JP3095952U - Seismic foundation structure - Google Patents

Abstract

(57) [Abstract] (Modified) [Problem] An earthquake-resistant foundation for insulating a base and an upper building structure to mitigate earthquake shaking and impact on the building structure, in particular, impact during vertical pitching. Provide structure. SOLUTION: The earthquake-resistant foundation structure of the present invention is provided on the surface of a base 5 (usually formed by digging the ground to a required depth, laying a ballast or the like on the surface, tamping and leveling the ground). A first foundation 1 made of concrete, a small piece of elastic material (resin, rubber, etc.) (a chip 6 of a rubber piece scraped from a used tire, etc.) is bonded to an adhesive component (moisture-curable urethane adhesive or the like). An intermediate layer 2 that is three-dimensionally joined by a one-component urethane adhesive or the like and a second concrete base are sequentially laminated.

Description

[Detailed description of the device]

[0001]

[Technical field to which the device belongs]

  The present invention relates to a seismic foundation structure. More specifically, the foundation and the upper building structure Insulates and protects building structures from shaking and impacts during an earthquake, especially those caused by pitching. It relates to seismic foundation structures for mitigation. The present invention is relatively suitable for general private houses, etc. Widely used in small-scale building structures.

[0002]

[Prior art]

  In a building structure, the invariance of the structure itself is always maintained for stable long-term loads such as its own weight. It is required with a high safety factor. However, it is fatal for short-term loads such as earthquakes that are difficult to predict. There is no choice but to allow partial destruction. Usually, a design based on this idea However, in reality, many building structures will be fatally damaged if a strong earthquake occurs. It is not uncommon for people to receive the treatment. Thus, at present, seismic structures are not always It has not been established, and it has been piloted in some schools, research institutes, high-rise buildings, etc. It has only been incorporated.

[0003]   In addition, especially for small-scale building structures such as general private houses, seeds for improving strength are used. To some extent, some measures have been taken to improve rolling, such as rolling due to bracing. ing. However, the design and construction taking into account the vertical pitching during an earthquake are practically done. The reality is not. It is not easy to deal with this pitch, but As a foundation structure and construction method considering, whether an elastic body is used between the first foundation and the second foundation. A laminate of the intermediate layers is disclosed (for example, see Patent Document 1).

[0004]

[Patent Document 1]         Japanese Patent Laid-Open No. 10-54043

[0005]

[Problems to be solved by the device]

  According to the earthquake-resistant foundation structure described in Patent Document 1, the damage to the building structure is sufficiently suppressed. It is possible, but the intermediate layer in this earthquake-resistant foundation structure has specific physical properties, etc. In this case, it is possible to more fully cope with the pitching during an earthquake.   The present invention has been made in view of the above circumstances, and includes a foundation, a foundation, and a building structure. By specifying the physical properties of the elastic intermediate layer that is interposed between the object and the By reducing the amount of decrease in the thickness of the middle layer when a load is applied, it is possible to A seismic base that can mitigate vibrations and impacts on the building structure, especially impacts caused by pitching. The purpose is to provide the foundation structure.

[0006]

[Means for Solving the Problems]

