 with an interval between the upper part. A first plate portion 21 disposed between the first plate portion 21 and the second plate portion 22 and a second plate portion arranged in parallel with the first plate portion 21 and having the same outer shape as the first plate portion. And three moving parts 24, 24, 24 that support the connected first plate part 21 and second plate part 22 movably along the floor surface 12 a. And have.

The first plate portion 21 is formed with a hole portion 21a having a substantially circular shape in plan view that penetrates in the center portion in the vertical direction. Also, at the lower part of the first plate part 21, three displacement measuring parts 4, 4, 4 and three moving parts 24, 24, 24 are arranged, and between the lower surface of the first plate part 21 and the floor surface 12a. Is provided with a space.
In the second plate part 22, three corners 22b, 22b, 22b of a substantially equilateral triangle in plan view overlap with three corners 21b, 21b, 21b of a substantially equilateral triangle in plan view of the first plate part 21, respectively. Are arranged as follows. It should be noted that the second plate portion 22 is not formed with a hole portion 21 a like the first plate portion 21.

  The connecting portion 23 is formed in a cylindrical shape whose axial direction is the vertical direction and whose inner diameter is larger than the diameter of the hole 21 a of the first plate portion 21, and the lower end portion is fixed to the upper surface of the first plate portion 21. The portion is fixed to the lower surface of the second plate portion 22. The connecting portion 23 is disposed so that the central axis thereof overlaps with the centers 21 c of the first plate portion 21 and the second plate portion 22 in the vertical direction.

The moving portion 24 has a cylindrical portion 24a whose axial direction is the vertical direction and an upper end fixed to the lower surface of the first plate portion 21, and the floor portion 12a in contact with the floor surface 12a while being inserted into the cylindrical portion 24a. And a moving sphere 24b that can move by rolling along 12a. The cylindrical portion 24a is disposed so that the lower end portion does not contact the floor surface 12a.
Further, in the present embodiment, the three moving parts 24, 24, 24 are arranged at equal intervals in the circumferential direction around the center 21 c of the first plate part 21 with respect to the first plate part 21. The three moving parts 24, 24, 24 are arranged in the vicinity of the three corners 21 b, 21 b, 21 b of the substantially equilateral triangle in the plan view of the first plate part 21, respectively. It is arranged on a line connecting the center 21 c of the one plate portion 21.

  Returning to FIG. 1, the support member 6 is formed as a substantially L-shaped rod-shaped member in a front view. The support member 6 has one end portion 6 a joined to the column portion 14 of the structure 11 and the other end portion 6 b connected to the connecting portion 31 of the biasing portion 3. The joint portion 61 between the support member 6 and the column portion 14 is positioned above the height 1/2 of the height H from the floor surface 12a to the second floor slab 13 (height of the central portion) 1 / 2H. doing.

The support member 6 has one end 6a side extending in the horizontal direction from the substantially L-shaped bent portion 6c, and the other end portion 6b side extends downward from the bent portion 6c from the bent portion 6c.
Further, the support member 6 is configured such that one end portion 6 a is pin-joined to the column portion 14 and the direction thereof can be changed around the junction portion 61 with the column portion 14.
Note that one end portion 6a side of the bent portion 6c of the support member 6 and the other end portion 6b side of the bent portion 6c are rigidly joined at the bent portion 6c.

The urging portion 3 has an upper end portion that is connected to the other end portion 6b of the support member 6 and a second plate portion 22 of the support body 2 that is disposed on the lower side of the connection portion 31 from above. A pressing plate portion 32 and a spring 33 that is disposed between the connecting portion 31 and the pressing plate portion 32 and that can be expanded and contracted in the vertical direction are provided.
The spring 33 has an upper end in contact with the connecting portion 31 and a lower end in contact with the holding plate 32, and urges the support body 2 to the lower side (floor surface 12 a side) via the holding plate 32. Is configured to do.
Thereby, it is prevented that the support body 2 leaves | separates from the floor surface 12a by the vibration of an earthquake.

