JP7042145B2 - Test equipment using a seismic isolation damper test fixing jig and a seismic isolation damper test fixing jig - Google Patents

Description

The present invention is used, for example, in a seismic isolation structure of a building, and is used for a joint portion between H-shaped steel and H-shaped steel which is a column, or a joint portion between a brace and H-shaped steel which is a column. For example, the present invention relates to a test fixing jig for a seismic isolation damper for absorbing an impact caused by shaking such as an earthquake, and a test device using a test fixing jig for the seismic isolation damper.

More specifically, such a seismic isolation damper has a structure as shown in FIG. 7.

That is, as shown in the perspective view of FIG. 7, the seismic isolation damper 100 includes, for example, a rectangular inner plate-shaped body 102 made of a steel plate, and for example, sticky on both surfaces of the inner plate-shaped body 102. A pair of rectangular rubber members 104 made of elastic seismic isolation rubber are provided.

Further, a pair of outer plate-shaped bodies 106 are provided on the outside of these rubber members 104. Further, as shown in FIG. 7, one end 108a of the inner plate-like body 102 is longitudinally longer than one end portion 104a of the rubber member 104 and one end portion 106a of the outer plate-like body 106. It has a protruding structure. A plurality of mounting bolt holes 110 are provided in one of the fixing protrusions 108 of the inner plate-shaped body 102.

On the other hand, the other end portion 106b of the outer plate-shaped body 106 has a structure that protrudes in the longitudinal direction from the other end portion 102b of the inner plate-shaped body 102 and the other end portion 104b of the rubber member 104. A plurality of mounting bolt holes 114 are provided in the other fixing protrusion 112 of the outer plate-shaped body 106.

A seismic isolation damper 100 having such a structure is used, for example, by using a test device as disclosed in Patent Document 1 (Japanese Patent Laid-Open No. 2005-3379), Patent Document 2 (Japanese Patent Laid-Open No. 2003-207430), and the like. Then, mounting bolts are attached to the plurality of mounting bolt holes 110 of the protruding portion 108 of the inner plate-shaped body 102 to be fixed to one grip portion of the test device, and the protruding portion 112 for fixing the outer plate-shaped body 106 is fixed. Mounting bolts are mounted in a plurality of mounting bolt holes 114 and fixed to the other grip portion of the test device so that a test such as a vibration test is performed.

Japanese Unexamined Patent Publication No. 2005-3379 Japanese Unexamined Patent Publication No. 2003-207430

By the way, in the seismic isolation damper 100 having such a structure, the thickness of the rubber member 104 is not uniform and varies due to the variation in processing accuracy, so that the pair of outer plate-like bodies 106 may not be parallel to each other.

Therefore, in the seismic isolation damper 100 having such a structure, a deviation in the thickness direction (arrow A direction, that is, the separation distance direction) in FIG. 7 may occur. For example, although not shown, the pair of outer plate-shaped bodies 106 may have a figure eight shape or an inverted figure eight shape in a cross-sectional view.

Further, in the seismic isolation damper 100 having such a structure, a deviation in the twisting direction (arrow B direction) in FIG. 7 and a deviation in the rotation direction (arrow C direction) in FIG. 7 may occur.

Therefore, when the seismic isolation damper 100 having such a deviation is to be sandwiched and fixed by a mounting jig, the deviation of the seismic isolation damper 100 may be corrected.

If the test is performed with these deviations of the seismic isolation damper 100 corrected (corrected) by the mounting jig in this way, the test data will be far from the actual test result of the seismic isolation damper 100, and the test data will be accurate. I can't do the test.

Therefore, in the conventional test apparatus, as in Patent Document 1, such a deviation of the seismic isolation damper 100 is corrected by sandwiching a correction member such as a shim material or a feeler gauge between the mounting jigs. Is designed to prevent.

However, depending on the size and type of these deviations of the seismic isolation damper 100, shim materials having a plurality of dimensions and shapes must be prepared and used alone or in combination, which is complicated. It requires a lot of work, takes time and effort, and increases the test cost.

In view of such a situation, the present invention can fix the seismic isolation damper to the test fixing jig while the seismic isolation damper is not corrected and the seismic isolation damper is displaced. Testing using a seismic isolation damper test fixing jig and a seismic isolation damper test fixing jig that can perform accurate tests without the test data being far from the test results of the seismic isolation damper. The purpose is to provide the device.

