JP5342847B2 - Seismic isolation device - Google Patents

Description

  The present invention relates to a seismic isolation device. In particular, the present invention relates to a seismic isolation device having a friction damper provided between an upper structure and a lower structure and an isolator provided between the upper structure and the upper structure.

2. Description of the Related Art Seismic isolation devices having a friction damper provided between an upper structure and a lower structure and an isolator provided between the upper structure and the lower structure to isolate the upper structure are already known. In such a seismic isolation device, a friction damping force generating unit formed between a friction surface and a sliding surface that is slidably pressed against the friction surface, and the friction damping force is formed between the upper structure and the lower structure. A disc spring that is provided between the generator and at least one of the upper structure and the lower structure, and that generates a resilient force that generates a pressing force in the friction damping force generator; Some friction dampers are provided.
Japanese Patent Laid-Open No. 10-238164

The seismic isolation device has a tendency to increase in size, and there has been a demand for downsizing. In addition, we would like to enjoy the benefits that come from downsizing the seismic isolation device, such as reducing the manufacturing cost and manufacturing effort of the seismic isolation device, reducing the weight of the seismic isolation device, improving the workability of the seismic isolation device There was also a request.
This invention is made | formed in view of this subject, The place made into the objective is to provide the seismic isolation apparatus reduced in size.

The seismic isolation device of the present invention is a seismic isolation device having a friction damper provided between an upper structure and a lower structure and an isolator provided between the friction damper and the upper structure to support the base structure. A friction damper is formed between the upper structure and the lower structure, and includes a friction surface, a friction damping force generation unit that slides while being pressed against the friction surface, and the friction damping force generation unit. A disc spring that is provided between at least one of the upper structure and the lower structure and that generates a resilient force that generates a pressing force in the friction damping force generation unit; A bolt member that penetrates the spring and holds the deflection amount of the disc spring at a predetermined amount, and a shearing force that is provided in parallel with the bolt member and that is applied from the friction damping force generation unit to one of the upper structure and the lower structure A pin member for transmitting It is characterized in.
In this way, a downsized seismic isolation device is provided.

In the seismic isolation device, the bolt member may be a member for transmitting a shear force from the friction damping force generation unit to one of the upper structure and the lower structure .
In this way, a more compact seismic isolation device is provided.

In the seismic isolation device, the friction damper may be at least one of the structure between the structure spring and the disc spring and the friction damping force generator and the disk spring. The bolt member and the pin member penetrating the disc spring are connected to the flange, and each of the bolt member and the pin member penetrating the disc spring has an H-shaped steel provided with a flange composed of an upper flange and a lower flange and a web. It is good to be.
In this way, the seismic isolation device is further miniaturized and the installation of the seismic isolation device becomes simpler.

In the above seismic isolation device, the friction damper has at least a first disc spring and a second disc spring as the disc spring, and has at least a first bolt member and a second bolt member as the bolt member. The pin member has at least a first pin member and a second pin member, and the first H-section steel provided between any one of the structures and the disc spring and the friction damping force generation. The first bolt member and the first pin member penetrating the first disc spring are both the first H-section steel and the second H-section steel provided between the portion and the disc spring. And the second bolt member and the second pin member penetrating the second disc spring are connected to the first H-section steel and the second H-section flange, respectively. The first bolt member as viewed from the H-shaped steel web and Serial at a first pin member and the horizontal direction opposite may be that it is connected to the first H-shaped steel flange and the second H-section steel flanges.
In this way, even when the bolt member (disc spring) is divided into a plurality of friction dampers, access to the bolt member is easily realized, and the installation of the seismic isolation device is simpler. It will be a thing. In addition, when the pin member is divided into a plurality of friction dampers, the shear force transmission function by the pin member is appropriately exhibited.

  According to the present invention, a downsized seismic isolation device can be provided.

=== About a configuration example of the seismic isolation device according to the present embodiment ===
First, the structural example of the seismic isolation apparatus which concerns on this Embodiment is demonstrated using FIG. FIG. 1 is a schematic cross-sectional view of a friction damper applied to the seismic isolation device according to the present embodiment. 1 is a front view of the friction damper, an upper left view is a side view of the friction damper, a center view is a view from the B and C arrows in the upper right view, and a lower view is the upper view. The AA arrow view of the right figure is each represented.

