JP2002070039A - House damping foundation structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a house damping foundation structure capable of suiting such a structure as a detached house and being supplied at a low cost. SOLUTION: The house damping foundation structure includes a ground side concrete foundation 30 having the flat upper surface formed on the ground 20 where the house 10 is constructed, a house side concrete foundation 40 having the flat lower surface set on the ground side concrete foundation constituted on the lower part of the house and a plurality of automatic restoring mechanisms 60 connecting between the ground side concrete foundation and the house side concrete foundation through a friction damping material 50 in a state to make it possible to horizontally vibrate the house side concrete foundation.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a housing seismic reduction base structure for reducing horizontal vibration during an earthquake and preventing the destruction of houses, and more particularly to an inexpensive housing seismic base suitable for detached houses. Regarding the structure.

[0002]

2. Description of the Related Art Heretofore, seismic isolation devices have been known as means for preventing the destruction of buildings due to earthquakes.
For example, as a seismic isolation device for a large building such as a building, a laminated rubber formed by laminating a disk-shaped iron plate and rubber is known. However, such a laminated rubber is suitable for a structure having a large weight, but is not suitable for a structure that is lighter than a building such as a detached house.

[0003] Therefore, as a seismic isolation device for a detached house, a device using a ball bearing is provided. This is configured by providing a bearing with a ball bearing between a house and its foundation. A plurality of ball bearing bearings are provided. The base portion is provided with a saucer for receiving a rigid sphere in a ball bearing, and the upper surface of the saucer is usually formed in a concave shape.

[0004]

However, although the sphere has rigidity, since it is supported at one point, damage such as chipping is likely to occur. In order to prevent this, it is necessary to reduce the load per bearing part by the ball bearing. This means that the number of bearings by ball bearings increases.

On the other hand, as another means for preventing the destruction of a building due to an earthquake, a vibration control device is known. As an example, there is one that utilizes the plastic flow resistance of lead housed in a cylinder. In this method, lead in a cylinder undergoes plastic deformation due to relative movement of a rod having a projection that moves in lead in the cylinder, and absorbs vibration energy. A plurality of such vibration control devices are required even in the case of a detached house.

[0006] In any case, the seismic isolation device and the vibration control device having the above-described structure are expensive, and cause an increase in house prices.

It is an object of the present invention to provide a base structure for housing seismic reduction suitable for a structure such as a detached house and which can be provided at a low cost.

[0008]

According to the present invention, there is provided a ground foundation formed on the ground on which a house is constructed, and a housing foundation formed at a lower portion of the house and placed on the ground foundation. Including a friction-reducing material provided between the ground-side foundation and the house-side foundation, and having a friction coefficient of the friction-reducing material in the range of 0.05 to 0.5, When the ground-side foundation horizontally vibrates, the horizontal vibration is reduced and transmitted to the house-side foundation, and furthermore, it is made to vibrate within a maximum single amplitude of 35 cm. Provided.

The friction reducing material is selected from a sheet or plate member made of synthetic resin or metal, a powder or particle material, and a coating material.

[0010] In the base structure for earthquake-reducing housing according to the aspect of the present invention, the ground-side foundation is a solid foundation, a cloth foundation or a combination thereof, which has a flat portion on the upper surface. It is a solid foundation, a cloth foundation, or a combination of them, which has a flat part at a location corresponding to the flat part of the ground side foundation.

In another embodiment of the present invention, the ground-side foundation is a solid foundation having a flat portion on an upper surface, a cloth foundation, or a combination thereof, and the housing-side foundation is provided. And a steel base having a flat portion at a place in contact with the flat portion of the ground-side foundation.

In any of the embodiments, an underground beam and a ground beam may be integrally formed on at least one of the ground-side foundation and the house-side foundation, respectively, as a reinforcing portion.

Further, the ground-side foundation is formed so as to be larger in area than the housing-side foundation, and the ground-side foundation outside the housing-side foundation has the housing-side foundation vibrated by an earthquake. A jig fixing portion to which a jig for returning the house-side foundation to the original position when displaced with respect to the ground-side foundation may be provided at a plurality of locations.

[0014] Further, between the house side foundation and the ground side foundation, when the house side foundation is displaced with respect to the ground side foundation due to vibration caused by an earthquake, the house side foundation is returned to its original position. An automatic return mechanism for automatically returning to the home position may be provided at a plurality of locations.

In this case, the automatic return mechanism includes a rubber body,
Or an elastic body made of a laminated body of rubber and a steel plate, or an elastic body made of a spring body. The elastic body has a spring constant selected in advance by design, and the elastic body has a weight of the housing-side foundation and a housing portion thereon. , The automatic return mechanism also has a seismic reduction effect on the house-side foundation.

