JP3677715B2 - Seismic isolation method for masonry buildings - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present inventionSeismic isolation method for seismic isolation of masonry buildingsIt is about.
[0002]
[Prior art]
In recent years, in order to preserve buildings with historical value, in order to protect the buildings from earthquakes that are expected to occur in the future, earthquake-resistant repairs have been carried out, or there has been an exemption between the foundation of the building and the ground. Construction to install seismic devices has been started.
[0003]
In such a seismic retrofit, it is common practice to install a reinforced concrete slab in order to reinforce the walls of historical buildings.
[0004]
In general, in order to install a seismic isolation device below an existing building, the building is supported by a temporary receiving jig, etc., and a jack is installed between the foundation of the building and the ground, After jacking up and replacing the temporary support jig with a seismic isolation device, the method of jacking down the building and supporting the building with the seismic isolation device is used. In many cases, it is a masonry structure made of stone or the like. In this case, since there is almost no unity of each member constituting the building, the above-described method cannot be simply adopted.
Therefore, the following methods are used to seismically isolate masonry buildings.
That is, as shown in FIG. 11, first, the ground 3 on both sides of the fabric foundation (foundation) 2 of the masonry building 1 is excavated, and the lower part of the fabric foundation 2 is dug in a tunnel shape, and a steel frame is provided there. A temporary mount 5 is inserted. Furthermore, this operation is successively performed in the direction in which the fabric foundation 2 extends.
[0005]
Subsequently, as shown in FIG. 12, the ground 3 below the temporary mount 5 is excavated, leaving a portion located below the fabric foundation 2. Further, the temporary mount 5 is supported from the ground 3 via the support frames 6 and 6, and the entire area below the temporary mount 5 is excavated.
[0006]
After that, as shown in FIG. 13, the bottom panel 8 and the retaining wall 9 are newly installed, and the seismic isolation device 10 is installed on the bottom panel 8. Furthermore, concrete is cast around the fabric foundation 2 to form a foundation beam 11, and a floor slab 12 is installed between the foundation beam 11 and another foundation beam (not shown). Then, the upper end 10 a of the seismic isolation device 10 is connected to the lower surface 11 a of the foundation beam 11 so that the masonry building 1 is supported by the seismic isolation device 10, and among the temporary mount 5 and the support frames 6, 6, the foundation beam 11 and the part protruding from the bottom board 8 are cut and removed, so that the masonry building 1 is seismically isolated.
[0007]
[Problems to be solved by the invention]
As described above, when a historic building is reinforced with reinforced concrete slabs to ensure earthquake resistance, the building weight increases, so the foundation of the building needs to be retrofitted. At this time, in the case where the historical building is masonry, in particular, since the holding strength of the foundation is small, a technique capable of effectively reinforcing the foundation has been desired.
[0008]
Further, when the masonry building 1 is subjected to seismic isolation as described above, since the cloth foundation 2 has almost no integrity as a member, the temporary base 5 is extended in the direction in which the cloth foundation 2 extends. It was necessary to install them almost continuously, which caused an increase in construction costs and a longer construction period.
Also, there are many examples of historic buildings of the old age, where the bottom floor is dirt concrete, and such buildings lack the plane rigidity of the foundation. Before excavating under the floor, it is necessary to change the floor to a structural slab in advance. Therefore, in such a case, a beam that can support the structural slab is separately required, and as a result, the problems such as the increase in the construction cost and the extension of the construction period as described above become more remarkable. It was.
[0009]
  The present invention has been made in view of the above circumstances,Its purpose isInstall seismic isolation devices at the foundation of masonry buildingsSeismic isolationIn comparison with the past, it is possible to reduce the cost and shorten the construction period of the temporary structure for supporting the building,MoreoverAn object of the present invention is to provide a seismic isolation method for a masonry building that does not require additional reinforcement even when the foundation rigidity of the masonry building is small.
[0016]
[Means for Solving the Problems]
  Claim 1The seismic isolation method for masonry buildings described above is to seismically isolate the building by interposing a seismic isolation device between the foundation of the masonry building and the ground supporting the foundation.On the basis of the aboveThe foundation is reinforced by applying a compressive force from a direction orthogonal to the extending direction of the foundation, and then the ground below the foundation is excavated between the foundation and the ground. Interposing the seismic isolation deviceBasic.