  In the present embodiment, the upper structure is an object (seismic isolation object) that is supported on the seismic isolation device and is to be subjected to seismic isolation. It includes an upper layer portion for a lower layer portion (for example, a capital of the first floor) when the structure is separated into an upper layer portion and a lower layer portion, a seismic isolation floor in a double floor structure, and the like. The lower structure is the side below the seismic isolation device that propagates and inputs vibrations to the upper structure, and not only the above-mentioned foundation but also the lower layer part or the seismic isolation floor below the upper layer part. This includes the floor slab of the other side.

  In the present embodiment, basically, a friction damper 14 provided between a beam 10 as an example of the upper structure and a floor 12 as an example of the lower structure, and a beam 10 provided therebetween. As shown in FIG. 1, the friction damper 14 is formed between the beam 10 and the floor 12, and includes a friction material 16 (corresponding to a friction surface) and the friction isolator 14. A friction damping force generation unit 20 including a sliding plate 18 (corresponding to a sliding surface) that slides while being pressed against the friction material 16, and a structure of at least one of the friction damping force generation unit 20, the beam 10, and the floor 12. (In this embodiment, the structure is a beam 10), and a disc spring 22 that generates a resilient force that generates a pressure contact force on the friction damping force generation unit 20 and a disc spring 22 Bolt member (hereinafter simply referred to as bolt 24) And U), which is connected in parallel with the bolt 24, and a pin member 36 for transmitting the one shearing force from the other of the beams 10 and the floor 12, the arrangement comprising a. Further, at least one of the structure (beam 10) and the disc spring 22 and the friction damping force generator 20 and the disc spring 22 (both in the present embodiment, both H-shaped steel (hereinafter simply referred to as H-steel 30) as an example of an open type gantry provided in the steel), and both the bolt 24 and the pin member 36 that penetrate the disc spring 22 are connected to the flange of the H-steel 30 It has the structure which is made.

  On the side of an isolator (not shown), a friction damper 14 is provided in the vertical gap δ between the upper surface of the floor 12 and the lower surface of the beam 10 as shown in FIG. The friction damper 14 is mainly composed of a plate-like sliding plate 18 provided on the upper surface of the floor 12 and a friction damping member 16 that is slidably disposed on the sliding plate 18 in the front-rear and left-right directions. Two H steels 30 (that is, between the beam 10 and the disc spring 22) provided between the force generation unit 20, the friction damping force generation unit 20 (more specifically, the friction material 16) and the beam 10. An upper H steel 32 as an example of the first H-section steel provided on the lower H-section 34 as an example of a second H-section steel provided between the friction damping force generator 20 and the disc spring 22. ) And a disc spring 22, a bolt 24, a pin member 36, and a bush 40 which will be described later. As will be described later, the friction material 16, the two H steels 30, the disc spring 22, the bolt 24, the pin member 36, and the bush 40 are integrally configured. (Hereinafter, also referred to as an integral member 60 for convenience) can be integrally inserted between the beam 10 and the floor 12 or taken out from the space.

  The sliding plate 18 is formed of a stainless steel plate or clad steel having a stainless steel plate provided on the surface thereof. The friction material 16 slid on the surface of the sliding plate 18 is made of a material having a substantially constant friction coefficient μ with the stainless plate, such as tetrafluoroethylene or ultrahigh molecular weight polyethylene (for example, Somalite (trade name)). Is used. The friction material 16 is attached to the bottom surface of the lower flange 34b of the lower side H steel 34 with a screw (not shown).

  A lower side H steel 34 and an upper side H steel 32 are provided between the friction damping force generation unit 20 and the beam 10. As described above, the friction material 16 is attached to the lower side H steel 34. The upper side H steel 32 (the upper flange 32a thereof) is detachably attached to the lower surface of the beam 10 via a bolt 42. A spacer (not shown) is provided between the upper flange 32a and the beam 10 so as to be detachable so as to close a gap generated therebetween.

  Further, between the upper side H steel 32 and the lower side H steel 34, the disc spring 22 is formed by both H steels 30 (more specifically, the lower flange 32b and the lower side H of the upper side H steel 32). It is provided to be sandwiched between the upper flange 34a of the steel 34. The disc spring 22 generates a pressure contact force on the friction damping force generation unit 20 by its elastic force (that is, the disc spring 22 is connected to the friction material 16 via the lower H steel 34). To press the friction material 16 against the sliding plate 18).