Further, the present invention does not require a correction member such as a shim material or a feeler gauge as in the past, can reduce cost and labor, and can easily attach a seismic isolation damper to a test fixing jig, and has an mounting accuracy. To provide a test fixing jig for a seismic isolation damper and a test device using a test fixing jig for a seismic isolation damper, which have no variation and non-linear factors due to rattling do not affect the test results. The purpose.

The present invention has been invented in order to achieve the above-mentioned problems and objects in the prior art, and the test fixing jig for the seismic isolation damper of the present invention is used.
A test fixing jig for a seismic isolation damper composed of an inner plate-shaped body, a pair of rubber members provided on both sides of the inner plate-shaped body, and a pair of outer plate-shaped bodies provided on the outside of the rubber member. There,
It is provided with a pair of fixing jig members that are erected on the base plate, arranged in a state of being separated from each other, and configured to sandwich and fix the fixing protrusions of the outer plate-like body of the seismic isolation damper.
Each of the fixing jig members
The fixing nut fixed on the base plate and
A jig strut mounted on the fixing nut via a pressure nut,
The jig body fixed to the upper part of the jig support and
The jig main body is provided with a fixing member rotatably mounted via a rotation shaft arranged in a horizontal direction so as to be parallel to the outer plate-like body of the seismic isolation damper .
A fastening bolt hole is formed in the fixing member so as to correspond to a mounting bolt hole formed in the fixing protrusion of the outer plate-shaped body of the seismic isolation damper.
The dimension X1 of the inner diameter of the fastening bolt hole is configured to be larger than the dimension X2 of the outer diameter of the fastening bolt.
The inner diameter of the pressure nut Y1 is larger than the outer diameter Y2 of the jig strut mounted via the pressure nut.

With this configuration, the fixing member can rotate via a rotating shaft arranged in the horizontal direction so as to be parallel to the outer plate-shaped body of the seismic isolation damper in the jig main body. Since it is mounted on the, the fixing member rotates about the rotation axis.

As a result, when a deviation occurs in the thickness direction (arrow A direction, that is, the separation distance direction) in FIG. 7, for example, the pair of outer plate-shaped bodies 106 may have a figure eight shape in a cross-sectional view. It is possible to absorb the state of being in the shape of an inverted eight.

Further, the fixing bolt hole is formed in the fixing member so as to correspond to the mounting bolt hole formed in the fixing protrusion of the outer plate-shaped body of the seismic isolation damper.

Further, since the dimension X1 of the inner diameter of the fastening bolt hole is larger than the dimension X2 of the outer diameter of the fastening bolt and has a clearance, the deviation in the rotation direction (arrow C direction) in FIG. 7 is absorbed. be able to.

Further, since the dimension Y1 of the inner diameter of the pressure nut is larger than the dimension Y2 of the outer diameter of the jig support mounted via the pressure nut and has a clearance, the twisting direction in FIG. 7 is obtained. The deviation (direction of arrow B and direction of arrow A) can be absorbed.

Therefore, the seismic isolation damper 100 can be fixed to the test fixing jig while the seismic isolation damper 100 is not corrected and the seismic isolation damper 100 is displaced, and the actual seismic isolation damper 100 is tested. It is possible to perform an accurate test without the test data being far from the result.

In addition, there is no need for correction members such as shim materials and feeler gauges as in the past, cost and labor can be reduced, and the seismic isolation damper 100 can be easily attached to the test fixing jig, resulting in variations in mounting accuracy. No, non-linear factors due to rattling do not affect the test results.

Further, the fixing jig for testing the seismic isolation damper of the present invention is
Each of the fixing jig members
Through the fastening nut in which the fastening nut hole is formed so as to correspond to the mounting bolt hole formed in the fixing protrusion of the outer plate-shaped body of the seismic isolation damper.
The fastening bolt is configured to fasten the fixing protrusion of the outer plate-shaped body of the seismic isolation damper.

With this configuration, the protrusion for fixing the outer plate-shaped body of the seismic isolation damper can be fastened by the fastening bolt via the fastening nut in which the fastening nut hole is formed. The seismic isolation damper 100 can be easily attached and firmly fixed in a state where the deviation in the direction (direction of arrow C) is absorbed.