[0017]
In order to be configured as described above, in this seismic isolation method for masonry buildings, before installing the seismic isolation device, the foundation is reinforced to ensure the integrity of the foundation. be able to.
[0018]
  And claim 1Of listed masonry buildingsThe seismic isolation method isIn reinforcing the foundation, on both sides of the foundationWhile installing the reinforced concrete beam material over the entire length of the foundation,A tension member that penetrates the foundation and the beam material in a direction perpendicular to the extending direction of the foundation is provided.By tensioning the tendon,The compressive force is applied by applying a prestressing force to the beam material and the foundation.
[0019]
Since it becomes the above structures, in this seismic isolation method of a masonry building, a compressive force can be made to act favorably with respect to a foundation.
[0020]
  Claim 2The seismic isolation method for masonry buildings described is seismic isolation for isolating the building by interposing a seismic isolation device between the foundation of the masonry building and the ground supporting the foundation. A chemical method,By placing a tendon on both sides of the foundation and tensioning the tendon, a compressive force is applied to the foundation from its extending direction.The foundation is reinforced, and then the ground below the foundation is excavated, and the seismic isolation device is interposed between the foundation and the ground.
[0021]
In order to be configured as described above, in this seismic isolation method for masonry buildings, before installing the seismic isolation device, the foundation is reinforced to ensure the integrity of the foundation. be able to. Moreover, since it was set as the structure which applies compressive force with respect to the foundation from the extension direction, it is not necessary to reinforce the foundation completely from the side.
[0022]
  Claim 3The seismic isolation method for masonry buildings described isClaim 2The seismic isolation method for a masonry building according to claim 1, wherein the foundation is reinforced by installing loading bodies on both end faces in the longitudinal direction of the foundation in parallel with the end faces, andOn both sidesPlace the tendon, and support both ends of the tendon with the packing described above,By tensioning the tendon and fixing both ends to the loaded body,A prestressing force is applied to the foundation in the extending direction of the foundation through the load body described above, and thereby the compression force is applied.
[0023]
Since it becomes the above structures, according to the seismic isolation method of this masonry building, compressive force can be made to act on a foundation by simple structure.
[0024]
DETAILED DESCRIPTION OF THE INVENTION
  Prior to describing the embodiment of the present invention, a basic reinforcement technique for a foundation of a masonry building will be described as a reference example.
[Reference example]
FIG.The situation when the reinforcement structure 22 is newly provided with respect to the cloth foundation (foundation) 21a of the existing masonry building 21 is shown. Here, the longitudinal direction of the fabric foundation 21a is perpendicular to the paper surface.
[0025]
The reinforcing structure 22 includes a concrete structure 24 provided on both sides of the cloth foundation 21a, a sheath (not shown) provided so as to penetrate the cloth foundation 21a and the concrete structure 24, and a PC disposed in the sheath. It comprises a steel bar (tension material) 26,.
[0026]
Among these, the concrete structure 24 is a reinforced concrete structure in which a reinforcing bar (not shown) is embedded therein, and an installation area necessary to support the weight of the masonry building 21 is secured on the bottom surface 24a. It has been configured.
[0027]
Further, the PC steel bars 26,... Are arranged at a plurality of positions at a predetermined pitch in the extending direction of the fabric foundation 21a (the direction orthogonal to the paper surface). Further, a tension force is applied to the PC steel rods 26,..., And the tension force is applied to the concrete via anchor plates 28, 28 provided at both ends 26a, 26a of the PC steel rod 26. The structure is transmitted to the structure 24.
[0028]
In order to obtain the reinforcing structure 22 configured as described above, a side portion of the fabric foundation 21a in the ground G (see FIG. 1) in which the fabric foundation 21a is embedded is excavated to expose the fabric foundation 21a. Then, the cloth foundation 21a is drilled to provide a PC steel rod 26, through-hole for insertion, and the PC steel rod 26, ... is inserted into the through-hole.
[0029]
Next, a formwork is arranged so as to form a cross-sectional shape of the concrete structure 24 at a position away from the cloth foundation 21a on both sides of the cloth foundation 21a, and the reinforcing bars are assembled in this formwork. Further, concrete is placed in the mold, and anchor plates 28 are provided at both ends 26a, 26a of the PC steel bar 26. After the concrete is hardened, prestress is introduced into the PC steel bars 26,.