  Further, a bolt 24 is provided so as to penetrate the disc spring 22. That is, the hole 22a is provided in the center of the disc spring 22, and the bolt 24 penetrates the hole 22a. Further, the bolt 24 penetrating the disc spring 22 is connected to the lower flange 32 b of the upper side H steel 32 and the upper flange 34 a of the lower side H steel 34. In the present embodiment, the bolt 24 does not have a shearing force transmission function described later.

  Further, the pin member 36 is provided in parallel with the bolt 24 (in other words, in parallel with the disc spring 22). The pin member 36 exhibits a function of transmitting a shearing force from one of the beam 10 and the floor 12 to the other. That is, the pin member 36 plays a role of bearing a horizontal shearing force generated by the earthquake. Similar to the bolt 24, the pin member 36 is connected to the lower flange 32 b of the upper H steel 32 and the upper flange 34 a of the lower H steel 34. In this embodiment, the nut 38 is attached to the pin member 36. However, the nut 38 is not necessarily required (an example in which the nut 38 does not exist will be described later), and the pin member 36 is a pin. What is necessary is just to have a function.

  Further, FIG. 1 shows that the nuts 26 and 38 are attached to the lower portions of the bolt 24 and the pin member 36, but when the function of the friction damper 14 is exhibited (in other words, friction damping). When the elastic force is generated in the disc spring 22 in order to generate a pressure contact force in the force generation unit 20, the nuts 26 and 38 are removed (or are equivalent to the removed state). Need to be loosened). That is, FIG. 1 shows the state of the friction damper 14 that is installed between the beam 10 and the floor 12 but has not yet been able to perform its function (for convenience). In order to perform the function, the nuts 26 and 38 are removed (or loosened). The specific installation procedure of the friction damper 14 will be described in detail later.

  Further, as shown in the central view of FIG. 1, a metal bush 40 is provided between the disc spring 22 and the bolt 24 in the radial direction of the disc spring 22 (bolt 24). The bush 40 has a function of preventing the disc spring 22 from being displaced.

  Further, the friction damper 14 in the present embodiment includes at least two (two or more) disc springs as the disc springs 22, at least two (two or more) bolts as the bolts 24, and at least two ( It has two or more pin members. 1, the left disc spring 22, bolt 24, and pin member 36 are the first disc spring, first bolt, first pin member, right disc spring 22, bolt 24, and pin member 36 are the first disc spring. When the two disc springs, the second bolt, and the second pin member are used, the first bolt that penetrates the first disc spring and the second bolt that penetrates the second disc spring are the upper side H steel 32 and the lower side H steel. 34 is provided on both sides (left side and right side) of the webs 32c, 34c, and the first pin member and the second pin member are provided on both sides (left side and right side) of the webs 32c, 34c. That is, both the first bolt and the first pin member penetrating the first disc spring are connected to the lower flange 32b of the upper side H steel 32 and the upper flange 34a of the lower side H steel 34, and the second disc spring is used. Both the penetrating second bolt and the second pin member are connected to the lower flange 32b and the upper flange 34a on the side opposite to the first bolt and the first pin member when viewed from the webs 32c, 34c. Will be. As can be seen from the central view of FIG. 1, the friction damper 14 according to the present embodiment includes four sets of disc springs 22, bolts 24, and four pin members 36.

Next, an example of the installation procedure of the friction damper 14 will be described.
When installing the friction damper 14, first, the plate-like sliding plate 18 is installed on the upper surface of the floor 12 (the first step).

  Next, the nut 26 is tightened with respect to the bolt 24 (and the nut 38 is tightened with respect to the pin member 36), and the integral member 60 is appropriately contracted, and the integral member 60 is moved to the beam 10. Install on the lower sliding plate 18. That is, since the disc spring 22 is provided in the integral member 60, when the nut 26 is tightened or loosened with respect to the bolt 24, the integral member 60 contracts or extends in the vertical direction (in other words, Due to the expansion and contraction of the disc spring 22 due to the tightening of the nut 26, the upper H steel 32 and the lower H steel 34 approach or move away, and the distance from the upper end to the lower end of the integrated member 60 becomes longer or shorter. To do). Therefore, when the integral member 60 is installed between the beam 10 and the floor 12, the integral member 60 has sufficient clearance with respect to the beam 10 and the floor 12 (the integral member 60 is attached to the beam 10 and the floor 12). In order to prevent interference with a margin), the integrated member 60 is installed on the sliding plate 18 in a state where the nut 26 is tightened and the integrated member 60 is appropriately contracted (the second step).