Further, the fixing jig for testing the seismic isolation damper of the present invention is
Each of the fixing jig members
It is characterized by including a rotation fixing portion for fixing the rotation of the rotation shaft of the fixing member.

With this configuration, each fixing jig member includes a rotation fixing portion for fixing the rotation of the rotation shaft of the fixing member, so that the fixing member rotates about the rotation shaft. It can be fixed in the prevented state.

As a result, when a deviation occurs in the thickness direction (arrow A direction, that is, the separation distance direction) in FIG. 7, for example, the pair of outer plate-shaped bodies 106 may have a figure eight shape in a cross-sectional view. The seismic isolation damper 100 can be attached in a state of absorbing the inverted eight-shaped state.

Further, the fixing jig for testing the seismic isolation damper of the present invention is
The rotation fixing part
The flange portion erected on the jig body and the flange portion
A shaft hole formed in the flange portion and into which the rotation shaft of the fixing member is inserted,
The slit formed in the shaft hole and
A tightening bolt that tightens the slit,
It is characterized by having.

With this configuration, the fixing member 36 can be fixed in a state where the fixing member is prevented from rotating about the rotation shaft only by tightening the tightening bolt and tightening the slit.

As a result, when a deviation occurs in the thickness direction (arrow A direction, that is, the separation distance direction) in FIG. 7, for example, the pair of outer plate-shaped bodies 106 may have a figure eight shape in a cross-sectional view. The seismic isolation damper 100 can be attached in a state of absorbing the inverted eight-shaped state.

Further, the test apparatus of the present invention is characterized in that it is configured to perform a test by using the test fixing jig of the seismic isolation damper described in any of the above.

According to the present invention, the fixing member is rotatably attached to the jig main body via a rotating shaft arranged in the horizontal direction so as to be parallel to the outer plate-shaped body of the seismic isolation damper. Therefore, the fixing member rotates about the rotation axis.

As a result, when the deviation in the thickness direction (arrow A direction) of FIG. 7 occurs, for example, in the cross-sectional view, the pair of outer plate-shaped bodies 106 becomes a figure eight shape or an inverted figure eight shape. It is possible to absorb the state that has become.

Further, the fixing bolt hole is formed in the fixing member so as to correspond to the mounting bolt hole formed in the fixing protrusion of the outer plate-shaped body of the seismic isolation damper.

Further, since the dimension X1 of the inner diameter of the fastening bolt hole is larger than the dimension X2 of the outer diameter of the fastening bolt and has a clearance, the deviation in the rotation direction (arrow C direction) in FIG. 7 is absorbed. be able to.

Further, since the dimension Y1 of the inner diameter of the pressure nut is larger than the dimension Y2 of the outer diameter of the jig strut mounted via the pressurizing nut and has a clearance, the twist in FIG. 7 is obtained. It is possible to absorb the deviation in the direction (direction of arrow B and direction of arrow A).

Therefore, the seismic isolation damper 100 can be fixed to the test fixing jig while the seismic isolation damper 100 is not corrected and the seismic isolation damper 100 is displaced, and the actual seismic isolation damper 100 is tested. It is possible to perform an accurate test without the test data being far from the result.

In addition, there is no need for correction members such as shim materials and feeler gauges as in the past, cost and labor can be reduced, and the seismic isolation damper 100 can be easily attached to the test fixing jig, resulting in variations in mounting accuracy. No, non-linear factors due to rattling do not affect the test results.

FIG. 1 is a perspective view of a test fixing jig for the seismic isolation damper of the present invention. FIG. 2 is a perspective view illustrating a state in which the seismic isolation damper is fixed by using the test fixing jig for the seismic isolation damper of the present invention. FIG. 3 is a cross-sectional view taken along the line I-I of FIG. FIG. 4 is a partially enlarged cross-sectional view of FIG. FIG. 5 is a schematic view showing an example in which the test fixing jig 10 of the present invention is applied to a test apparatus for performing a vibration test as an example of a test. FIG. 6 is a front view illustrating a usage state of the test apparatus main body of FIG. FIG. 7 is a perspective view showing the structure of the seismic isolation damper.