The present invention is as follows. 1. A concrete first foundation provided on the surface of the base, an intermediate layer in which small pieces made of an elastic material are three-dimensionally bonded by an adhesive component, and a second concrete foundation are laminated in this order. Earthquake-resistant basic structure characterized by that. 2. 1. The small piece is a chip made of a rubber piece scraped from a used tire. Seismic foundation structure described in. 3. 1. In which the small piece is a curved columnar body. Or 2. Seismic foundation structure described in. 4. 2. The columnar body is a prismatic body, and the intermediate layer has a mixture of a prismatic body having a square cross section and a rectangular prismatic body having a rectangular cross section. Seismic foundation structure described in. The shape and dimensions of the cross section of the above "prism" in the length direction may be constant or may change. In particular, it may be gradually thin on one end side in the length direction. 5. 2. The lengthwise dimension of the columnar body is 2 to 5 times the maximum radial dimension. Or 4. Seismic foundation structure described in. 6. 1. The adhesive component is 15 to 40 parts by mass when the small piece is 100 parts by mass. Through 5. Seismic-resistant foundation structure described in any of. 7. 1. The adhesive component comprises a one-pack type urethane adhesive. To 6. Seismic-resistant foundation structure described in any of. 8. A film made of the adhesive component is formed around the small piece, and the small piece is three-dimensionally bonded by the adhesive component. Through 7. Seismic-resistant foundation structure described in any of. 9. 7. A void is formed between the small pieces on which the film is formed. Seismic foundation structure described in. 10. 1. The thickness of the intermediate layer is 10 to 100 mm. Through 9. Seismic-resistant foundation structure described in any of. 11. The thickness of the intermediate layer is set to 20 mm, and the amount of decrease in thickness when a load of 170 to 175 kPa is applied to the intermediate layer is 25 × 10 ⁻² mm or less. Through 10. Seismic-resistant foundation structure described in any of. Decrease in thickness (mm) = thickness before applying load (mm) -thickness when applying load (mm) 12. 11. The reduction amount is 15 × 10 ^{−2 to} 25 × 10 ⁻² mm. Seismic foundation structure described in. 13. The thickness of the intermediate layer is set to 20 mm, and a load of 32.5 to 36.5 kPa, 68 to 72 kPa, 102 to 106 kPa, 137 to 141 kPa, and 17 1.5 to 175.5 kPa is continuously applied to the intermediate layer in this order. When each of them is loaded for 30 minutes, the amount of decrease in thickness after 30 minutes in each stage is 2.5 × 10 ^{−2 to} 5.5 × 10 ⁻² mm and 7.5 × 10 ^{−, respectively. 2 ~10.5 × 10 - 2 mm,} 12 × 10 -2 ~16 × 10 -2 mm, 16.5 × 10 -2 ~1 9.5 × 10 -2 mm and 20.5 × 10 ^-2 ~ The above 1. which is 23.5 × 10 ⁻² mm. Through 10. Seismic-resistant foundation structure described in any of. 13. Reduction amount of thickness (mm) = thickness before applying load (mm) −thickness when applying load (mm) 14. The reduction rate of the thickness when a load of 170 to 175 kPa is applied to the intermediate layer is 1.25% or less. Through 10. Seismic-resistant foundation structure described in any of. 14. Reduction rate of thickness (%) = [{thickness before applying load (mm) -thickness when applying load (mm)} / thickness before applying load (mm)] × 100 15. 14. The reduction rate is 1.05 to 1.25%. Seismic foundation structure described in. 16. Loads of 32.5 to 36.5 kPa, 68 to 72 kPa, 102 to 106 kPa, 137 to 141 kPa, and 171.5 to 175.5 kPa are continuously applied in this order for 30 minutes to the intermediate layer, respectively. The reduction rate of the thickness after 30 minutes in the step is 0.18 to 0.24%, 0.42 to 0.48%, 0.66 to 0.72%, 0.90 to 0.96, respectively. % And 1.10 to 1.16%. Through 10. Seismic-resistant foundation structure described in any of. Reduction rate of thickness (%) = [{thickness before applying load (mm) -thickness under load (mm)} / thickness without load (mm)] × 100 17. The first base has an overhanging portion that projects obliquely downward at least at a part of the peripheral edge thereof. Through 16. Seismic-resistant foundation structure described in any of. 18. At least one of the first foundation and the second foundation and the intermediate layer are prevented from being displaced from each other by displacement preventing means. Through 17. Seismic-resistant foundation structure described in any of. 19. 18. The shift prevention means is a reinforcing bar embedded over at least one of the first foundation and the second foundation and the intermediate layer. Seismic foundation structure described in. 20. The building structure is constructed on the upper surface of the second foundation, and the load of 7 to 11 kPa is applied. Through 19. Seismic-resistant foundation structure described in any of.

[0007]

[Effect of device]

According to the seismic-resistant foundation structure of the present invention, shaking and shock during an earthquake, especially shock due to pitching, are absorbed and alleviated by the intermediate layer, and damage to the building structure is suppressed. In addition, when the small piece is a chip made of a rubber piece scraped off from a used tire, shaking and shock during an earthquake, particularly shock due to pitching is more absorbed and mitigated. Furthermore, when the small piece is a curved columnar body, it is possible to form an intermediate layer that is hard to break and has high strength. Further, when the columnar body is a prismatic body and the intermediate layer has a mixture of a prismatic body having a square cross section and a rectangular prismatic body having a rectangular cross section, it is more difficult to break and has a higher strength. It can be a layer. Furthermore, when the lengthwise dimension of the columnar body is 2 to 5 times the maximum dimension in the radial direction, shaking and impact during an earthquake are more fully absorbed and alleviated. Further, when the adhesive component is 15 to 40 parts by mass when the small piece is 100 parts by mass, the intermediate layer has sufficient strength and a uniform thickness. Furthermore, when the adhesive component is a one-pack type urethane adhesive, the workability in forming the intermediate layer is excellent. Also, when a film made of an adhesive component is formed around the small pieces and the small pieces are three-dimensionally bonded by the adhesive component, the shaking and impact during an earthquake are sufficiently absorbed and alleviated. . Further, in the case where voids are formed between the pieces on which the film is formed, it is possible to provide an intermediate layer in which shaking and impact are more sufficiently absorbed and alleviated. Further, when the thickness of the intermediate layer is 10 to 100 mm, the effect of alleviating shaking and impact is sufficiently exhibited. Furthermore, when the thickness of the intermediate layer is 20 mm and the amount of decrease in thickness when a load of 170 to 175 kPa is applied to the intermediate layer is 25 × 10 ⁻² mm or less, the earthquake is stable over a long period of time. The impact due to is absorbed and relieved. If the thickness of the intermediate layer is 20 mm and the amount of decrease in thickness when a specific load is applied to the intermediate layer stepwise for a certain period of time is within the prescribed range, the impact from the earthquake is sufficient. It is possible to obtain a stable earthquake-resistant foundation structure that is absorbed by and is relaxed. Furthermore, when the reduction rate of the thickness when the load of 170 to 175 kPa is applied to the intermediate layer is 1.25% or less, the shock due to the earthquake is stably absorbed and mitigated for a long period of time. In addition, if the reduction rate of the thickness when a specific load is gradually applied to the intermediate layer for a certain period of time is within the predetermined range, the shock due to the earthquake is sufficiently absorbed, relaxed and stable. It can be a seismic foundation structure. Furthermore, when the first foundation has a projecting portion that projects obliquely downward at least at a part of the peripheral edge thereof, the entire seismic-resistant foundation structure can be made more stable. Further, when at least one of the first foundation and the second foundation and the intermediate layer are prevented from being displaced from each other by the displacement preventing means, a more stable earthquake-resistant foundation structure can be obtained. Furthermore, when the displacement prevention means is a reinforcing bar embedded over at least one of the first foundation and the second foundation and the intermediate layer, the seismic-resistant foundation structure with higher stability can be obtained. . Moreover, when the building structure is constructed on the upper surface of the second foundation and a load of 5 to 15 kPa is applied, the earthquake resistance of the earthquake resistant foundation structure is sufficiently exhibited.