  Next, the nut 26 is loosened with respect to the integral member 60 installed on the sliding plate 18 so that the deflection amount of the disc spring 22 becomes a predetermined deflection amount (according to this, according to this). Loosen the nut 38). That is, with respect to the friction damping force generated in the friction damping force generation unit 20, a necessary (desired) magnitude of the friction damping force is determined in advance, and the friction damping force generation unit 20 generates the friction damping force from this magnitude. The power contact force, the elastic force of the disc spring 22 required to generate the press force, and the deflection amount of the disc spring 22 required to generate the elastic force can be obtained sequentially. In the loosening operation of the nut 26, until the deflection amount of the disc spring 22 becomes a deflection amount (obtained based on the magnitude) corresponding to the required (desired) friction damping force. Then, the nut 26 is loosened to reduce the deflection amount (the third step).

  Next, when there is a gap between the upper flange 32a of the upper H steel 32 and the beam 10 when the deflection amount of the disc spring 22 reaches a predetermined deflection amount, a spacer is interposed in the gap. Disguise. And the said upper side flange 32a is fixed to the beam 10 via a spacer with the volt | bolt 42 (Thereby, the friction damper 14 will be in the state shown in FIG. 1. Above, 4th step).

  Although the installation of the friction damper 14 is completed by the above operation, the friction damper 14 is not yet in a state where its function can be exhibited. Therefore, next, in order to exert the function of the friction damper 14, the nuts 26 and 38 are removed (or the nuts 26 and 38 are sufficiently loosened). As a result, an elastic force is generated in the disc spring 22 and a necessary (desired) friction damping force is generated in the friction damping force generation unit 20 (the fifth step).

  By the way, the bolt 24 has a function of holding the deflection amount of the disc spring 22 at a predetermined amount by cooperating with the nut 26. That is, as described above, the bolt 24 has the disc spring 22 in order to allow the integral member 60 to have sufficient clearance with respect to the beam 10 and the floor 12 when the integral member 60 is installed between the beam 10 and the floor 12. The deflection amount is kept at a predetermined amount (large amount). Further, the bolt 24 has a predetermined amount of deflection (necessary (necessary ()) so that when the spacer is interposed in the gap and the upper side H steel 32 is fixed to the beam 10, the operation proceeds smoothly. (Desired amount corresponding to the magnitude of the desired frictional damping force). In this manner, the bolt 24 exhibits a function of holding the deflection amount of the disc spring 22 at a predetermined amount during the installation work of the friction damper 14.

  In the above description, the installation procedure for inserting the friction damper 14 between the existing beam 10 and the floor 12 has been described. However, the installation procedure is not limited to this. For example, first, the floor 12 is constructed, then the first step and the second step are performed, the beam 10 is constructed, and then the third step to the fifth step are performed. It may be a procedure.

<<< Characteristics of the disc spring 22 according to the present embodiment >>>
As described above, the disc spring 22 is used in a state where the deflection amount of the disc spring 22 is the predetermined deflection amount (that is, the deflection amount corresponding to the required (desired) magnitude of the frictional damping force). The friction damper 14 is installed so that the disc spring 22 can be used in this state.

  By the way, the dimension of the vertical gap δ between the upper surface of the floor 12 and the lower surface of the beam 10 may fluctuate due to changes with time, deformation of the isolator during an earthquake, or the like. More specifically, the isolator such as seismic isolation laminated rubber expands and contracts due to temperature changes of the outside air temperature, the creep phenomenon occurs as the structure weight is supported for many years, and it deforms horizontally when an earthquake occurs. The dimensions may vary due to the sinking of the isolator, the wear generated between the friction material 16 and the sliding plate 18 due to long-term use, the creep phenomenon of the friction material 16 and the sliding plate 18 itself, and the like. And if such a fluctuation | variation arises notably, since the deflection amount of the disc spring 22 will change a lot, the elastic force (in other words, the press-contact force produced in the friction damping force production | generation part 20) of the disc spring 22 will also become large. Change and the necessary (desired) friction damping force cannot be obtained.