Further, the rubber body may be a high-damping rubber body having high damping characteristics by mixing artificial rubber.

Further, when the automatic return mechanism is provided at a location where the house-side foundation and the ground-side foundation overlap, the automatic return mechanism includes: a ground-side fixing plate fixed to the ground-side foundation; A housing-side fixing plate fixed to an upper surface of the housing-side foundation; and the elastic body connected to the ground-side fixing plate and the housing-side fixing plate through a through hole provided in the housing-side foundation. Thus, a function of preventing the housing-side foundation including the housing portion from being lifted by strong wind or the like can be provided.

In this case, the through-hole has a size that allows at least a maximum single amplitude of 35 cm of the elastic body.

[0019] Further, between the housing-side foundation and the ground-side foundation, horizontal vibration is absorbed when the maximum amplitude of the housing-side foundation exceeds a predetermined value due to horizontal vibration caused by an earthquake. May be installed at a plurality of locations.

Further, by providing a plate-shaped vibration isolator between the house-side foundation and the friction reducing material so as to be fixed to the house-side foundation, vertical vibration of the house-side foundation is reduced. It can be made to attenuate.

Further, a pillar on the house side is assembled on the house side foundation via a wooden base, and the house side foundation portion corresponding to the pillar has a hole down to the house side foundation and the pillar. One or more holes for attaching hardware may be provided in advance.

[0022]

BEST MODE FOR CARRYING OUT THE INVENTION The base structure for seismic reduction of houses according to the present invention is designed to reduce horizontal vibrations expected at the time of an earthquake in a form different from the conventional concept of seismic isolation devices and seismic control devices. There is a characteristic in that. In particular, according to the housing seismic reduction base structure according to the present invention, the acceleration (Ga
When l) exceeds a predetermined value, the housing part can be caused to horizontally vibrate after being subjected to seismic reduction.

Hereinafter, a first embodiment of the present invention will be described. Referring to FIG. 1, a base structure for house seismic reduction according to the first embodiment includes a ground 20 on which a house 10 is built.
Ground-side concrete foundation 30 formed in
Ground-side concrete foundation 3
0, the concrete foundation 40 on the housing side, the concrete foundation 30 on the ground side, and the concrete foundation 40 on the housing side
And a friction reducing material 50 provided between the two. And
By setting the friction coefficient of the friction reducing material 50 in the range of 0.05 to 0.5, when the ground-side concrete foundation 30 vibrates horizontally due to the earthquake, the horizontal vibration is reduced to the house-side concrete foundation 40. , And vibrates within a maximum single-amplitude of 35 cm.

As for the ground-side concrete foundation 30, as shown in FIG. 2 (a), a plurality of underground beams 30 as reinforcing parts are provided below the solid foundation made of concrete having a predetermined thickness.
2 and, as shown in FIG. 2 (b), underground beams 30-2 are provided in a girder shape below a solid foundation made of concrete having a predetermined thickness. However, the structure does not matter as long as a part of the upper surface has a flat surface and satisfies the strength required as a foundation on the ground side. For example, a cloth foundation as described later or a combination of a cloth foundation and a solid foundation may be used. It is preferable that a reinforcing bar is incorporated in the solid foundation portion, and particularly a double reinforcing bar is incorporated in the underground beam.

Referring to the house side concrete foundation 40, as shown in FIG. 3 (a), a cloth foundation 40-1 is provided at a peripheral portion on the upper surface side of a solid foundation made of concrete of a predetermined thickness. In addition, there is a structure in which a girder-shaped ground beam 40-2 is further provided as a reinforcing portion in 1. FIG.
As shown in (b), cloth foundation 40-1 without solid foundation
And a ground beam 40-2 or a solid foundation shown in FIG. 3 (c) with holes 40-3. In other words, the structure of the house-side concrete foundation 40 is not limited as long as it has a flat surface on a part of the lower surface and satisfies the strength required for the house-side foundation. However, it is necessary that at least a part of the lower surface side flat surface of the house-side concrete foundation 40 matches with the upper surface side flat surface of the ground side concrete foundation 30. This is because it is necessary to provide the friction reducing material 50 between the upper surface side flat surface of the ground side concrete foundation 30 and the lower surface side flat surface of the house side concrete foundation 40. In the housing-side concrete foundation 40 as well, it is preferable that a double reinforcing bar is incorporated into the cloth foundation 40-1 and the reinforcing portion 40-2 as well as the solid foundation.

The house-side concrete foundation 40 is integrated with the lower part of the house 10. This is performed after the house-side concrete foundation 40 is formed and then the house 10 is formed thereon.