The three displacement measuring units 4, 4, and 4 are configured by a displacement sensor that can measure the relative displacement between the support 2 and the floor 12a in a plane (substantially in a horizontal plane) along the floor 12a. For example, the three displacement measuring units 4, 4 and 4 are configured by an optical displacement sensor using a bar code reader, an optical mouse, a displacement sensor using an anotopen, a differential transformer type displacement sensor, or the like. Has been.
Further, in the present embodiment, the three displacement measuring units 4, 4, 4 are arranged at equal intervals in the circumferential direction around the center 21 c of the first plate portion 21 with respect to the first plate portion 21. . The three displacement measuring units 4, 4, 4 are arranged between the three moving units 24, 24, 24 and the center 21 c of the first plate unit 21, respectively. Note that the three displacement measuring units 4, 4, 4 may be arranged at the center between the adjacent moving units 24, 24.

  And in this embodiment, the data of the relative displacement amount of the support body 2 and the floor surface 12a measured by the three displacement measuring units 4, 4, 4 are communicated to the processing unit (not shown), and the processing unit The relative displacement amount between the support 2 and the floor 12a is calculated based on the above data. In the interlayer deformation angle measuring apparatus 1A, a communication device for communicating these data from the three displacement measuring units 4, 4 and 4 to the processing unit and three displacement measuring units 4, 4 and 4 respectively measure the data. A storage unit for storing the relative displacement data between the support 2 and the floor 12a, the relative displacement between the support 2 and the floor 12a calculated by the processing unit, and the like are appropriately installed.

When the switch sphere 51 and the switch sphere 51 come into contact with each other, the switch sphere 51 is movable while rotating along the floor surface 12a while being inserted into the hole 21a of the first plate portion 21 of the support 2. And four mechanical switches 52, 52,... For driving the three displacement measuring units 4, 4, 4.
The switch sphere 51 is formed to have a diameter slightly smaller than the inner diameter of the hole 21 a of the first plate portion 21. When the switch sphere 51 is inserted into the hole 21 a of the first plate portion 21, the first plate portion 21 is configured to be movable within the hole 21a. Further, the switch sphere 51 is configured such that when it is inserted into the hole 21 a of the first plate portion 21, the upper side of the first plate portion 21 is inserted inside the connecting portion 23.

Such a switch sphere 51 has a very small mass as compared with the structure 11 and is configured to be displaceable even by minute vibration that does not cause the structure 11 to be displaced (deformed). For this reason, the switch sphere 51 can be displaced even by a minute vibration such that the support 2 supported by the structure 11 does not move, and the support 2 and the switch sphere 51 behave differently due to the minute vibration. It is configured.
Note that the friction coefficient between the switch sphere 51 and the floor surface 12a is smaller than the friction coefficient between the movement sphere 24b of the moving unit 24 and the floor surface 12a, and almost no vibrations such as an earthquake occur. You may be comprised so that it may stay at substantially one point without shaking. When the floor 12a and the support 2 are relatively displaced, the support 2 and the switch sphere 51 may be configured to behave differently.

The mechanical switches 52, 52,... Are arranged at equal intervals along the edge of the hole 21 a of the first plate portion 21.
In such a switch unit 5, the switch sphere 51 inserted in the hole 21 a of the first plate portion 21 of the support 2 and the support 2 is stationary when the earthquake vibration or the like does not occur normally. The spherical body 51 and the mechanical switches 52, 52,... Provided at the edge of the hole 21a of the first plate portion 21 are separated from each other. When the earthquake or the like occurs in the switch unit 5, the switch sphere 51 behaves differently from the support 2 so that one or more of the four mechanical switches 52, 52,. Touch.

In the present embodiment, when the switch sphere 51 comes into contact with any one or more of the four mechanical switches 52, 52,..., Power is supplied from the battery to the three displacement measuring units 4, 4, 4. The three displacement measuring units 4, 4, and 4 are configured to be driven. At this time, if the switch sphere 51 is configured to be displaceable by slight vibration, the switch sphere 51 can come into contact with any one or more of the four mechanical switches 52, 52,. Therefore, the relative displacement amount of the support body 2 and the floor surface 12a can be measured from the state of slight vibration.
The three displacement measuring units 4, 4, and 4 that are being driven are separated from the battery after a predetermined period of time in which the relative displacement amount between the support 2 and the floor surface 12 a not less than a predetermined value is set. The power supply is stopped and the measurement is stopped.

In the present embodiment, the three displacement measuring units 4, 4, 4 that are driven are continuously in 10 seconds when the relative displacement between the measuring support 2 and the floor 12 a is 0 mm. The power supply from the battery is stopped and the measurement is stopped.
In the present embodiment, the power supply from the battery to the three displacement measuring units 4, 4 and 4 is determined according to the signal from the switch unit 5 and the value of the measurement amount measured by the three displacement measuring units 4, 4 and 4. And a control unit (not shown) for controlling the driving and stopping of the three displacement measuring units 4, 4, and 4.