Thereby, the reinforcing structure 22 as shown in FIG. 1 is completed, and the reinforcement of the fabric foundation 21a is realized.
[0030]
As described above, in the reinforcing structure 22, since the fabric foundation 21a of the masonry building 21 is reinforced using prestress, the bending strength and shear strength of the fabric foundation 21a can be dramatically improved. Even when the weight of the building building 21 is increased by renovation, it is possible to easily cope with it.
[0031]
Further, since the masonry building 21 normally has a relatively high compressive strength from the beginning, it is possible to appropriately set the prestress introduced to the PC steel rods 26. . Further, the stress can be controlled so that cracks do not occur at the ends of the PC steel bars 26,... Due to changes over time, and durability can be ensured.
[0032]
Further, in the reinforcing structure 22, since the concrete structure 24 is made of reinforced concrete, a strong structure is formed on both sides of the fabric foundation 21a, thereby securing an installation area as a foundation. . In addition, this makes it possible to further improve the yield strength of the fabric foundation 21a and realize a structure suitable for introducing prestress.
[0033]
Moreover, in the reinforcement method of the above-mentioned masonry building 21, it can construct by digging down the side part of the fabric foundation 21a, and compared with the conventional reinforcement method which replaces all the foundation parts with a newly reinforced concrete structure. And workability is good. In addition, from the viewpoint of preservation, there is an advantage in that the current basics can be left as they are.
[0035]
  [First embodiment]
  Next, the present inventionFirst embodimentAn example will be described with reference to FIGS. FIG. 2 is a diagram illustrating the foundation 121a of the masonry building 121 that has undergone seismic isolation. The masonry building 121 is erected on a bottom board 123 provided in the ground 122. As shown in the figure, the masonry building 121 is configured such that its foundation 121a is located in a space T1 surrounded by a retaining wall 124 and a bottom plate 123 formed by excavating the ground 122. In addition, the base beam 126 is supported from the bottom plate 123 via a seismic isolation device 128 including a lead plug (not shown) and laminated rubber 127.
[0036]
Moreover, in the figure, the code | symbol 129 represents the cloth foundation (foundation) of the masonry building 121 before seismic isolation is performed. The fabric foundation 129 includes beam members 130 and 130 disposed on both sides thereof, concrete C placed between the beam member 130 and the fabric foundation 129, and flat beams 131 disposed below the fabric foundation 129. The foundation beam 126 is formed as a unit.
[0037]
The beam members 130 and 130 and the flat beam 131 are both formed of reinforced concrete and arranged along the cloth foundation 129. These beam members 130, 130 and the flat beam 131 are fastened by anchor reinforcing bars 132, 132,... Tightened by anchors 134 and 134.
[0038]
Further, the foundation beam 126 includes a cloth foundation 129, beam members 130 and 130, and concrete C placed therebetween, in a direction orthogonal to the direction in which the cloth foundation 129 extends (A in the figure).₁Sheaths 135 and 135 penetrating in the direction) are provided, and PC steel bars (tension members) 136 and 136 are inserted into the sheath 135. A tension force acts on the PC steel bars 136 and 136, and this tension force acts as a prestress force on the foundation beam 126 via the nuts 138, 138,... And the anchor plates 139, 139,. ing.
Furthermore, a floor slab 140 newly provided for base isolation of the masonry building 121 is provided on the foundation beam 126 so as to extend laterally.
[0039]
The above is the main configuration in the present embodiment. Next, a procedure for isolating the masonry building 121 will be described.
In order to make the masonry building 121 seismic isolation, first, the ground 122 around the foundation 121a in the masonry building 121 is excavated to expose the cloth foundation 129. Next, beam members 130 and 130 are formed along the fabric foundation 129. In forming the beam members 130, 130, first, the main bars 143, 143,... And the barbs 144, 144, etc. constituting the beam members 130, 130 are arranged along the cloth foundation 129. The mold 145 is arranged so as to surround the main bars 143, 143,. In addition, the post-installed anchor 134 is fixed to the throwing-away portion 133 so that the tip 134a protrudes into the mold 145.