Although several examples have been given for the ground-side concrete foundation 30 and the house-side concrete foundation 40, they need not necessarily be made of concrete. For example, in the case of a foundation as shown in FIG. 3 (b), a steel material, particularly a material such as an H-section steel, may be used. For example,
When an H-section steel is used, two parallel plate portions are arranged so that one of them is on the lower side and the other is on the upper side. Use of such a material can be similarly applied to the second and third embodiments described later.

The friction reducing material 50 is selected from a sheet or plate member made of synthetic resin or metal, a powder or particle material, and a coating material. In the case of a synthetic resin, for example, a sheet material or a powder material made of ethylene tetrafluoride is commercially available. Further, a plate-like material made of bakelite is also commercially available. For metal sheet or plate members,
There is no limitation on the type of metal, but an oilless metal is one example. In the case of powder or particulate material, stone powder or sand having a small particle size, powder of a sintered product (glass or brick tile, etc.), granular oil-less metal and the like can be mentioned. Such a powdery or particulate material may be mixed with an enamel material and applied. Also,
In the case of a sintered product, a plate-like material can be realized. On the other hand, in the case of a coating material, a coating material applied to a normal concrete floor has a friction coefficient of about 0.5 to 1, but is mixed with a particulate friction reducing material (for example, the above-mentioned tetrafluoroethylene). By doing so, the friction coefficient can be reduced to 0.5 or less. Such a coating agent may be applied only by a roller or a brush, or may be further subjected to heat treatment.

The friction reducing material 50 may be a plate made of a stone material such as marble or granite. This is because marble, granite, and the like can have a friction coefficient of 0.5 or less by polishing the surface. Of course, such a plate-like material may be combined with the above-mentioned powdery or particulate material or coating material.

In some cases, when the ground-side concrete foundation 30 is hardened after striking the concrete, the friction reducing material 50 has a particle size that can be obtained by sweeping the upper surface of the solid foundation with a broom-like object. Small granular materials may be used. On the other hand, the sheet-like thing means that the house-side concrete foundation 40 is usually laid on the sheet-like thing after the ground-side concrete foundation 30 has been concreted and then hardened. It is also assumed that the side concrete foundation 40 is formed by forming a formwork, incorporating a reinforcing bar, and pouring concrete into it. Of course, the housing-side concrete foundation 40 may be formed in another place, for example, a place adjacent to the ground-side concrete foundation 30, and may be arranged on the ground-side concrete foundation 30 by a crane or the like.

In any case, the thickness of the friction reducing material 50 is several mm or less, and particularly, its friction coefficient is 0.05 to
What is necessary is just to design so that it may be in the range of 0.5.

As described above, the ground-side concrete foundation 3
Friction reducing material 5 between 0 and housing side concrete foundation 40
When 0 is present, even if the ground-side concrete foundation 30 horizontally vibrates due to the earthquake, the horizontal vibration is reduced and transmitted to the house-side concrete foundation 40. Then, by selecting the friction coefficient of the friction reducing material 50 based on the total weight of the ground-side concrete foundation 30 and the housing part, the housing-side part can be configured to vibrate within a maximum single amplitude of 35 cm. To achieve this, the preferable range of the friction coefficient of the friction reducing material 50 is 0.1 to 0.1.
3.

By the way, in the foundation structure as shown in FIG. 1, when horizontal vibration occurs due to an earthquake, the housing-side concrete foundation 40 and the ground portion-side concrete foundation 3
There is a case where a positional shift occurs with respect to 0. Such a displacement can be manually recovered by using a special jig, for example, a hydraulic jack.

FIGS. 4 and 5 show a basic structure in consideration of the above restoration work. Ground side concrete foundation 30
Is larger (for example, about 35 cm) than the housing-side concrete foundation 40 in that area. The ground-side concrete foundation 30 outside the house-side concrete foundation 40 is provided with jig fixing portions 31 at a plurality of locations so that special jigs can be attached. The jig fixing portion 31 includes a plurality of anchor hooks 31-2.
This is realized by the L-shaped steel sheet 31-1 having the following. The L-shaped steel plate 31-1 corresponding to the upper surface side of the ground-side concrete foundation 30 has a plurality of screw holes 31-3 for attaching a special jig.

With reference to FIG. 6, a second embodiment of the present invention will be described. 1 are given the same numbers. This embodiment is an automatic return mechanism for automatically returning the housing-side concrete foundation 40 to the original position together with the housing-side portion when the housing-side concrete foundation 40 is displaced with respect to the ground-side concrete foundation 30 due to horizontal vibration. 60 is provided.