  In view of this, in the present embodiment, a disc spring 22 having a characteristic that the elastic force (the pressure contact force) does not change much even if the predetermined deflection amount changes greatly is used.

  FIG. 2 shows an actual measurement example of a load-displacement curve graph of the disc spring 22 according to the present embodiment. The elastic force of the disc spring 22 is shown on the vertical axis, and the amount of deflection of the disc spring 22 is shown on the horizontal axis. The disc spring 22 reaches a region R where the load-displacement relationship is non-linear at the predetermined deflection amount (about 40 mm). Here, the non-linear region R refers to a region in which the variation of the elastic force is small with respect to the expected change amount of the dimension of the vertical gap δ between the beam 10 and the floor 12. Even when the dimension of the vertical gap δ between the beam 10 and the floor 12 is reduced by 10 mm and the amount of deflection of the disc spring 22 is 30 mm, the change in the elastic force can be suppressed to about 7 t.

=== About the effectiveness of the seismic isolation device according to the present embodiment ===
As described above, the seismic isolation device according to the present embodiment includes the friction damper 14 provided between the beam 10 and the floor 12 and the isolator provided between the beam 10 and the base 10 to provide seismic isolation support. 14 is formed between the beam 10 and the floor 12, and includes a friction material 16 and a friction damping force generation unit 20 that slides while being pressed against the friction material 16, and the friction damping force generation unit 20. A disc spring 22 that is provided between at least one of the beam 10 and the floor 12 and generates a spring force that generates a pressure contact force in the friction damping force generation unit 20, and penetrates the disc spring 22. And a pin member 36 provided in parallel with the bolt 24 for transmitting a shearing force from one of the beam 10 and the floor 12 to the other. This makes it possible to reduce the size of the seismic isolation device (friction damper 14).

  About the above, it demonstrates using FIG. 3, comparing the seismic isolation apparatus (friction damper 14) which concerns on this Embodiment, and the seismic isolation apparatus (friction damper 114) which concerns on a prior art example (namely, patent document 1). To do. FIG. 3 is a schematic cross-sectional view of a friction damper applied to a conventional seismic isolation device.

  The friction damper 114 according to the conventional example shown in FIG. 3 is provided between the upper structure 110 and the lower structure 112, similarly to the friction damper 14 according to the present embodiment. In addition, the friction damping force generation unit 120 formed between the upper structure 110 and the lower structure 112, which includes the friction material 116 and the sliding plate 118 that slides while being pressed against the friction material 116, and the friction damping force generation. The friction damping force generation unit is provided between the unit 120 and at least one of the upper structure 110 and the lower structure 112 (in the conventional example, the structure is the upper structure 110). This embodiment is also similar to the present embodiment in that it includes a disc spring 122 that generates a resilient force that generates a pressing force on 120.

  However, the friction damper 114 according to the conventional example is not provided with a bolt penetrating the disc spring 122 or a pin member for transmitting a shearing force from one of the upper structure 110 and the lower structure 112 to the other. That is, the friction damper 114 according to the conventional example is provided with a spring casing 126 including an upper cylindrical body 132 and a lower cylindrical body 130 for accommodating the disc spring 122. As is apparent from FIG. A side portion 126a of the spring casing 126 located on the outer side in the horizontal direction from the disc spring 122 transmits a shearing force from one of the upper structure 110 and the lower structure 112 to the other (that is, the spring casing). 126 side 126a plays the role of bearing the horizontal shearing force generated by the earthquake). The bolt 142 is also provided in the friction damper 114 according to the conventional example, and the bolt 142 has a function of holding the deflection amount of the disc spring 22 at a predetermined amount (during installation of the friction damper 114). Demonstrate. However, the bolt 142 is provided on the outer side in the horizontal direction than the disc spring 122 (the outer side in the horizontal direction further than the side portion 126 a), and does not penetrate the disc spring 122.

  Thus, in the conventional example, the side portion 126a and the bolt 142 of the spring casing 126 are provided with the two functions (shear force transmission function and deflection amount holding function). The friction damper 114 according to the conventional example is increased in size because it is a large member and the bolt 142 is located on the outer side in the horizontal direction than the disc spring 122.