Hereinafter, embodiments (examples) of the present invention will be described in more detail with reference to the drawings.
(Example 1)

FIG. 1 is a perspective view of a test fixing jig for the seismic isolation damper of the present invention, and FIG. 2 is a perspective view illustrating a state in which the seismic isolation damper is fixed using the test fixing jig for the seismic isolation damper of the present invention. FIG. 3 is a cross-sectional view taken along the line I-I of FIG. 3, and FIG. 4 is a partially enlarged cross-sectional view of FIG.

In FIGS. 1 to 4, reference numeral 10 indicates a test fixing jig for the seismic isolation damper of the present invention (hereinafter, simply referred to as “test fixing jig”).

As shown in FIGS. 2 and 3, the test fixing jig 10 of the present invention fixes the other fixing protrusion 112 side of the outer plate-shaped body 106 of the seismic isolation damper 100 having the structure shown in FIG. It is configured to do.

As shown in FIGS. 1 to 3, the test fixing jig 10 of the present invention includes a base plate 12. A pair of fixing jig members erected on the base plate 12, arranged in a state of being separated from each other, and configured to sandwich and fix the fixing protrusion 112 of the outer plate-shaped body 106 of the seismic isolation damper 100. It is equipped with 14.

Further, the fixing jig member 14 includes a fixing nut 16 fixed on the base plate 12. In this embodiment, as shown in FIG. 3, one fixing nut 16 common to the left and right fixing jig members 14 is fixed. Reference numeral 11 indicates a fixing bolt hole for fixing the base plate to the grip portion of the test device.

Further, as shown in FIGS. 3 and 4, the fixing nut 16 is formed with two fixing hole portions 18 so as to correspond to the left and right fixing jig members 14. A female screw 21 is formed on the inner circumference of the fixing hole 18.

Further, the test fixing jig 10 of the present invention is provided with two pressure nuts 20 so as to correspond to the left and right fixing jig members 14. A male screw 22 is formed on the outer periphery of the pressure nut 20, and is configured to be screwed with a female screw 21 formed on the inner circumference of the fixing hole 18 of the fixing nut 16. There is.

Further, the pressure nut 20 is formed with an insertion hole 24 so as to correspond to the fixing hole portion 18 of the fixing nut 16.

Further, the strut portion 28 of the jig strut 26 is inserted into the fixing hole portion 18 of the fixing nut 16, and the enlarged diameter portion 29 at the lower end of the jig strut 26 is erected so as to be seated on the base plate 12. Has been done.

Then, as shown in FIGS. 3 and 4, by tightening the pressure nut 20, the jig support column 26 is fixed to the fixing nut 16 via the pressure nut 20.

Further, as shown in FIGS. 1 to 2, a jig main body portion 30 having a substantially U-shape is fixed to the upper portion of the support column portion 28 of the jig support column 26.

The jig body 30 includes a jig body bottom 32 and two flanges 34 extending upward from both ends of the jig body bottom 32. Between these flange portions 34, the fixing member 36 is arranged horizontally so as to be parallel to the outer plate-shaped body 106 of the seismic isolation damper 100 , as shown by the arrow D in FIG. It is rotatably mounted via a rotating shaft 38. Further, a rotation fixing portion 40 for fixing the rotation of the rotation shaft of the fixing member 36 is provided.

Specifically, as the rotation fixing portion 40, as shown in FIGS. 1 to 2, a shaft hole 41 for inserting the rotation shaft 38 of the fixing member 36 is formed in these flange portions 34. There is. Further, the shaft hole 41 is formed with a slit 42 and is provided with a tightening bolt 44 for tightening the slit 42.

With this configuration, the fixing member 36 is placed on the jig main body 30 via a rotating shaft 38 horizontally arranged so as to be parallel to the outer plate-shaped body 106 of the seismic isolation damper 100. As shown by the arrow D in FIG. 2, the fixing member 36 rotates about the rotation shaft 38, and the tightening bolt 44 is tightened to tighten the slit 42. Therefore, the fixing member 36 can be fixed in a state where the fixing member 36 is prevented from rotating around the rotation shaft 38.