In FIG. 6, the base structure for seismic reduction of a house according to the present embodiment includes a ground-side concrete foundation 30 formed on the ground 20 on which the house 10 is constructed, and a ground-side concrete foundation formed integrally with the lower part of the house 10. A housing-side concrete foundation 40 having a flat lower surface placed on the concrete foundation 30, a ground-side concrete foundation 30, and a housing-side concrete foundation 40
And a plurality of automatic return mechanisms 60 to which the housing-side concrete foundation 40 is connected in a horizontally vibrable state via a friction reducing material 50.

The ground-side concrete foundation 30, the residential-side concrete foundation 40, and the friction reducing material 50 may be exactly the same as those described in the first embodiment.

In this embodiment, in consideration of the thickness of the solid foundation portion of the housing-side concrete foundation 40, the upper surface of the solid foundation of the housing-side concrete foundation 40 is 5 cm or more from the ground surface in consideration of the thickness of the solid foundation portion of the housing-side concrete foundation 40. Made in the ground 20 to a height. The ground-side concrete foundation 30 is formed so as to have a larger area than the housing-side concrete foundation 40, specifically, to be several tens of cm larger. The space formed between the concrete foundation 40 on the housing side and the ground 10 is provided with a vibration isolator 45.
Is provided. Various types of vibration insulators 45 are known, and any of them may be used. For example, hard rubber products obtained by reclaiming waste rubber such as old tires are commercially available.

Referring also to FIG. 7 and FIG.
Numeral 0 indicates that a bolt or the like is directly implanted or embedded in the ground-side concrete foundation 30, and that the bolt or the like is directly implanted or embedded in the upper surface side of the housing-side concrete foundation 40. And a resilient member 63 connected to the ground-side fixing plate 61 and the housing-side fixing plate 62 through the through hole 41 provided in the housing-side concrete foundation 40. The elastic body 63 can be realized by a well-known rubber body having a predetermined spring constant, a laminated body of rubber and a steel plate, a metal spring, or the like. The size is, for example, about 35 cm in height and about 35 cm in diameter. Such an elastic body 63 is commercially available, and is much cheaper than the above-described seismic isolation device or vibration damping device using a ball bearing. As the elastic body 63, a high-damping rubber body having high damping characteristics by further mixing artificial rubber with a rubber body is known.

The through hole 41 in the concrete foundation 40 on the house side
Is made to have a size that can at least allow a horizontal displacement of the elastic body 63 of about ± 35 cm, and a stopper 42 made of a metal material or the like is provided on the inner wall thereof in order to prevent the concrete from peeling off when the elastic body 63 comes into contact. Can be The house-side fixing plate 62 has an area larger than the through hole 41 and has a function of preventing the house 10 from rising due to wind pressure or the like by being fixed to the upper surface side of the house-side concrete foundation 40, but it does not necessarily have to. It is not necessary to fix to the upper surface side of the house side concrete foundation 40.

In any case, the automatic return mechanism 60 uses the elastic body 63 to attenuate the vibration of the ground-side concrete foundation 30 due to the earthquake and to transmit the vibration to the housing-side concrete foundation 40; In addition to the function of restoring the displaced housing-side concrete foundation 40 to its original position, the housing-side concrete foundation 40 has a function of preventing the housing-side concrete foundation 40 from rising up due to wind pressure or the like. When the above-described high damping rubber body is used for the elastic body 63, the vibration damping function can be further improved.

The number of the automatic return mechanisms 60 to be installed is determined by their horizontal load bearing characteristics.
Usually, each has a load bearing capacity of about 10 tons. As is clear from FIGS. 6 and 7, the load on the housing-side concrete foundation 40 and the housing portion above it does not act on the automatic return mechanism 60, and the static vertical load is zero. On the other hand, the horizontal load of the house is about several tens tons, and the number of automatic return mechanisms 60 that can withstand this is installed. FIG. 9 shows an automatic return mechanism 60.
Are indicated by white circles, and are located near the four corners of the house-side concrete foundation 40 so that the horizontal load on the house is applied to each of them as evenly as possible. When there is a sufficient space outside the house-side concrete foundation 40, the automatic return mechanism 60 may be installed outside the house-side concrete foundation 40 as shown by a broken circle in FIG. . In this case, an auxiliary plate made of a steel plate or the like is required outside the house-side concrete foundation 40 to fix the house-side fixing plate 62.

On the other hand, as shown in FIGS. 3B and 3C,
Even when there is no space for fixing the housing-side fixing plate 62 to the housing-side concrete foundation 40, an auxiliary member such as a steel plate is provided on the housing-side concrete foundation 40, and the housing-side fixing plate 62 is fixed to the auxiliary member. You.