Further, in the present embodiment, the displacement measuring units 4, 4, 4 are supported by the column portion 14 via the support and the support member 6, so that the supports measured by the displacement measuring units 4, 4, 4 respectively. 2 (displacement measuring portion 4) and the floor surface 12a correspond to the horizontal relative displacement amount of the joint portion 61 between the column portion 14 and the support member 6 with respect to the floor surface 12a.
The interlayer deformation angle calculation unit is configured to calculate the interlayer deformation angle of the structure from the following equation based on the relative displacement (described later) between the support 2 and the floor 12a processed by the processing unit. Has been.
Interlayer deformation angle θ (rad) = relative displacement σ between the support 2 and the floor 12a / height from the floor to the junction 61 between the pillar 14 and the support member 6 (1)

  The battery is disposed, for example, between the first plate portion 21 and the second plate portion 22 of the support body 2 or an upper portion of the second plate portion 22. In addition, when the battery is arranged on the upper part of the second plate portion 22, it is easy to replace the battery.

Next, the flowchart shown in FIG. 3 about the processing method by the process part of the data (henceforth data) of the relative displacement amount of the support body 2 and the floor surface 12a which each three displacement measurement part 4,4,4 measured. Based on the explanation.
(Measurement step)
The relative displacement amounts of the support 2 and the floor 12 are respectively measured by the three displacement measuring units 4, 4, and 4 of the displacement measuring apparatus 1 described above (S-1).

(Correction step)
The relative displacement data (hereinafter referred to as data) between the support 2 and the floor 12 measured by the three displacement measuring units 4, 4 and 4 in the measurement step (S-1) are corrected for the axis and used as a reference 1 The time history of two pieces of data other than one piece of data is matched with one piece of reference data (S-2).

(Selection step)
Of the three data whose axes have been corrected in the correction step (S-2), data for the subsequent average value calculation step is selected (S-3).
First, it is determined whether or not the three data are missing (S-4).
If it is determined in this determination (S-3) that there is no missing data, a standard deviation is calculated from the three data (S-5).
Then, it is determined whether or not there is an abnormal value outside the standard deviation range in the data (S-6).
If it is determined in this determination (S-6) that there is no abnormal value outside the standard deviation range, three data are selected (S-7).

If it is determined in this determination (S-6) that the data has an abnormal value outside the standard deviation range, the displacement measuring unit that measured the data outside the standard deviation range in the measurement step (S-1). 4 based on the data measured immediately before the data outside the standard deviation range is measured by 4, the correction data is applied by applying the change of the data measured by the displacement measuring unit 4 that measured the data within the standard deviation range. Is calculated (S-8).
Then, the correction data and data within the standard deviation are selected (S-9).

  Further, in the determination of whether or not the three data are missing (S-4), if there is a missing data, the data that is not missing is selected (S-10).

(Average value calculation step)
Selection process (S7, S9, S10) of the selection step (S-3) The average value of the selected data is calculated, and this average value is used as the relative displacement (representative value) between the support 2 and the floor surface 12. (S-11).

Next, operations and effects of the above-described interlayer deformation angle measuring apparatus 1A will be described with reference to the drawings.
In the interlayer deformation angle measuring apparatus 1A according to the first embodiment described above, the displacement measuring units 4, 4, 4 and the support 2 that supports the displacement measuring units 4, 4, 4 so as to be movable along the floor surface 12a, Since it is the simple structure provided with the support member 6 which supports the support body 2 to the pillar part 14, compared with the past, construction is easy with respect to the structure 11, and installation space can be made small. . Thereby, the inter-layer deformation angle measuring apparatus 1A can be easily installed on the structure 11.

Further, the joint 61 between the support member 6 and the pillar portion 14 is above the height 1/2 of the height H from the floor surface 12a to the second floor slab 13 (height of the central portion) 1 / 2H. By being located at, it is possible to calculate the interlayer deformation angle more accurately.
Further, since the support member 6 is pin-bonded to the column part 14, the support member 6 can change its direction around a joint part 61 with the column part 14. For this reason, even when the floor surface 12a and the column part 14 are relatively displaced, the orientation of the support member 6 is maintained so that the displacement measuring unit 4 (support 2) is maintained movable along the floor surface 12a. Therefore, the displacement measuring unit 4 can reliably measure the relative displacement in the horizontal direction with respect to the floor surface 12a without being separated from the floor surface 12a.