[0008]

[Embodiment of device]

  Hereinafter, the present invention will be described in detail.   (1) First foundation   The above-mentioned "first foundation" is usually made by digging the ground to the required depth and After laying the last, etc., tamping and leveling to form the above "base", concrete It can be formed by pouring a sheet and solidifying. This first foundation Usually, the required number of reinforcing bars, etc. are embedded and strengthened at regular intervals. . The thickness of the first base is not particularly limited, but is 50 to 200 mm, particularly 50 to 15 mm. It can be 0 mm, further 90 to 110 mm. This thickness is less than 50 mm Is insufficient in strength, and sufficiently supports the second foundation and the building structure in case of an earthquake. It may not be possible. Also, this thickness of 200 mm is usually sufficient.   Further, at least a part of the peripheral edge of the first foundation is If a projecting part is provided that projects diagonally downward, the first foundation is It will be more stable.

[0009]   (2) Middle layer   As shown in FIG. 1, the above-mentioned “intermediate layer” is made up of a small piece made of an elastic material that depends on the adhesive component. The first foundation, which is three-dimensionally connected and shakes with the ground during an earthquake, Insulates the foundation and building structure of 2 and absorbs and buffers the shaking and shock caused by an earthquake Have an effect. This intermediate layer is usually provided over almost the entire upper surface of the first foundation. To be It should be noted that in FIG. 1, the ends of each chip are depicted as having corners. However, in practice, these tips are primarily located at one or both ends of the length direction. Tapered tip on one side and one or both tips rounded Chips, etc.

[0010]   Examples of the "elastic material" include resins and rubbers. As a resin, General-purpose resins such as reolefin, polyamide, polyester, polyvinyl chloride To be Further, as the rubber, styrene-budadiene rubber, acrylonitrile- Butadiene rubber, chloroprene rubber, ethylene-propylene rubber, ethylene-propylene rubber Examples thereof include synthetic rubber such as ropylene-diene rubber and natural rubber. This elastic element The material is the middle layer, which has a large effect of absorbing and mitigating shaking and shock during an earthquake. The rubber that can be used is more preferable.

[0011]   The shape of the above "small pieces" (hereinafter referred to as "chips") made of elastic material is particularly limited. Not defined, columnar shape (transverse cross section may be circular or elliptical), prismatic shape (cross section) The shape of the surface may be a square, a rectangle, a parallelogram, a trapezoid, or the like. ), Spherical, It may be oval or string-shaped. If the tip is columnar, then straight It may be present or curved, but it is preferably curved. The tip is curved If it is, the chips can be easily entangled with each other to form a stronger intermediate layer. It Furthermore, if the tip is cylindrical, prismatic, string-shaped, etc. The shape and size of the cross section may be substantially constant or may be changed. Especially the length It may be gradually tapered on one or both end sides (one or both ends) May have a rounded tip. ). In addition, the middle layer has a square cross section. Shaped and curved prismatic chip [see Fig. 2 (A)] and rectangular cross section Shape and curved flat prismatic chip [see FIG. 2 (B)] Good. Furthermore, these chips and one or both ends of the length of each chip The tip is gradually thinned (even if one or both tips are rounded) Good. ) And may be mixed. Also, all the chips have a similar shape Alternatively, chips having different shapes may be mixed. Furthermore, this chip The length should be 2 to 10 times the maximum dimension in the radial direction, especially 2 to 5 times long and slender. And are preferred. Such an elongated shape, for example, the shape of a seaweed "Hijiki" If so, the chips are easily entangled with each other, and the strength of the intermediate layer is improved.

[0012]   The specific dimensions of the tip are 2 to 8 mm in length, especially 3 to 6 mm, the maximum in the radial direction. It is preferable that the dimension is about 0.2 to 2 mm, especially about 0.5 to 1.5 mm. Change In addition, with such dimensions, the length is 2 to 10 times the maximum dimension in the radial direction, especially More preferably, it is about 2 to 5 cultures. It ’s an elongated chip like this However, it can be mixed sufficiently uniformly with the adhesive component containing the adhesive component, and , The adjacent chips are entangled with each other to form an intermediate layer that is hard to break and has high strength. You can

[0013]   The chip is made of an elastic material such as resin or rubber. This chip is a rubber molded product , Scrap material in the manufacturing process of resin molded products, rubber pieces scraped from used tires (Rubber pieces scraped from raw tires when manufacturing recycled tires) And various rubber molded products and resin molded products such as waste tires and discarded tires are crushed. It is preferable to use a chip or the like. Use of these scraps or scraps Meets the needs of the age of resource reuse, and the cost of the middle class Can be drastically reduced. Recycled tires are generally manufactured for trucks. However, it is not limited to this. Further, as the waste material, a waste tire is particularly preferable. Ta The ear rubber has excellent weather resistance due to the combination of UV absorbers, etc. Obtained by crushing chips made of rubber pieces scraped from tires and waste tires, etc. All of the rubber chips used have excellent durability and are made of an intermediate layer that requires a long service life. Suitable for formation.