Further, in an area where earthquakes are likely to occur frequently or where the seismic intensity is large, the maximum amplitude at the time of design may be exceeded. In consideration of this, between the ground-side concrete foundation 30 and the house-side concrete foundation 40, the maximum amplitude of the house-side concrete foundation 40 is set to a predetermined value (for example, 35 cm) due to horizontal vibration caused by the earthquake.
May be provided with a damper mechanism for absorbing horizontal vibration when the distance exceeds the limit. As this type of damper mechanism, a hydraulic type and a type using a metal spring are commercially available, and detailed illustration and description of the structure are omitted. In any case, this type of damper mechanism is adapted to fix one to the ground-side concrete foundation 30 and the other to the residential-side concrete foundation 40.

FIG. 10 shows a case where the house-side concrete foundation 40 comprises only the cloth foundation 40-1. Here, four damper mechanisms 70 are provided inside the cloth foundation 40-1. Of course, as shown by a broken line in FIG.
May be provided outside the cloth foundation 40-1. The housing-side concrete foundation 40 is composed of a solid foundation and a cloth foundation 4.
0-1, the damper mechanism 70 is attached to the cloth base 40-
If it is necessary to install the damper mechanism 70 inside the solid base 1, a hole is formed in the solid base portion to secure a space necessary for providing the damper mechanism 70.

Referring to FIG. 11, a third embodiment of the present invention will be described. This embodiment is an improvement of the first embodiment shown in FIG. 1, but it is needless to say that the present embodiment is also applicable to the second embodiment shown in FIG. In this embodiment, a housing-side concrete foundation 40 and a plate-like vibration-absorbing material 80 are provided between the housing-side concrete foundation 40 and the friction reducing material 50 so as to be fixed to the housing-side concrete foundation 40. The vertical vibration of the housing part can be attenuated. As the vibration isolator 80, the same material as the vibration isolator 45 described with reference to FIG. 6, particularly, a hard rubber material obtained by reclaiming waste rubber such as old tires can be used. The vibration isolating material 80 has a natural period of the ground 20,
The spring constant, the damping coefficient, and the like are selected in consideration of the natural period of the house and the like so that the damping effect in the vertical direction is maximized.

In other words, the natural period of the ground is 5 Hz or more for the first type and 1.3 for the second type according to the notification of the Ministry of Construction.
It is set to 3 Hz to 5 Hz, and to 1.33 Hz or less for the third type. In the second embodiment, the first to third types of ground are targeted, and the period range and the elastic body 63 are set.
By applying the relationship with the natural period of a house, the horizontal vibration of the house at the time of the earthquake is reduced, and the influence on the house is reduced. Specifically, by appropriately selecting the friction coefficient of the friction reducing material 50 and the spring constant of the elastic body 63,
When the acceleration (Gal) at the time of the occurrence of the earthquake exceeds a predetermined value, the housing-side concrete foundation 40 and the housing part thereon can be configured so as to be horizontally shaken after the earthquake is reduced. As the predetermined value of the acceleration, for example, 200 (Gal) is set.

Referring to FIGS. 12 and 13 showing the relationship between the vibration transmissibility and the frequency ratio (frequency ratio), the principle of the above-described vibration reduction in the case of the type 3 ground will be described.

In FIG. 12, the natural period of the ground is f_G,
Let the natural period of the elastic body 63 be f_SThen, the attenuation range of the vibration is
f_G/ F_SIs 2^1/2It appears when it is more than
Is f _G/ F_S≧ 2.

The natural period f _S of the elastic body 63 and the spring constant k have a relationship of f _S = 1 / 2π (k / M) ^1/2 (where M is weight).

Here, the horizontal load on the house side is the friction reducing material 5
Although it changes with the friction coefficient of 0, it is about 50 tons on average, and it is about 66 m ² when the building area is 20 tsubo. Assuming that six automatic return mechanisms 60 are used, 1
You will receive 8.33 tons per piece. Therefore, assuming that the friction coefficient of the friction reducing material 50 is 0.2, even if an acceleration up to 200 (Gal) is applied due to an earthquake, the housing-side concrete foundation 40 and the housing part thereon do not move.
In order to cause the housing-side concrete foundation 40 and the housing part thereon to vibrate horizontally at a time exceeding 200 (Gal), the following is necessary.

Assuming that the thickness of the solid foundation of the house-side concrete foundation 40 (= the height of the elastic body 63) is about 20 cm and the horizontal displacement of the elastic body 63 is ± 20 cm, the acceleration 4
When the earthquake of 00 (Gal) occurs, if the attenuation of the elastic body 63 is set to 0, (400-200) = 200 (Gal)
If 200 (Gal) × 8.33 tons / 20 (cm), then 1.7 tons / 20 cm, and the spring constant k =
0.085 (ton / cm).

At that time, the natural period f _S of the elastic body 63 = (1
/2π)｛{(0.085×980)/8.33} ^1/2
= 0.5 (Hz).