Further, the inner diameter Y1 of the pressure nut 20 is larger than the outer diameter Y2 of the support column 28 of the jig support column 26 mounted via the pressure nut 20, and the clearance T2 is formed. Therefore, there is a degree of freedom in the XY plane of FIG.

As a result, when a deviation occurs in the thickness direction (arrow A direction, that is, the separation distance direction) in FIG. 7, for example, the pair of outer plate-shaped bodies 106 may have a figure eight shape in a cross-sectional view. The seismic isolation damper 100 can be attached in a state of absorbing the inverted eight-shaped state.

Therefore, it is possible to finely adjust the angle of the pair of outer plate-shaped bodies 106 and the separation distance in the X direction (arrow A direction) in FIGS. 3 and 4.

Further, in the test fixing jig 10 of the present invention, as shown in FIGS. 3 and 4, the fixing member 36 is formed on the fixing protrusion 112 of the outer plate-shaped body 106 of the seismic isolation damper 100. A fastening bolt hole 46 is formed so as to correspond to the mounting bolt hole 114.

The inner diameter X1 of the fastening bolt hole 46 is larger than the outer diameter X2 of the fastening bolt 52, and the clearance T1 is formed.

Further, since the dimension X1 of the inner diameter of the fastening bolt hole 46 is larger than the dimension X2 of the outer diameter of the fastening bolt 52 and the clearance T1 is formed, there is a degree of freedom in the YZ plane of FIG.

Further, as shown in FIGS. 1, 3, and 4, the inside of the fixing member 36 corresponds to the mounting bolt hole 114 formed in the fixing protrusion 112 of the outer plate-shaped body 106 of the seismic isolation damper 100. As such, a substantially plate-shaped fastening nut 50 having a fastening nut hole 48 formed therein is provided.

As a result, the fixing protrusion 112 of the outer plate-shaped body 106 of the seismic isolation damper 100 can be fastened by the fastening bolt 52 via the fastening nut 50 in which the fastening nut hole 48 is formed. There is.

With this configuration, the fixing protrusion 112 of the outer plate-shaped body 106 of the seismic isolation damper 100 can be fastened by the fastening bolt 52 via the fastening nut 50 in which the fastening nut hole 48 is formed. Therefore, the seismic isolation damper 100 can be easily attached and firmly fixed in a state where the deviation in the rotation direction (arrow C direction) of FIGS. 2 to 4 and 7 is absorbed.

Thereby, the deviation in the rotation direction (arrow C direction) of FIGS. 2 to 4 and 7 can be absorbed.

Further, as shown in FIGS. 3 and 4, the inner diameter Y1 of the pressure nut 20 is larger than the outer diameter Y2 of the support column 28 of the jig support column 26 mounted via the pressure nut 20. It is configured and a clearance T2 is formed.

As a result, the degree of freedom of the XY plane of FIG. 4 is obtained, and the twisting direction (arrow B direction) of FIGS. 2 to 4 and 7 and the thickness direction of FIG. 7 (arrow A direction, that is, the separation distance) are obtained. It can absorb the deviation of the direction).

Therefore, according to the test fixing jig 10 of the present invention, the seismic isolation damper 100 is used as a test fixing jig while the seismic isolation damper 100 is not corrected and the seismic isolation damper 100 is displaced. It can be fixed to 10 and an accurate test can be performed without the test data being far from the actual test result of the seismic isolation damper 100.

In addition, there is no need for correction members such as shim materials and feeler gauges as in the past, cost and labor can be reduced, and the seismic isolation damper 100 can be easily attached to the test fixing jig 10 and the mounting accuracy varies. There is no, and non-linear factors due to rattling do not affect the test results.
(Example 2)

FIG. 5 is a schematic view showing an example in which the test fixing jig 10 of the present invention is applied to a test device for performing a vibration test as an example of a test, and FIG. 6 shows a usage state of the test device main body of FIG. It is a front view to explain.

In FIG. 5, reference numeral 10 indicates the test apparatus of the present invention as a whole.

As shown in FIGS. 5 to 6, the test apparatus 200 of the present invention includes a test apparatus main body 202 for performing a test.

In this embodiment, the test device main body 202 is composed of a test device that performs a vibration test as an example of the test.