[0014]   The above-mentioned "adhesive component" is a component that is contained in the adhesive and three-dimensionally joins the chips. Examples of this adhesive component include various resins and rubbers. Adhesion used The agent is not particularly limited, and it is preferable to appropriately select it depending on the material of the chip and the like. An example For example, chips made of rubber pieces scraped from raw tires when manufacturing recycled tires, When using rubber chips such as those obtained by crushing waste tires, It is preferable to use an adhesive. As this rubber adhesive, Examples of the adhesive include an adhesive obtained by dissolving a rubber in an organic solvent, or an emulsion adhesive. It Also, one-component urethane adhesives, adhesives containing vinyl pyridine rubber, etc. Can also be used. Of these, it is easy to adjust the viscosity, curing time, etc. Therefore, a one-pack type urethane adhesive that is excellent in workability during use is particularly preferable.

[0015]   A moisture-curing urethane adhesive is used as the one-component urethane adhesive. There are many. This moisture-curable urethane adhesive is generally used in excess of polyols. It is obtained by reacting polyisocyanate and has a isocyanate group at the molecular end. Contains a repolymer. Further, as the polyols, polyether polyol However, as polyisocyanate, diphenylmethane diisocyanate is costly. Also, it is preferable in terms of workability.

[0016]   The amount of the adhesive compounded is not particularly limited, but when the chip is 100 parts by mass, Blend so that the adhesive component is 15 to 40 parts by mass, especially 20 to 30 parts by mass. Is preferred. If this adhesive component exceeds 40 parts by mass, the adhesive component such as rubber or the like Depending on the type, the strength of the intermediate layer may be insufficient. On the other hand, the adhesive component is 15 mass If it is less than a part, that is, if the number of chips is relatively large, the workability during stirring and mixing decreases, The viscosity of the mixture increases. As a result, workability when spreading on the upper surface of the first foundation is improved. It is not easy to form an intermediate layer having a uniform thickness.

[0017]   A film consisting of an adhesive component is formed around the chip, and due to this adhesive component The chips are three-dimensionally bonded and voids are formed between the coated pieces. There is. It is considered that there are many closed cells in the voids generated in this intermediate layer, but there are some communication holes. It may be generated. However, even if the communication holes are formed, the intermediate layer is Because it is pressed by a fairly large surface of the foundation and the building structure, the air inside The intermediate layer is not easily deformed by being discharged in a short time. Therefore, the void is In some cases, even if there is a communication hole in some areas, the middle layer will not be affected by the shaking and impact of the earthquake. It does not easily deform and maintains a sufficient shake and shock absorbing function for a long period of time. It

[0018]   The thickness of this intermediate layer is not particularly limited, but can be 10 to 100 mm. 20 to 80 mm, particularly 30 to 70 mm, and more preferably 40 to 60 mm Good If the thickness of the intermediate layer is 10 to 100 mm, there is sufficient cushioning and shock absorbing action. Played in minutes. If this thickness is less than 10 mm, the effect of alleviating shaking and impact is sufficient. If it exceeds 100 mm, it depends on the hardness and rigidity of the intermediate layer. It may be easily deformed during an earthquake, and in some cases it may not be able to withstand impact and may be destroyed. It is not preferable because it may happen.

Further, it is preferable that the reduction amount of the thickness when a load of 170 to 175 kPa is applied to the intermediate layer having a thickness of 20 mm is 25 × 10 ⁻² mm or less. The amount of decrease in thickness is preferably 23 × 10 ⁻² mm or less, more preferably 21 × 10 ⁻² mm or less (usually 15 × 10 ⁻² mm or more). When the thickness reduction amount exceeds 25 × 10 ⁻² mm, shaking and impact due to an earthquake may not be sufficiently mitigated.

[0020]   Furthermore, 32.5 to 36.5 kPa and 68 to 72 kP are provided on the intermediate layer having a thickness of 20 mm. a, 102 to 106 kPa, 137 to 141 kPa and 171.5 to 175.5. When the load of kPa is continuously applied in this order for 30 minutes, the amount of decrease in thickness is , 2.5 × 10 at each stage^-2~ 5.5 x 10^-2mm (preferred 2.5 × 10^-2~ 4.5 x 10^-2mm), 7.5 x 10^-2~ 10.5 x 10^-2mm (preferably 7.5 x 10^-2~ 9.5 x 10^{− Two} mm), 12 x 10^-2~ 16 x 10^-2mm (preferably 12 × 10 ^-2 ~ 15 x 10^-2mm), 16.5 x 10^-2~ 19.5 x 10^-2 mm (preferably 16.5 x 10^-2~ 18.5 x 10^-2mm) and 20 ． 5 x 10^-2~ 23.5 x 10^-2mm (preferably 20.5 x 10^{− Two} ~ 22.5 x 10^-2mm) is preferable. Thickness at each stage If the amount of decrease in depth exceeds the upper limit of each, shaking and impact due to earthquakes May not be fully mitigated over time.

[0021]   The amount of decrease in the above thickness changes depending on the thickness of the intermediate layer, but the thickness before applying a load The ratio of the reduction amount to the thickness, that is, the reduction ratio of the thickness is 170-175 kPa load. Is preferably 1.25% or less regardless of the thickness of the intermediate layer. Good This thickness reduction rate is 1.20% or less, particularly 1.15% or less (usually 1 ． It will be 05% or more. ) Is more preferable. Thickness reduction rate of 1.25% If it exceeds the limit, the shaking and impact from the earthquake may not be sufficiently mitigated.