As described above, the attenuation appears when the value of f _G / f _S becomes 2 ^1/2 or more. Therefore, if the safety factor is 2, 0.5 (Hz) × 2 = 1.0 ( Hz), and FIG.
As shown in FIG. 3, large attenuation can be expected at a frequency of 1 (Hz) or more.

On the other hand, for a house, it is assumed that the total weight of the house including the house-side concrete foundation 40 and the house 10 is 50 tons, and this attenuation may be considered as the attenuation of the whole house. The natural frequency of the house itself is 4.5-11.
It is known to be in the range of 5 (Hz) (for example,
Proceedings of the Autumn Meeting of the Japan Society of Geophysical Exploration 1986 “Evaluation of Vibration Characteristics of Wooden House by Microtremor Measurement” Tatsuro Matsuoka, Chiyuki Kiyomiya, Takashi Shiroquartz Saitama Prefectural Pollution Center) If it is not in the appropriate band (however, it may be 0.4 to 1 Hz in design), it is considered that there is equivalent attenuation.
It is expected that the damping of the vibration transmission rate and the damping of the vibration transmission rate will be attenuated, and a vibration reduction effect of about 1/2 to 1/5 can be obtained depending on the natural period of the ground.

In other words, concrete foundation 4 on the house side
A wooden pillar on the house side is usually mounted on the zero through a wooden base. When a considerable number of years have passed since the construction of such a wooden base, a termite may be eaten by the termites or may be corroded by water or the like, resulting in a defective portion. When such a missing part is found by a house diagnosis or the like, a renovation work is required. Until now, this type of renovation work has been to install a metal plate called a hole-down metal fitting on the pillar side, attach a member called a chemical anchor to the concrete foundation on the house side, and mechanically connect the hole-down hardware and the chemical anchor. To be reinforced. However, since such renovation work requires extremely high costs (10 million yen or more per building), it is actually hardly performed.

A fourth embodiment for solving the above problem will be described with reference to FIGS.
In FIG. 14, a plurality of holes 40a for attaching hole-down hardware to the house-side concrete foundation 40 and the pillars are provided in advance on the house-side concrete foundation 40 corresponding to the wooden pillars on the house side. . The hole 40a is provided with a screw hole into which a metal member is embedded in the inner wall and into which a bolt can be screwed. In FIG. 15, when a missing part due to termites, corrosion, or the like is found on the wooden base 100 by a house diagnosis or the like, the hole-down metal fitting 120 is attached to the pillar 110 and the house-side concrete foundation 40 using the hole 40a. . In addition, a hole for a bolt can be formed on the pillar 110 side even afterwards.
The surface on which the hole 40a is provided is preferably an outer surface in consideration of workability, but may be an inner surface. According to such a foundation structure, it is possible to perform renovation work at a low cost when a defect occurs in the base 100. Of course, this form
The present invention can be applied to any of the first to third embodiments.

[0058]

As described above, according to the present invention,
It is possible to realize horizontal vibration reduction at the time of an earthquake at a lower cost than conventional seismic isolation devices and vibration control devices. This makes it possible to provide a detached house with safety against earthquakes at a lower price than before.

[Brief description of the drawings]

FIG. 1 is a cross-sectional view showing a base structure for vibration reduction according to a first embodiment of the present invention.

FIG. 2 is a view of two examples of a ground-side concrete foundation in FIG. 1 as viewed from a lower surface side.

FIG. 3 is a view of three examples of the house-side concrete foundation in FIG. 1 as viewed from above.

FIG. 4 is a diagram showing a base structure for explaining a jig fixing portion for mounting a jig provided on the ground-side concrete foundation when the positional deviation of the housing-side concrete foundation is manually returned to the original position in the present invention. It is a top view.

FIG. 5 is an enlarged sectional view for explaining the jig fixing portion shown in FIG.

FIG. 6 is a cross-sectional view showing a base structure for vibration reduction according to a second embodiment of the present invention.

FIG. 7 is an enlarged sectional view showing a part of FIG. 6;

FIG. 8 is an enlarged sectional view showing an automatic return mechanism and its peripheral portion in FIG. 6;

FIG. 9 is a plan view for explaining an installation position of the automatic return mechanism shown in FIG. 6;

FIG. 10 is a plan view for explaining an installation location when a vibration absorbing damper mechanism is installed in a second embodiment of the present invention.

FIG. 11 is a cross-sectional view showing a base structure for vibration reduction according to a third embodiment of the present invention.

FIG. 12 shows a relationship between a vibration transmissibility when a spring is interposed between the ground and a structure thereon, and a frequency ratio based on a ratio of a natural period of the ground to a natural period of the spring. It is a characteristic diagram.