[0040]
On the other hand, the cloth foundation 129 is formed with insertion holes 146, 146, and the sheaths 135, 135 are formed with the molds 145, 145 and the insertion holes 146, 146 in a direction perpendicular to the extending direction of the cloth foundation 129 (in the drawing). A₁(Direction). In addition, PC steel rods 136 and 136 are inserted into the sheaths 135 and 135.
[0041]
  Subsequently, by placing concrete inside the formwork 145, the beam members 130 and 130 and the concrete C portion are placed.As shown in FIG. 4, over the entire length of the fabric foundation 129Form. Thereafter, anchor plates 139 (see FIG. 2) are installed on both ends of the PC steel rods 136, 136 from the outer surface 130a (see FIG. 2) side of the beam member 130, and nuts 138 (see FIG. 2) are installed from the outside. By screwing, tension is applied to the PC steel bars 136 and 136. As a result, the prestressing force in the A1 direction is introduced into the beam members 130 and 130 and the cloth foundation 129.
[0042]
Thereafter, as shown in FIG. 4, the direction in which the fabric foundation 129 extends (B in the figure) on the ground 122 below the integrated fabric foundation 129 and the beam members 130 and 130.₁Are formed at intervals in the direction), and sanddles 148, 148,... Are further installed in the drill holes 147, 147,. Tentatively.
Further, as shown in FIG. 5, the fabric foundation 129 and the ground 122 below the beam members 130 and 130 are fully excavated, and the bottom plate 123 and the retaining wall 124 (see FIG. 2) are installed. Also, on the bottom plate 123, B in the figure₁The seismic isolation devices 128, 128, ... are installed at intervals in the direction.
[0043]
Thereafter, a flat beam 131 (see FIG. 2) is formed below the fabric foundation 129 and the beam members 130 and 130, and these are integrated to form the foundation beam 126 (see FIG. 2). Furthermore, the lower surface 126a (see FIG. 2) of the foundation beam 126 formed in this way is connected to the upper end 128a (see FIG. 2) of the seismic isolation device 128. On the other hand, a floor slab 140 is newly installed and integrated with the foundation beam 126. Further, by removing and dismantling the portions of the sandals 148, 148,... (See FIG. 5) that protrude from the bottom plate 123, the seismic isolation of the masonry building 121 is completed as shown in FIG. It will be.
[0044]
In the seismic isolation method for the masonry building 121 described above, when the seismic isolation device 128 is interposed in the foundation portion 121a of the masonry building 121, the fabric foundation 129 is compared with the fabric foundation 129 of the masonry building 121. By applying a compressive force from a direction perpendicular to the extending direction of the fabric, it is possible to ensure the integrity of the fabric foundation 129 as a member. This eliminates the need for continuous support. Therefore, it is possible to greatly reduce the cost and the amount of work involved in installing the temporary base.
[0045]
Further, in the seismic isolation method for the masonry building 121 described above, when reinforcing the cloth foundation 129, the beam members 130 and 130 are arranged on both sides of the cloth foundation 129, and these are integrated, A prestressing force is applied to the cloth foundation 129 and the beam members 130 and 130 by PC steel bars 136 and 136. Thereby, it is possible to reinforce the cloth foundation 129 and safely perform seismic isolation of the masonry building 121. Further, according to this construction method, before excavating the lower part of the fabric foundation 129, the main portion of the foundation beam 126 is formed in advance, for example, the bottom floor of the masonry building 121 Even when the floor has to be previously structured as a structural slab in order to ensure planar rigidity, it is not necessary to separately provide a beam for supporting the structural slab. Thereby, even when the lowest floor of the masonry building 121 is configured to lack planar rigidity such as dirt concrete, the construction can be easily and economically proceeded.
[0046]
In the above embodiment, a part of the configuration may be changed without departing from the gist of the present invention.
For example, instead of the PC steel bars 136 and 136, other tendons such as PC steel wires may be used.
Further, the seismic isolation device 128 does not have to be as in the above embodiment, and may have another shape / structure.
Moreover, in the said embodiment, although the cloth foundation 129 was made into the object of the seismic isolation construction method, you may make it apply this seismic isolation construction method to reinforcements other than a cloth foundation.