As shown in FIG. 5, the test apparatus main body 202 includes a gantry frame 204, and an actuator 206 composed of a cylinder is provided below the gantry frame 204. The actuator 206 includes a piston 208 for mounting a test piece P made of a seismic isolation damper 100 fixed by the test fixing jig 10 of the present invention, and a displacement detector 210 for detecting displacement. ing.

Further, an upper frame 218 is erected above the gantry frame 204, and the upper frame 218 is provided with a guide rod 212 between the upper frame 218 and the gantry frame 204.

A ball screw 214 is provided between the lower part of the guide rod 212 and the upper frame 218, and a crosshead 216 that can move up and down with respect to the piston 208 is provided by the ball screw 214. Further, the crosshead 216 is provided with a load detector 220 so as to face the piston 208.

Further, as shown in FIG. 5, the test device 200 of the present invention is connected to the test device main body 202 to set and execute test conditions and collect test data for the test device main body 202. It is provided with a control device 222 that functions as a test control device for the above.

In this embodiment, the control device 222 includes a CRT 224 for displaying a setting screen such as test conditions, test data, and the like, a control device main body 226, a keyboard 228, and a mouse 230. Therefore, the control device 222 has a built-in internal memory composed of, for example, a hard disk. A personal computer for operation may be connected to the control device main body 226.

Then, the displacement detector 210 of the actuator 206 of the test device main body 202 and the control device main body 226 are connected, and the load detector 220 of the test device main body 202 and the control device main body 226 are connected.

Further, as shown in FIG. 5, in the test device 200 of this embodiment, in the control device main body 226 of the control device 222, for example, an external analysis device 232 made of a personal computer is provided with a communication line (for example, LAN, GPIB, etc.). It is connected via. Similar to the control device 222, the external analysis device 232 includes a CRT 236 for displaying test conditions, test data, and the like, an external analysis device main body 238, a keyboard 240, and a mouse 242.

On the other hand, in the test device 200 of the present invention, an actuator drive source 234 connected to the control device main body 226 of the control device 222 and connected to the actuator 206 of the test device main body 202 is provided.

In the test apparatus 200 of the present invention configured as described above, the test is performed as follows.

That is, as shown in FIG. 6, the test piece P is placed on the upper surface of the piston 208, and the crosshead 216 is lowered with respect to the piston 208 by the ball screw 214 by a drive mechanism (not shown) to reduce the piston 208. The test piece P is sandwiched between the upper surface and the lower surface of the crosshead 216.

Then, based on the program stored in advance in the control device 222, the setting of the test conditions and the like, the execution, and the collection of the test data are performed.

That is, as shown in FIG. 5, the actuator drive source 234 connected to the control device 222 is driven under a predetermined condition by the control of the control device 222. As a result, the actuator 206 connected to the actuator drive source 234 is driven under predetermined conditions to give a constant vibration to the test piece P.

Then, the displacement of the test piece P is detected by the displacement detector 210 provided in the actuator 206, and the displacement data of the test piece P is input to the control device main body 226 of the control device 222. On the other hand, the load detector 220 provided on the crosshead 216 detects the load applied to the test piece P, and the load data applied to the test piece P is input to the control device main body 226 of the control device 222. There is.

Further, based on these test data, a feedback command signal is output from the control device 222 to the actuator drive source 234 based on the program of the control device main body 226 of the control device 222, and the actuator drive source 234 is set under predetermined conditions. It is designed to be driven.

Although the preferred embodiment of the present invention has been described above, the present invention is not limited to this. For example, in the above embodiment, as shown in FIG. 3, the left and right fixing jig members 14 are used. One common fixing nut 16 is fixed, and the fixing nut 16 is configured so that two fixing holes 18 are formed so as to correspond to the left and right fixing jig members 14.

However, two separate fixing nuts 16 are fixed to the left and right fixing jig members 14, and one fixing nut 16 is attached to the fixing nut 16 so as to correspond to the left and right fixing jig members 14. The fixing hole 18 may be formed.

Further, in the above-mentioned Examples, an Example in which the test fixing jig 10 of the present invention is applied to a test device for performing a vibration test as an example of a test has been described, but a material test, a vibration test, a fatigue test, and a characteristic test have been described. Various changes can be made without departing from the object of the present invention, such as being applicable to various test devices such as a material test device, a vibration test device, and a fatigue test device for performing the above.