[0022]   In addition, 32.5 to 36.5 kPa, 68 to 72 kPa, 102 to 10 in the intermediate layer. Loads of 6 kPa, 137 to 141 kPa and 171.5 to 175.5 kPa, The rate of decrease in thickness when continuously loaded for 30 minutes in this order is In 0.18 to 0.24% (preferably 0.18 to 0.22%), 0.42 ~ 0.48% (preferably 0.42-0.46%), 0.66-0.72% (good) 0.60-0.70%), 0.90-0.96% (preferably 0.90) ~ 0.94%) and 1.10 to 1.16% (preferably 1.10 to 1.14%) Is preferred. The reduction rate of thickness at each stage is the upper limit of each If it exceeds the range, it is possible to sufficiently mitigate the shaking and shock caused by the earthquake over a long period of time. It may not be possible.

[0023]   Note that this thickness reduction amount is based on the Society of Geotechnical Engineering Standards, for example, as in the examples described below. Design load according to the “Ground plate loading test method” (JSF standard T25-81) While gradually increasing the load to be exceeded in stages, at each load for a certain period of time, For example, it is obtained as a cumulative value when continuously loaded for 30 minutes, and the reduction rate is the reduction amount. Can be calculated based on

[0024]   The method for forming the intermediate layer is not particularly limited, but it is usually formed as follows. You can   First, a rubber chip or the like and an adhesive are stirred and mixed. Then the resulting mixture Is spread and molded on the upper surface of the first foundation at the construction site, and is naturally hardened. mixture After preparing the items, use a plaster trowel etc. and manually without using special equipment. The viscosity is preferably such that it can be easily spread. Also, that It is preferable that the curing speed is such that it completely cures after half a day to one day after the spreading is completed. In addition, it cures so fast that the workability of spreading is impaired, and it takes days to completely cure it. Delaying the schedule of other work is not desirable.

The first base is usually a rectangle, a square, or a planar shape in which these are combined, but since the intermediate layer can be formed by manually spreading the mixture, the first base has a flat surface. Regardless of the shape, it can be installed easily and in a short time. For example, construction of about 100 m ² per day is sufficiently possible. Further, by appropriately adjusting the viscosity of the adhesive, it can be cured in about half a day in the summer when the temperature is around 30 ° C., and can be cured in one day even in the winter, thus delaying other work. There is nothing like that. In addition, since this intermediate layer can be easily made into a continuous and homogeneous material regardless of the planar shape of the first foundation, it does not break from an inhomogeneous or discontinuous portion during an earthquake.

[0026]   (3) Second foundation   Like the first foundation, the "second foundation" is made of concrete, and The required number of rebars are embedded and strengthened inside the flat plate of the . This second foundation is equivalent to the foundation when it is not a normal seismic structure. First, pour concrete onto the upper surface of the intermediate layer and solidify it to form the flat plate. It The thickness of the flat plate portion is not particularly limited, but is 100 to 250 mm, particularly 100 It can be set to about 200 mm, further about 150 mm. This thickness is 100m If it is less than m, cracks may occur due to insufficient strength during an earthquake. Also usually A thickness of 250 mm is sufficient.

[0027]   In this 2nd foundation, of the standing part constructed according to the floor plan on the upper surface of the flat plate part. Bolts embedded inside are projected on the upper end surface, The placed base is fixed and a building structure is built on the upper surface. Earthquake resistance of the present invention The foundation structure is particularly useful for relatively small-scale building structures such as private houses. In the case of, usually 5 to 15 kPa, especially 6 to 14 kPa, and further 7 to 12 kPa. Degree load is applied. The flat plate portion and the upright portion of the second foundation are usually connected to each other. It is reinforced integrally by the reinforcing bar embedded in the shape of a gutter. Also, the middle layer and the second A tarpaulin similar to the one laid between a normal foundation and the ground. Can be laid.

[0028]   The first base, the intermediate layer and the second base may have the same planar dimensions, , The plane dimensions of the first foundation and the intermediate layer are substantially the same, and the plane dimension of the second foundation is It is preferable to make them a little smaller. In this way, increase the area of the substructure. With, the second foundation becomes more stable. The first foundation and middle layers are It is preferable to make it 100 to 300 mm wider than the second foundation over the entire periphery of the However, if this is 100 mm or less, the stabilization effect is insufficient, If you do so, a sufficient effect is achieved.

[0029]   Also, in the case of a particularly strong earthquake, the first foundation and the second foundation, and the middle layer There may be a gap between them. To prevent or at least suppress this deviation, At least one of the first base and the second base and the intermediate layer, It is preferable that they do not shift from each other. As this deviation prevention means , For example, unevenness may be provided on the surface of the first base and / or the surface of the intermediate layer, As shown in FIG. 8, the rebar 13 embedded in the first foundation is projected from the surface by the required length. Good. This reinforcing bar 13 requires the end of the embedded reinforcing bar to strengthen the flat plate. The length may be bent to project, or separately for the purpose of preventing misalignment. It may be embedded. In addition, the thickness of the intermediate layer The length may be made longer than that, and may be used together to prevent displacement between the second foundation and the intermediate layer. Also A reinforcing bar may be erected on the intermediate layer to prevent the gap from being displaced from the second foundation. Incidentally, rebar Not only can other rods with the required strength be used.