Further, in the interlayer deformation angle measuring apparatus 1A, the three displacement measuring units 4, 4, and 4 are configured to be able to measure the relative displacement amount between the floor surface 12a and the support 2 at different positions. Even when the support body 2 moving along the surface 12a is inclined and partly separated from the floor surface 12a, another displacement measurement unit provided on the side of the support body 2 that is in contact with the floor surface 12a. 4 can reliably measure the relative displacement between the floor surface 12a and the support 2.
Further, the three displacement measuring units 4, 4, 4 are configured to be able to measure the relative displacement amount between the floor surface 12 a and the support 2 at different positions, thereby providing the three displacement measuring units 4, 4, 4. If an average value of a plurality of displacement measurement amounts measured by 4 is used, or if there is an abnormal value among the plurality of displacement measurement amounts measured by the three displacement measurement units 4, 4, 4 respectively, By adopting a relative displacement amount other than or by correcting the abnormal value based on the relative displacement amount other than the abnormal value, the relative displacement amount can be reliably calculated.

(Second Embodiment)
Next, other embodiments will be described with reference to the accompanying drawings. However, the same or similar members and parts as those of the first embodiment described above are denoted by the same reference numerals, and description thereof is omitted. Will be described.
As shown in FIG. 4, the inter-layer deformation angle measuring apparatus 1B according to the second embodiment is provided with a pressing portion 7 for preventing the support body 2 from floating from the floor surface 12a when an earthquake vibration occurs. It has been. FIG. 4B shows a form in which two interlayer deformation angle measuring devices 1 </ b> B are attached to one column portion 14 via support members 6.
The pressing portion 7 has a pair of pressing portion main bodies 71 and 71 on both sides via the support member 6. The holding part main body 71 is disposed on the upper part of the second plate part 22 of the support 2 and extends from the second plate part 22 along the surface of the second plate part 22, and from both ends of the first bar 72. It has a pair of 2nd bar | rods 73 and 73 extended toward the floor surface 12a, and the front-end | tip part contact | abutted with the floor surface.

The first bar 72 is supported on the floor surface 12 a via a pair of second bars 73 and 73. The first bar 72 is in contact with the second plate portion 22 in a relatively movable state, or the first bar 72 is provided with a slight gap between the second plate portion 22 and the first bar 72. ing.
Such a holding | maintenance part 7 is comprised so that the movement of the support body 2 along the floor surface 12a is accept | permitted, and the movement of the support body 2 of the direction (up-down direction) spaced apart from the floor surface 12a is restrained.

  According to the inter-layer deformation angle measuring apparatus 1B according to the second embodiment, the same effect as that of the first embodiment can be obtained, and by providing the pressing portion 7, the support 2 can be brought into contact with the floor 12a due to earthquake vibration or the like. The displacement measuring unit 4 can reliably measure the relative displacement in the horizontal direction with the floor surface 12a.

As mentioned above, although the embodiment of the deformation angle measuring device according to the present invention has been described, the present invention is not limited to the above-described embodiment, and can be appropriately changed without departing from the gist thereof.
For example, in the above-described embodiment, the interlayer deformation angle measuring devices 1A and 1B are configured such that the support 2 is movable on the floor surface 12a, but the upper surface of the equipment disposed on the floor surface 12a, the upper surface of the beam The first floor slab 12 may be configured to be movable in the horizontal direction along the upper surface or the like.
In the above embodiment, the support member 6 is joined to the column part 14, but the wall of the structure 11 joined to the first floor slab 12 and the second floor slab 13 instead of the pillar part 14. It may be joined to a part or the like. Further, the column part 14 and the wall part to which the support member 6 is joined are arranged on the lower side of the floor for measuring the interlayer deformation angle, instead of the first floor slab 12 and the second floor slab 13 of the structure. It may be joined to the beam material and the beam material arranged on the upper side.

Moreover, in said embodiment, the junction part 61 of the supporting member 6 and the pillar part 14 is 1/2 height (height of a center part) of the height H from the floor surface 12a to the 2nd floor slab 13. Although it is located above 1 / 2H, it is located below the height 1/2 of the height H from the floor surface 12a to the second floor slab 13 (height at the center) 1 / 2H or less. Also good.
Further, in the above embodiment, the support member 6 is pin-bonded to the column portion 14, but may not be pin-bonded.