FIG. 13 is a diagram illustrating a vibration transmission rate when an elastic body of an automatic return mechanism is interposed between the ground and a house in the present invention, and a frequency ratio based on a ratio between a natural period of the ground and a natural period of the elastic body. FIG. 6 is a characteristic diagram showing the relationship of FIG.

FIG. 14 is a partial perspective view for explaining a fourth embodiment of the present invention.

FIG. 15 is a partial perspective view for explaining the operation of the fourth embodiment of the present invention.

[Explanation of symbols]

 Reference Signs List 10 house 20 ground 30 ground side concrete foundation 40 house side concrete foundation 45, 80 anti-vibration material 50 friction reducing material 60 automatic return mechanism 61 ground side fixed plate 62 house side fixed plate 63 elastic body

 ──────────────────────────────────────────────────続 き Continuation of the front page (71) Applicant 500408740 Disaster Prevention Basic Development Co., Ltd. 6-12-16 Honkomagome, Bunkyo-ku, Tokyo (72) Inventor Naganori Sato 2-14-6, Daimachi, Hachioji-shi, Tokyo F-term (Reference) 2D046 AA14 BA00 DA13 DA14 3J048 AA03 AC01 AC05 AD05 BA24 BG04 DA01 EA38

Claims (24)

[Claims] 1. A ground-side foundation formed on the ground on which a house is built; a housing-side foundation formed at a lower part of the house and placed on the ground-side foundation; a ground-side foundation and the house-side foundation When the ground-side foundation horizontally vibrates due to an earthquake by setting the friction coefficient of the friction-reducing material to be in the range of 0.05 to 0.5. The horizontal vibration is reduced and transmitted to the house-side foundation, and furthermore, the vibration is made within a maximum single amplitude of 35 cm or less. 2. The base structure for seismic vibration reduction according to claim 1, wherein the friction reducing material is selected from a sheet or plate member made of synthetic resin or metal, a powder or particle material, and a coating material. A base structure for seismic reduction of houses. 3. The base structure for housing seismic reduction according to claim 1, wherein the ground-side foundation is a solid foundation, a cloth foundation, or a combination thereof, having a flat portion on an upper surface, and the housing-side foundation. Is a solid foundation, a cloth foundation, or a combination thereof, having a flat portion at a location corresponding to the flat portion of the ground-side foundation. 4. The substructure for seismic reduction of a house according to claim 3, wherein the ground-side foundation and the house-side foundation are respectively:
A base structure for seismic reduction of a house, characterized in that an underground beam and a ground beam are integrally formed on at least one of the reinforcing portions. 5. The base structure for seismic reduction of a house according to any one of claims 1 to 4, wherein the ground-side foundation is formed to be larger in area than the house-side foundation, and is located outside the house-side foundation. The jig for attaching the jig for returning the housing side foundation to the original position when the housing side foundation is displaced with respect to the ground side foundation due to the vibration accompanying the earthquake is attached to the ground side foundation. A base structure for housing seismic reduction characterized by providing fixtures at multiple locations. 6. The base structure for seismic reduction of a house according to any one of claims 1 to 4, wherein the house-side foundation is located between the house-side foundation and the ground-side foundation due to vibration caused by an earthquake. A base structure for seismic reduction of a house, wherein an automatic return mechanism for automatically returning the house side foundation to its original position when displaced with respect to a ground side foundation is provided at a plurality of locations. 7. The base structure for seismic reduction according to claim 6, wherein the automatic return mechanism includes a rubber body, a laminated body of rubber and a steel plate, or an elastic body made of a spring body.
The elastic body has a spring constant selected in advance by design, and the elastic body is configured so that a vertical load due to the weight of the housing-side foundation and the housing part thereon is not applied to the elastic body. A base structure for seismic reduction of a house, wherein the return mechanism also has a seismic reduction effect on the house-side foundation. 8. The base structure for seismic reduction of a house according to claim 7, wherein said rubber body is a high damping rubber body having high damping characteristics by mixing artificial rubber. Seismic foundation structure. 9. The base structure for seismic vibration reduction according to claim 7, wherein the automatic return mechanism is provided at a place where the house-side foundation and the ground-side foundation overlap each other. A ground-side fixed plate fixed to the ground-side foundation, a house-side fixed plate fixed to the upper surface side of the house-side foundation, and the ground-side fixed plate and the through-hole provided in the house-side foundation. A base for housing seismic reduction characterized by including a function of preventing the housing-side foundation including a house part from being lifted by strong wind or the like by including the elastic body connected to a housing-side fixing plate. Construction. 10. The base for seismic vibration reduction according to claim 9, wherein said through hole has a size that allows at least a maximum single amplitude of 35 cm of said elastic body. Construction. 