[0030]

【Example】

  Hereinafter, the present invention will be described in detail with reference to examples.   Example 1 (load resistance test of a test body formed in the same manner as the intermediate layer)   (1) Measurement status   A load resistance test of a test body formed in the same manner as the intermediate layer was performed according to JSF standard T25-81. It was carried out according to. The situation will be described below with reference to FIGS.   Crawler 1011 of heavy equipment (Yunbo, crane, bulldozer, etc.) 101 on the ground Form a groove with a predetermined depth slightly narrower than the space, and place the curing iron plate 108 on the bottom of the groove, A test body 109 was formed on the upper surface of the iron plate 108 for curing as described in (2) below. So After that, an iron load having a diameter of 30 cm and a thickness of 2.5 cm is loaded on the entire upper surface of the test body 109. The plates 105 are overlapped, and the hydraulic jack 104 is further attached to the center of the upper surface of the loading plate 105. Was placed. Then, the loading plate 105 is moved up and down via the magnet stand 107. Dial gauge (20 mm stroke, reading up to 1/100 mm) The reference beam 102 to which two 106 are attached is attached to both sides of the test body 109, etc. It was placed at a distance. These two reference beams 102 are magnet bases. It was fixed to the upper surface of the iron plate 108 for curing by 103. The magnet stand 10 7, dial gauge 106, reference beam 102 and magnet base 103 are integrated It was assembled in the model No. TK-121 manufactured by Teclock Co. It was By moving the cylinder of the hydraulic jack 104 up and down in this state, The load applied to 109 was adjusted.

[0031]   (2) Preparation of test specimen   Waste tires were crushed into rubber chips. This rubber tip is 3-6mm long Yes, the maximum dimension in the longitudinal direction is about 0.5 to 1.5 mm, and "Hijiki" seaweed It was moderately curved like. Then, this rubber chip and one-component urethane adhesive The agent and the mixture were put into a mixer and mixed by stirring. The one-component urethane adhesive is 25 parts by mass relative to 100 parts by mass of the rubber chip (substantially the entire amount of the adhesive component Become. ). Then, the obtained mixture is applied to the upper surface of the curing iron plate 108 by a plastering iron. A disc-shaped test body 109 having a diameter of 30 cm and a thickness of 20.05 mm is produced by spreading. did.

[0032]   (2) Preliminary test   With the device described in (1), a load of 20.6 kPa was applied to the test body, and then , Repeat the operation to release the load three times, before applying the load and applying the load The amount of reduction in thickness when released was read. The results are shown in Table 1. Also, 4 diamonds Table 1 also shows the average value obtained by arithmetically averaging the readings of the luggage. As a result, this preliminary trial The average value of the thickness of the test body after the test was 19.69 mm. Therefore, this value is The standard value of the thickness reduction rate and reduction rate in this test, that is, "thickness without load" And

[0033]

[Table 1]

[0034]   (3) Main test   Set the long-term allowable bearing capacity of the building structure to 29.4 kPa and slightly exceed this load. Load a load of 34.3 kPa for 30 minutes and scale each of 4 dial gauges. Were read and their average value was calculated. This average value and reference value (19.69m From the difference with m), the reduction amount and the reduction rate of the thickness were calculated. After that, every 30 minutes 69.6 kPa, 103.8 kPa, 139.2 kPa, 173.5 kPa , And after 30 minutes at each load, 4 diamonds The average value of the gauge reading and the reduction amount and reduction rate of the thickness were calculated. The thickness of The decrease of the load due to the decrease is caused by the hydraulic jack 10 in the thickness reduction rate measuring device 100. The stroke of 4 was adjusted and corrected.

[0035]   Load 34.3 kPa, 69.6 kPa, 103.8 kPa, 139.2 kPa And 173.5 kPa, the results are shown in Table 2, Table 3, Table 4, Table 5 and Table, respectively. 6 shows. In addition, the amount of decrease in thickness after 30 minutes at each stage is shown in the figure. 5 shows the reduction rate of thickness in FIG.

[0036]

[Table 2]

[0037]

[Table 3]

[0038]

[Table 4]

[0039]

[Table 5]

[0040]

[Table 6]

According to Table 2 and FIGS. 5 to 6, when a load of 34.3 kPa, which is slightly higher than the design load of 29.4 kPa, is applied, the amount of decrease in thickness after 30 minutes is 4.17 × 10 ^{−. The} thickness was ² mm and the thickness reduction rate was 0.21%. It can be seen that the thickness of the test piece is hardly reduced even when a load exceeding the design load is applied. Further, according to Tables 3 to 6 and FIGS. 5 to 6, the amount of decrease in thickness and the rate of decrease gradually increase with the increase of load and the cumulative time, but it is 5.9 times the design load, which is 173.5 kPa. Even when a load of 10 is applied, the amount of decrease in thickness after 30 minutes is 22.26 × 10 ⁻² mm, the rate of decrease in thickness is 1.13%, and the thickness before the test is substantially You can see that it is maintained. From these results, it can be inferred that the seismic-resistant foundation structure including the intermediate layer having the same composition and structure as this test piece can stably exert the effect of alleviating the shaking and impact caused by the earthquake over a long period of time. To be done.