  On the other hand, in the present embodiment, since the pin member 36 which is a small member has a shearing force transmission function, the large spring casing 126 can be omitted (removed). In addition, since the bolt 24 having a deflection amount holding function is provided so as to penetrate the disc spring 22, the bolt 142 positioned on the outer side in the horizontal direction than the disc spring 122 can be omitted (removed). Therefore, the friction damper 14 (and hence the seismic isolation device) can be reduced in size. And since the friction damper 14 is reduced in size, the manufacturing cost and the effort of manufacture of the friction damper 14 (seismic isolation device) are reduced. Further, the downsizing realizes a reduction in the weight of the friction damper 14 (base isolation device), simplifies the installation of the friction damper 14 (base isolation device), and eliminates the need for large equipment for the installation. (In other words, workability is improved).

  Further, in the present embodiment, the friction damper 14 is at least one of the beam 10 and the disc spring 22 and the friction damping force generator 20 and the disc spring 22 (in the present embodiment, , Both), the bolt 24 and the pin member 36 penetrating the disc spring 22 are connected to the flange of the H steel 30. As described above, since the H steel 30 is used as a member to which the bolt 24 and the pin member 36 that penetrate the disc spring 22 are connected, the space provided in the H steel 30 (that is, the upper flange, the web, and the lower flange). By using the space surrounded by (3), access to the bolt 24 and the pin member 36 is easily realized. Therefore, the friction damper 14 (the seismic isolation device) can be installed more easily (there can be installed with a simple tool such as a shear wrench). Furthermore, since the pin member 36 can be placed in the space, the pin member 36 can be prevented from being positioned horizontally outward from the H steel 30, and the friction damper 14 (the seismic isolation device) can be further downsized. It becomes possible.

  In the present embodiment, both the first bolt and the first pin member that penetrate the first disc spring are connected to the lower flange 32b of the upper H steel 32 and the upper flange 34a of the lower H steel 34. The second bolt and the second pin member penetrating the second disc spring are both on the lower flange 32b and the upper flange 34a on the opposite side in the horizontal direction from the first bolt when viewed from the webs 32c, 34c. It was decided to be connected. Since the first bolt, the second bolt, the first disc spring, the second disc spring, the first pin member, and the second pin member are arranged in this way, the bolts 24 (per disc) 22 ) Even if the bolt 24 (disc spring 22) is provided in a plurality of portions in the friction damper 14 for the purpose of further downsizing and weight reduction, the access to the bolt 24 is easily realized. The installation of the friction damper 14 (the seismic isolation device) becomes simpler. Further, when the pin member 36 is provided in a plurality of portions on the friction damper 14, a well-balanced arrangement of the pin members 36 is realized, and thereby the shear force transmission function is appropriately exhibited.

=== Other Embodiments ===
As mentioned above, although the seismic isolation apparatus based on this invention was demonstrated based on the said embodiment, embodiment mentioned above is for making an understanding of this invention easy, and does not limit this invention. Absent. The present invention can be changed and improved without departing from the gist thereof, and the present invention includes the equivalents thereof.

  Moreover, in the said embodiment, although the volt | bolt 24 decided not to have a shearing force transmission function, it is not limited to this, The volt | bolt 24 applies a shearing force from one side of the beam 10 and the floor 12 to the other. It may be a member for transmission. That is, both the bolt 24 and the pin member 36 are members that play a role of bearing a horizontal shearing force generated by an earthquake, and the shearing force transmission function may be exhibited by both. In such a case, the shear force is transmitted not only by the pin member 36 but also by the pin member 36 and the bolt 24, so that the pin member 36 can be made simpler. Thus, further downsizing of the friction damper 14 is realized.

  Moreover, in the said embodiment, although the disc spring 22 with which the both sides (left side and right side) of the webs 32c and 34c were equipped, and the volt | bolt 24 which penetrates the said disc spring 22 were one set, it is limited to this. Instead, a plurality of pieces may be provided as shown in FIG.

  Moreover, in the said embodiment, although the pin member 36 was provided in the horizontal direction outer side than the volt | bolt 24 (the bolt 24 provided in the horizontal direction outer side rather than the pin member 36 did not exist), FIG. 4, the bolt 24 may be provided on the outer side in the horizontal direction than the pin member 36 (the bolt 24 provided on the outer side in the horizontal direction than the pin member 36 may be present).