[0047]
  [Second embodimentNext, the present inventionSecond embodimentAn example will be described with reference to FIGS. FIG. 6 is a diagram illustrating the foundation 221a of the masonry building 221 subjected to seismic isolation. The masonry building 221 is erected on a bottom board 223 provided in the ground 222. As shown in the figure, the masonry building 221 is configured such that the foundation 221a is located in a space T2 surrounded by a retaining wall 224 and a bottom plate 223 formed by excavating the ground 222. In addition, the base beam 226 is supported from the bottom plate 223 via a seismic isolation device 228 made of a lead plug and laminated rubber 227 (not shown).
[0048]
The foundation beam 226 is formed by reinforcing the periphery of the fabric foundation (foundation) 229 of the masonry building 221 before the seismic isolation is performed with reinforced concrete R. Further, PC steel wires (tension materials) 231, 231,... Are arranged along the fabric foundation 229. These PC steel wires 231, 231,... Have a tension.
In addition, the foundation beam 226 is provided with a floor slab 233 newly provided to make the masonry building 221 base-isolated so as to extend laterally.
[0049]
FIG. 7 shows A in FIG.₂-A₂It is a figure which shows a cross section. On the end surface 229a of the fabric foundation 229, a loading body 235 integrated with the foundation beam 226 is disposed. Further, FIG. 8 shows B in FIG.₂-B₂It is a figure which shows a cross section. As shown in the figure, the loading body 235 is formed so that the cross section thereof is substantially L-shaped, and is arranged along both the end surface 229a of the fabric base 229 and the end surface 234a of another fabric base 234. The
[0050]
7 and 8, the loading body 235 has through holes 235a, 235a,..., And the end portions 231a, 231a,. , 235a,... Further, the tip of the end portion 231 a of each PC steel wire 231 is fixed to a cone 236 embedded in the loading body 235. Thereby, the tension of the PC steel wire 231 is transmitted to the loading body 235 through the cone 236.
[0051]
In addition, the loaded body 235 and the cone 236 are similarly provided on the other end face side (not shown) of the fabric foundations 229 and 234. Thereby, the tension force of the PC steel wires 231, 231,... Acts as a compressive force in the extending direction on the cloth foundations 229 and 234 via the loading body 235.
[0052]
The above is the main configuration of the present embodiment. Next, a procedure for isolating the masonry building 221 will be described.
In order to make the masonry building 221 seismic isolation, first, the ground 222 around the foundation portion 221a in the masonry building 221 is excavated to expose the fabric foundations 229 and 234. Next, the loading body 235 is disposed along the end surfaces 229a and 234a of the fabric foundations 229 and 234, and further, the PC steel wires 231, 231,. FIG. 9 shows a cross section of the fabric foundation 229 or 234 at this time. At this time, the end portions 231a, 231a of the PC steel wires 231, 231,... Are inserted into the through holes 235a, 235a,.
[0053]
Next, tension is applied to the PC steel wires 231, 231,..., And the end portions 231 a and 231 a of the PC steel wires are fixed to the cones 236, 236,. By performing this operation on both ends of the PC steel wires 231, 231,..., A compressive force is applied to the cloth foundations 229 and 234 via the loading body 235 in the extending direction.
[0054]
Subsequently, as shown in FIG. 10, the ground 222 below the fabric foundation 229 is excavated to form an excavation hole 238. At this time, the excavation hole 238 is formed so that the depth of the bottom surface 238a coincides with the depth of the installation target position of the bottom plate 223 (see FIG. 6). In addition, a sanddle 239 is installed on the bottom surface 238 a of the excavation hole 238, and the fabric foundation 229 is supported by the sanddle 239 and the supporting work 240 supported on the sanddle 239.
[0055]
By installing the sanddle 239 and the support work 240 at intervals in the extending direction of the cloth foundation 229, the cloth foundation 229 is temporarily received by the sanddle 239 and the support work 240. Further, the ground 222 below the fabric foundation 229 is then excavated entirely.
[0056]
When the ground 222 below the cloth foundation 229 is excavated, next, seismic isolation devices 228, 228,... Are installed on the bottom board 223 at intervals in the extending direction of the cloth foundations 229 and 234. Further, the loading body 235 and the fabric foundations 229 and 234 are integrated to form the foundation beam 226 as shown in FIG. 6, and the lower surface 226a of the foundation beam 226 and the upper ends 228a, 228a,. ... and concatenate. Further, the floor slab 233 is formed so as to extend from the foundation beam 226.