Example 2 (Construction of Earthquake-Resistant Foundation Structure) An example of an earthquake-resistant foundation structure will be described below with reference to FIGS. (1) Formation of the first foundation The required area of the ground 4 is dug down to a predetermined depth, and a groove with a depth of 200 mm is dug further obliquely downward at the peripheral edge of the dug ground, ballast is spread, pressed and hardened to level the ground. The base 5 was formed. After that, the required amount of concrete is poured and allowed to stand for a required time to be hardened, and the first base 1 having a rectangular plane shape of 830 × 1230 cm, an area of 102 m ² , and a flat plate portion having a thickness of 100 mm is formed. Formed.

[0043]   When the first foundation 1 was formed, half of the concrete was poured, and Arrange the required number of rebars 11 on the top surface of the cleat at intervals of 150 mm, and leave the rest from above. I poured half the amount. In addition, when forming the first foundation 1, a groove dug in the periphery Also, concrete was poured in, and an overhanging portion 12 protruding obliquely downward was provided. Incidentally, as shown in FIG. 8, in order to prevent the displacement between the first foundation 1 and the intermediate layer 2, Before the concrete has completely hardened, fill the required number of reinforcing bars 13 to prevent misalignment. It was set in and projected from the surface by a length of about 50 mm.

(2) Formation of Intermediate Layer A rubber piece scraped from a used tire was used in a mixer equipped with a stirring blade having a capacity of 200 liters, and the cross-sectional shape was square or rectangular, and the average cross-sectional dimension was Is about 2 mm and the length is about 5 mm, and one or both ends of the lengthwise direction are gradually narrowed into a curved prismatic rubber tip (of which one or both ends are rounded) .) And a one-pack type urethane adhesive were added, and the mixture was stirred at room temperature for 10 minutes and mixed. The amount of the one-pack type urethane adhesive used was 25 parts by mass when the rubber chip was 100 parts by mass. Then, this mixture was poured onto the upper surface of the first foundation 1 formed in (1) and manually spread into a plate-shaped body having a thickness of 50 mm using a plaster for a plasterer. The work was started at 9:00 am, and the stirring, mixing, and spreading were repeated, and the spreading was almost the same as the area of the upper surface of the first foundation 1, that is, the spreading of 102 m ² was completed at 5 pm. there were. This was left until the next morning, and the adhesive was cured to form the intermediate layer 2.

(3) Formation of Second Foundation Concrete is poured onto the upper surface of the intermediate layer 2 formed in (2), and the plan shape is a rectangle of 800 × 1200 cm, the area is 96 m ² , and the thickness is The flat plate portion 31 of the second base 3 having a size of 150 mm was formed. The flat plate portion 31 was formed such that the outer peripheral edge thereof was located inside 150 mm over the entire peripheral edge of the intermediate layer 2. Further, as in the case of the first foundation 1, a required number of reinforcing bars 33 were embedded at an interval of 150 mm in the middle portion in the thickness direction for reinforcement. After that, a required metal frame was assembled on the upper surface of the flat plate portion 31 according to the floor plan, and concrete was poured into the frame and hardened to form the second foundation 3 having the standing portion 32. In addition, the end portion of the reinforcing bar 33 is projected into the metal frame to strengthen the flat plate portion 31 and the upright portion 32 integrally.

[0046]   Building a two-story house on the earthquake-resistant foundation structure constructed as in (1) to (3) Then, after the completion, the thickness of the intermediate layer 2 is changed at the boundary between the intermediate layer 2 and the second foundation. Upon visual observation, no significant change was observed. Thus, the intermediate layer 2 is It can withstand shrinkage sufficiently, and shakes and shocks are sufficiently mitigated during an earthquake. It is presumed to be one.

[Brief description of drawings]

FIG. 1 is an explanatory view showing an enlarged part of an intermediate layer.

FIG. 2A is a perspective view showing the outer appearance of a curved prismatic chip having a square radial cross section. (B)
FIG. 4 is a perspective view showing the appearance of a flat, prismatic chip with a rectangular radial cross section and a curved shape.

FIG. 3 is an explanatory diagram schematically showing a measurement situation in a load bearing test using a test body having the same composition and structure as the intermediate layer of the earthquake-resistant basic structure.

FIG. 4 is an enlarged explanatory view of a main part in the measurement situation of FIG. 3 viewed from the plane direction.

FIG. 5 is an explanatory diagram showing a correlation between a load and a thickness reduction amount in a load bearing test.

FIG. 6 is an explanatory diagram showing a correlation between a load and a reduction rate of thickness in a load bearing test.

FIG. 7 is a vertical cross-sectional view of the seismic resistant basic structure of the embodiment.

FIG. 8 is a vertical cross-sectional view showing, in an enlarged manner, a situation in which reinforcing bars for preventing displacement are embedded in the earthquake-resistant basic structure of the embodiment.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1; 1st foundation, 11; Reinforcing bar for reinforcement, 12; Projection part in the diagonally downward direction in the periphery of 1st foundation, 13: Rebar for preventing slippage, 2; Intermediate layer, 3; 2nd foundation, 31; flat plate part, 32; standing part, 33; reinforcing bar for reinforcement, 4; ground,
5; Base, 6; Chip, 101; Heavy Machinery, 1011; Crawler, 102; Reference Beam, 103; Magnet Base, 1
04; hydraulic jack, 105; loading plate, 106; dial gauge, 107; magnet stand, 108; iron plate for curing, 109; test body.