11. The base structure for seismic reduction according to any one of claims 1 to 10, wherein the housing-side foundation is further provided between the housing-side foundation and the ground-side foundation by horizontal vibration accompanying an earthquake. A base structure for seismic reduction of houses, characterized by installing damper mechanisms at multiple locations to absorb horizontal vibrations when the maximum amplitude of a building exceeds a predetermined value. 12. The housing seismic reduction base structure according to any one of claims 1 to 11, wherein the plate-like structure is fixed to the house side foundation between the house side foundation and the friction reducing material. A base structure for seismic reduction of a house, characterized in that the vibration damping material is provided to attenuate the vertical vibration of the house-side foundation. 13. The base structure for seismic reduction of a house according to any one of claims 1 to 12, wherein a column on a house side is assembled on said house side foundation via a wooden base, and corresponds to said pillar. A base structure for seismic reduction of a house, wherein at least one hole for attaching a hole-down metal fitting to the house side foundation and the pillar is provided in the house side foundation portion in advance. 14. The base structure according to claim 1, wherein the ground-side foundation is a solid foundation, a cloth foundation, or a combination thereof, having a flat portion on an upper surface, and the housing-side foundation. Is a steel-made foundation having a flat portion at a place in contact with a flat portion of the ground-side foundation. 15. The substructure for seismic reduction of a house according to claim 14, wherein an underground beam and a ground beam are integrally formed on at least one of the ground-side foundation and the house-side foundation as a reinforcing portion. A base structure for seismic reduction of houses. 16. The base structure for seismic vibration reduction according to claim 14 or 15, wherein said ground-side foundation is formed so as to be larger in area than said housing-side foundation, and said ground-side outside said housing-side foundation. In the foundation, a jig fixing portion capable of attaching a jig for returning the housing-side foundation to its original position when the housing-side foundation is displaced with respect to the ground-side foundation due to vibration accompanying an earthquake. Base structure for housing seismic reduction characterized by being provided at multiple locations. 17. The base structure for seismic reduction according to claim 14 or 15, wherein the housing-side foundation is provided between the housing-side foundation and the ground-side foundation by vibration caused by an earthquake. A base structure for seismic reduction of a house, characterized in that an automatic return mechanism is provided at a plurality of places for automatically returning the house side foundation to its original position when displaced. 18. The base structure for seismic vibration reduction according to claim 17, wherein said automatic return mechanism includes an elastic body made of a rubber body, a laminated body of rubber and steel plate, or a spring body, and said elastic body is designed in advance. By having a spring constant selected by, the elastic body is configured not to apply a vertical load due to the weight of the housing-side foundation,
A base structure for seismic reduction of a house, wherein the automatic return mechanism also has a seismic reduction effect on the house-side foundation. 19. The base structure for seismic reduction according to claim 18, wherein said rubber body is a high damping rubber body having a high damping characteristic by mixing artificial rubber. Seismic foundation structure. 20. The base structure for seismic vibration reduction according to claim 18 or 19, wherein the automatic return mechanism is provided at a location where the house-side foundation and the ground-side foundation overlap each other. A ground-side fixed plate fixed to the ground-side foundation, a house-side fixed plate fixed to the upper surface side of the house-side foundation, and the ground-side fixed plate and the through-hole provided in the house-side foundation. A base for housing seismic reduction characterized by including a function of preventing the housing-side foundation including a house part from being lifted by strong wind or the like by including the elastic body connected to a housing-side fixing plate. Construction. 21. The base for seismic vibration reduction according to claim 20, wherein said through-hole has a size that allows at least a maximum single amplitude of 35 cm of said elastic body. Construction. 22. The base structure for seismic reduction according to any one of claims 14 to 21, wherein the housing-side foundation is further provided between the housing-side foundation and the ground-side foundation by horizontal vibration caused by an earthquake. A base structure for seismic reduction of houses, characterized by installing damper mechanisms at multiple locations to absorb horizontal vibrations when the maximum amplitude of a building exceeds a predetermined value. 23. The housing seismic reduction base structure according to any one of claims 14 to 22, wherein the plate-like structure is fixed to the house side foundation between the house side foundation and the friction reducing material. A base structure for seismic reduction of a house, characterized in that the vibration damping material is provided to attenuate the vertical vibration of the house-side foundation. 24. The housing seismic reduction base structure according to any one of claims 14 to 23, wherein a house-side pillar is assembled on said house-side foundation via a wooden base, and corresponds to said pillar. A base structure for seismic reduction of a house, wherein at least one hole for attaching a hole-down metal fitting to the house side foundation and the pillar is provided in the house side foundation portion in advance.