The present invention is used, for example, in a seismic isolation structure of a building, and is used for a joint portion between H-shaped steel and H-shaped steel which is a pillar, or a joint portion between a brace and H-shaped steel which is a pillar. For example, it can be applied to a test fixing jig for a seismic isolation damper for absorbing an impact caused by shaking such as an earthquake, and a test device using a test fixing jig for a seismic isolation damper.

10 Testing fixing jig 11 Fixing bolt hole 12 Base plate 14 Fixing jig member 16 Fixing nut 18 Fixing hole 20 Pressurizing nut 21 Female screw 22 Male screw 24 Insertion hole 26 Jig post 28 Strut part 39 Enlarged part 30 Jig body 32 Jigger body bottom 34 Flange 36 Fixing member 38 Rotating shaft 40 Rotating fixing 41 Shaft hole 42 Slit 44 Bolt 46 Fastening bolt hole 48 Fastening nut hole 50 Fastening nut 52 Fastening bolt 100 Seismic isolation damper 102 Inner plate-like body 102b End portion 104 Rubber member 104a, 104b End portion 106 Outer plate-like body 106a, 106b End portion 108 Fixing protrusion 108 Protrusion portion 108a End portion 110 Mounting bolt hole 112 Fixing protrusion 114 Mounting bolt hole 200 Test equipment 202 Test equipment body 204 Mount frame 206 Actuator 208 Piston 210 Displacement detector 212 Guide rod 214 Ball screw 216 Crosshead 218 Upper frame 220 Load detector 222 Control device 226 Control device body 228 Keyboard 230 Mouse 232 External analyzer 234 Actuator drive Source 238 External analyzer body 240 Keyboard 242 Mouse A Separation distance direction B Arrow direction C Rotation direction D Arrow P Test piece T1 Clearance T2 Clearance X1 Dimension X2 Dimension Y1 Dimension Y2 Dimension

Claims (5)

A test fixing jig for a seismic isolation damper composed of an inner plate-shaped body, a pair of rubber members provided on both sides of the inner plate-shaped body, and a pair of outer plate-shaped bodies provided on the outside of the rubber member. There,
It is provided with a pair of fixing jig members that are erected on the base plate, arranged in a state of being separated from each other, and configured to sandwich and fix the fixing protrusions of the outer plate-like body of the seismic isolation damper.
Each of the fixing jig members
The fixing nut fixed on the base plate and
A jig strut mounted on the fixing nut via a pressure nut,
The jig body fixed to the upper part of the jig support and
The jig main body is provided with a fixing member rotatably mounted via a rotation shaft arranged in a horizontal direction so as to be parallel to the outer plate-like body of the seismic isolation damper .
A fastening bolt hole is formed in the fixing member so as to correspond to a mounting bolt hole formed in the fixing protrusion of the outer plate-shaped body of the seismic isolation damper.
The dimension X1 of the inner diameter of the fastening bolt hole is configured to be larger than the dimension X2 of the outer diameter of the fastening bolt.
A test fixing jig for a seismic isolation damper, characterized in that the inner diameter dimension Y1 of the pressure nut is larger than the outer diameter Y2 of the jig strut mounted via the pressurizing nut. .. Each of the fixing jig members
Through the fastening nut in which the fastening nut hole is formed so as to correspond to the mounting bolt hole formed in the fixing protrusion of the outer plate-shaped body of the seismic isolation damper.
The fixing jig for testing a seismic isolation damper according to claim 1, wherein the fastening bolt is configured to fasten a protrusion for fixing the outer plate-shaped body of the seismic isolation damper. Each of the fixing jig members
The fixing jig for testing a seismic isolation damper according to any one of claims 1 to 2, further comprising a rotation fixing portion for fixing the rotation of the rotation shaft of the fixing member. The rotation fixing part
The flange portion erected on the jig body and the flange portion
A shaft hole formed in the flange portion and into which the rotation shaft of the fixing member is inserted,
The slit formed in the shaft hole and
A tightening bolt that tightens the slit,
3. The fixing jig for testing a seismic isolation damper according to claim 3. A test apparatus characterized in that the test is performed using the test fixing jig for the seismic isolation damper according to any one of claims 1 to 4.

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