In the above-described embodiment, three displacement measuring units 4 are provided in the interlayer deformation angle measuring apparatuses 1A and 1B. However, one, two, four or more may be provided. When only one displacement measuring unit 4 is provided, the interlayer deformation angle may be measured based on the amount of displacement measured by one displacement measuring unit 4 without providing a processing unit. . When only one displacement measuring unit 4 is provided, the displacement measuring unit 4 itself may be configured to be movable along the floor surface 12a without providing the support 2.
Moreover, in said embodiment, although the installation number of the displacement measurement part 4 and the installation number of a moving part are the same, you may differ.
Further, the positions where the plurality of displacement measuring units 4 are arranged may be set as appropriate.
Moreover, the processing method of the data of the displacement amount measured by the plurality of displacement measuring units 4 may be set as appropriate.

In the above embodiment, the switch unit 5 is provided. However, the switch unit 5 may not be provided, and the plurality of displacement measuring units 4 may be configured to always measure the displacement amount. Further, the form of the switch unit 5 may be other than the above form. In the above embodiment, the position, number, and form of the mechanical switch 52 may be set as appropriate.
Further, in the above embodiment, the interlayer deformation angle measuring devices 1A and 1B are provided with a battery capable of supplying power to the plurality of displacement measuring units 4, but such a battery is not provided. You may be comprised so that a power supply may be supplied to the several displacement measurement part 4 from the power supply device provided in the structure.

In the above embodiment, the urging unit 3 is provided, but it may not be provided.
In the above-described embodiment, the moving unit 24 includes the cylindrical part 24a and the moving sphere 24b. However, instead of the cylindrical part 24a and the moving sphere 24b, for example, the entire surface on the floor 12a is used. It is good also as a form which has a wheel etc. which can move to a direction.

  In the above-described embodiment, the support 2 includes the first plate portion 21 and the second plate portion 22 that are formed in a substantially equilateral triangular shape or a substantially cross shape in plan view. The shape of 21 and the 2nd board part 22 may be shapes other than the above. Further, the support 2 is supported by the support member 6 and can move on the floor surface 12a. If the support 2 is configured to be able to support the plurality of displacement measuring units 4, the first plate unit 21 and the second plate unit are provided. A member in place of 22 may be provided.

Further, in the above-described embodiment, the switch sphere 51 is configured to move on the floor surface 12a in contact with the floor surface 12a, but a plate material is provided in which the plate surface faces in the vertical direction. The switch sphere 51 may be configured to move on the plate material. In addition, this board | plate material may be supported by the structure 11, and may be supported by the support body 2. FIG.
Further, in the above embodiment, when an optical sensor is used for the displacement measuring unit 4, the displacement measuring unit 4 is surrounded in order to maintain the brightness of the space in which the displacement measuring unit 4 is installed uniformly. Such a cover body may be provided. Further, a cover member may be provided in order to prevent dust and the like from being mixed between the displacement measuring unit 4 and the floor surface 12a.

DESCRIPTION OF SYMBOLS 1A, 1B Interlayer deformation angle measuring apparatus 2 Support body 3 Energizing part 4 Displacement measuring part 5 Switch part 6 Supporting member 7 Holding part 11 Structure 12 First floor slab (1st structure part)
12a Floor (upper surface)
13 Second floor slab (second structure)
14 Column (third structure)

Claims (4)

In an interlaminar deformation angle measuring device for measuring an interlaminar deformation angle of a structure,
Displacement measuring unit that is installed on the upper surface of the first structure unit arranged below the floor to be measured for the interlayer deformation angle of the structure and that can measure the horizontal relative displacement with the first structure unit When,
Joined to the first structure part and the third structure part respectively joined to the second structure part arranged on the upper side of the floor, and supports the displacement measuring part movably along the upper surface of the first structure part An inter-layer deformation angle measuring device.   The joint portion between the third structure portion and the support member is located above a central portion of the height from the first structure portion to the second structure portion. The interlayer deformation angle measuring device described.   The interlayer deformation angle measuring apparatus according to claim 1, wherein the support member is pin-bonded to the third structure portion.   The interlayer deformation angle measuring apparatus according to any one of claims 1 to 3, further comprising a pressing unit that presses the displacement measuring unit toward the first structure unit.

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