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[Procedure amendment]

[Submission date] April 10, 2003 (2003.4.1)
0)

[Procedure Amendment 1]

[Document name to be amended] Statement

[Name of item to be corrected] Claim 11

[Correction method] Change

[Correction content]

[Procedure Amendment 2]

[Document name to be amended] Statement

[Name of item to be corrected] Claim 13

[Correction method] Change

[Correction content]

[Procedure 3]

[Document name to be amended] Statement

[Name of item to be corrected] Claim 14

[Correction method] Change

[Correction content]

[Procedure amendment 4]

[Document name to be amended] Statement

[Name of item to be corrected] Claim 16

[Correction method] Change

[Correction content]

Claims (20)

[Scope of utility model registration request] 1. A first foundation made of concrete provided on the surface of a base, an intermediate layer formed by three-dimensionally bonding pieces of elastic material by an adhesive component, and a second foundation made of concrete. Seismic foundation structure characterized by being laminated in order. 2. The seismic-resistant foundation structure according to claim 1, wherein the small piece is a chip made of a rubber piece scraped from a used tire. 3. The seismic resistant foundation structure according to claim 1, wherein the small piece is a curved columnar body. 4. The seismic resistant foundation according to claim 3, wherein the columnar body is a prismatic body, and the intermediate layer is a mixture of a prismatic body having a square cross section and a rectangular prismatic body having a rectangular cross section. Construction. 5. The seismic-resistant foundation structure according to claim 3, wherein the dimension of the columnar body in the lengthwise direction is 2 to 5 times the maximum dimension in the radial direction. 6. When the small pieces are 100 parts by mass,
The adhesive component is 15 to 40 parts by mass.
The earthquake-resistant foundation structure according to any one of 1. 7. The seismic resistant basic structure according to claim 1, wherein the adhesive component is a one-component urethane adhesive. 8. The film according to claim 1, wherein a film made of the adhesive component is formed around the small piece, and the small piece is three-dimensionally bonded by the adhesive component. Seismic foundation structure described in. 9. The seismic-resistant foundation structure according to claim 8, wherein voids are formed between the small pieces on which the film is formed. 10. The intermediate layer has a thickness of 10 to 100 mm.
The earthquake-resistant foundation structure according to any one of claims 1 to 9. 11. The thickness of the intermediate layer is set to 20 mm, and the amount of decrease in thickness when a load of 170 to 175 kPa is applied to the intermediate layer is 25 × 10 ⁻² mm or less. The earthquake-resistant foundation structure according to any one of the items. Thickness reduction (mm) = thickness before applying load (m)
m) -Thickness under load (mm) 12. The reduction amount is 15 × 10 ^{−2 to} 25.
The seismic resistant basic structure according to claim 11, which has a size of × 10 ⁻² mm. 13. The intermediate layer has a thickness of 20 mm, and the intermediate layer has a thickness of 32.5 to 36.5 kPa and 68 to 72 kP.
a, 102 to 106 kPa, 137 to 141 kPa, and 171.5 to 175.5 kPa, when the load is continuously applied for 30 minutes each in this order, the amount of decrease in thickness after 30 minutes at each stage is 2.5 x 1 each
0 ^{−2 to} 5.5 × 10 ⁻² mm, 7.5 × 10 ⁻²
˜10.5 × 10 ⁻² mm, 12 × 10 ^{−2 to} 16
× 10 ⁻² mm, 16.5 × 10 ^{−2 to} 19.5 ×
10 ⁻² mm and 20.5 × 10 ^{−2 to} 23.5 × 1
0 ^-2 any one of claims 1 to 10 is mm
Seismic foundation structure described in paragraph. Thickness reduction (mm) = thickness before applying load (m)
m) -Thickness under load (mm) 14. The seismic-resistant foundation structure according to claim 1, wherein a reduction rate of the thickness when a load of 170 to 175 kPa is applied to the intermediate layer is 1.25% or less. . Reduction rate of thickness (%) = [{Thickness before applying load (m
m) -thickness under load (mm)} / thickness before load (mm)] x 100 15. The seismic-resistant foundation structure according to claim 14, wherein the reduction rate is 1.05 to 1.25%. 16. The intermediate layer contains 32.5 to 36.5 kP.
a, 68 to 72 kPa, 102 to 106 kPa, 137
When a load of up to 141 kPa and 171.5 to 175.5 kPa is continuously applied in this order for 30 minutes,
The reduction rate of the thickness after 30 minutes in each stage is 0.18 to 0.24% and 0.42 to 0.48, respectively.
%, 0.66 to 0.72%, 0.90 to 0.96%, and 1.10 to 1.16%, The seismic foundation structure according to any one of claims 1 to 10. Reduction rate of thickness (%) = [{Thickness before applying load (m
m) -thickness under load (mm)} / thickness without load (mm)] x 100 17. The earthquake-resistant foundation structure according to claim 1, wherein the first foundation has a projecting portion that projects obliquely downward at least at a part of a peripheral edge thereof. . 18. The method according to claim 1, wherein at least one of the first foundation and the second foundation and the intermediate layer are prevented from being displaced from each other by displacement preventing means. The seismic foundation structure described in paragraph 1. 19. The seismic-resistant foundation structure according to claim 18, wherein the displacement prevention means is a reinforcing bar embedded over at least one of the first foundation and the second foundation and the intermediate layer. . 20. The earthquake-resistant foundation structure according to claim 1, wherein a building structure is constructed on the upper surface of the second foundation, and a load of 5 to 15 kPa is applied. .