  Moreover, in the said embodiment, as shown in the lower figure of FIG. 1, the friction material 16 was one, However, As shown in FIG.

  Moreover, in the said embodiment, although the several pin member 36 was provided in the friction damper 14, it is not limited to this, As shown in FIG. 5, only one pin member is shown. 36 may be provided.

  Moreover, in the said embodiment, although the nut 38 was attached to the pin member 36, it is not limited to this, As shown in FIG.4 and FIG.5, there is no nut 38. Also good.

  4 and 5 show schematic cross-sectional views of a friction damper applied to a seismic isolation device according to another embodiment.

  Moreover, in the said embodiment, although the H-shaped steel was mentioned as an example and demonstrated as the said open type gantry, it is not limited to this, A C-shaped steel may be sufficient.

The cross-sectional schematic diagram of the friction damper applied to the seismic isolation apparatus which concerns on this Embodiment is shown. It is the figure which showed one measurement example of the graph of the load-displacement curve of the disk spring 22 which concerns on this Embodiment. The cross-sectional schematic diagram of the friction damper applied to the seismic isolation apparatus which concerns on a prior art example is shown. The cross-sectional schematic diagram of the friction damper applied to the seismic isolation apparatus which concerns on other embodiment is shown. The cross-sectional schematic diagram of the friction damper applied to the seismic isolation apparatus which concerns on other embodiment is shown.

Explanation of symbols

10 beams, 12 floors, 14 friction dampers, 16 friction materials, 18 sliding plates,
20 friction damping force generation part, 22 disc spring, 22a hole,
24 bolts, 26 nuts, 30 H steel,
32 Upper side H steel, 32a Upper flange, 32b Lower flange, 32c Web,
34 Lower side H steel, 34a Upper flange, 34b Lower flange, 34c Web,
36 pin member, 38 nut, 40 bush, 42 bolt, 60 integral member,
110 upper structure, 112 lower structure, 114 friction damper, 116 friction material,
118 sliding plate, 120 friction damping force generation unit, 122 disc spring,
126 spring casing, 126a side,
130 Lower cylinder, 132 Upper cylinder, 142 bolts

Claims (4)

A seismic isolation device having a friction damper provided between an upper structure and a lower structure, and an isolator provided between the friction damper and the upper structure,
The friction damper is
A friction damping force generation unit formed between the upper structure and the lower structure, and including a friction surface and a sliding surface that slides in pressure contact with the friction surface;
It is provided between the friction damping force generation part and at least one of the upper structure and the lower structure, and generates a resilient force that generates a pressure contact force on the friction damping force generation part. A disc spring to
A bolt member that penetrates the disc spring and holds the deflection amount of the disc spring at a predetermined amount ;
A seismic isolation device, comprising: a pin member provided in parallel with the bolt member and configured to transmit a shearing force from the friction damping force generation unit to one of the upper structure and the lower structure. The seismic isolation device according to claim 1,
The seismic isolation device, wherein the bolt member is a member for transmitting a shearing force from the friction damping force generation unit to one of the upper structure and the lower structure. In the seismic isolation device according to claim 1 or 2,
The friction damper is
The upper flange and the lower flange are provided between at least one of the structure and the disc spring and between the friction damping force generation unit and the disc spring. H-shaped steel with flange and web,
Both the bolt member and the pin member penetrating the disc spring are connected to the flange. In the seismic isolation device according to claim 3,
The friction damper is
The disc spring has at least a first disc spring and a second disc spring,
The bolt member has at least a first bolt member and a second bolt member,
As the pin member, it has at least a first pin member and a second pin member ,
A first H-section steel provided between any one of the structures and the disc spring, and a second H-section steel provided between the friction damping force generation unit and the disc spring,
Both the first bolt member and the first pin member penetrating the first disc spring are connected to the flange of the first H-section steel and the flange of the second H-section steel,
Both the second bolt member and the second pin member that penetrate the second disc spring are the first bolt member and the first pin when viewed from the web of the first H-section steel and the second H-section steel. A seismic isolation device, which is connected to the flange of the first H-section steel and the flange of the second H-section steel on a side opposite to the pin member in the horizontal direction.

Images