[0057]
Then, by removing the sanddle 239 and the supporting work 240 other than the portion buried in the bottom plate 223, the seismic isolation of the masonry building 221 is realized as shown in FIGS.
[0058]
In the seismic isolation method for the masonry building 221 described above, when the seismic isolation device 228 is interposed in the foundation portion 221a of the masonry building 221, the cloth foundations 229 and 234 of the masonry building 221 are By applying a compressive force from the extending direction of the fabric foundations 229 and 234, the integrity of the fabric foundations 229 and 234 as members can be ensured. Therefore, it is not necessary to continuously support the fabric foundation from below with a temporary mount or the like as in the prior art, and the cost and the amount of work involved in installing the temporary mount can be greatly reduced.
[0059]
Furthermore, in this seismic isolation method, compressive force is applied to the fabric foundations 229 and 234 from their extending direction. For example, when a compressive force is applied to the fabric foundations 229 and 234 from the direction orthogonal to the extending direction to secure the integrity as a member, the entire side surfaces of the fabric foundations 229 and 234 are reinforced. On the other hand, in the seismic isolation method according to the present embodiment, a compressive force is applied to the fabric foundations 229 and 234 only by placing the loading body 235 on the end surfaces 229a and 234a. The fabric foundations 229 and 234 can be easily integrated.
[0060]
Further, in the seismic isolation method for the masonry building 221 described above, when the fabric foundations 229 and 234 are reinforced, the loading body 235 is arranged so as to be in a state parallel to the end surfaces 229a and 234a of the fabric foundations 229 and 234. , And the PC steel wires 231, 231,... Are disposed along the cloth foundations 229 and 234, and the end portions 231 a, 231 a,. It is set as the structure which applies a compressive force with respect to the cloth foundations 229 and 234 by giving tension | tensile_strength to PC steel wire 231,231, .... Thereby, the fabric foundations 229 and 234 can be reinforced and provided with a simple structure.
[0061]
In the above embodiment, a part of the configuration may be changed without departing from the gist of the present invention.
For example, instead of the PC steel wires 231, 231,..., Other tension materials such as PC steel bars may be used.
Further, the seismic isolation device 228 does not have to be as in the above embodiment, and may have another shape / structure.
Moreover, in the said embodiment, although the fabric foundation 229 was made into the object of seismic isolation construction method, you may make it apply this seismic isolation construction method to reinforcements other than a fabric foundation.
[0065]
【The invention's effect】
  Claim 1In the seismic isolation method for masonry buildings, when the seismic isolation device is interposed between the foundation of the masonry building and the ground, the direction orthogonal to the foundation with respect to the foundation of the masonry building It is supposed to give compression force from. As a result, prior to excavation of the lower part of the foundation, it is possible to ensure the integrity as a member of the foundation, and it is necessary to continuously support the foundation from below with a temporary mount, etc. Disappears. Therefore, it is possible to greatly reduce the cost and work amount related to the installation of the seismic isolation device.
[0066]
  In particular, claim 1The seismic isolation method for masonry buildings is related to both sides of the foundation.Reinforced concrete beam material is provided over the entire length,Furthermore, it is set as the structure which makes a prestress force act with respect to these foundations and a beam material with a tension material. Thereby, it is possible to reinforce the foundation firmly and secure the safety of the seismic isolation construction of the masonry building. Also, according to this construction method, the foundation is reinforced and used as a structural member prior to excavating the lower part of the foundation. Therefore, the floor is used to secure the plane rigidity of the lowest floor of the masonry building. Even when the structural slab has to be provided in advance, it is not necessary to separately provide a beam or the like for supporting the structural slab. Thereby, even if the lowest floor of the masonry building is soil concrete, the construction can be easily and economically proceeded.
[0067]
  Claim 2In the seismic isolation method for masonry buildings, the foundation of the masonry building is installed when the seismic isolation device is installed in the foundation of the masonry building.By placing the tension material on both sides of theBy applying a compressive force from the extending direction, the foundation can be reinforced and the integrity as the member can be secured. Therefore, it is not necessary to continuously support the foundation from below with a temporary mount or the like as in the prior art, and the cost and work amount associated with the installation of the temporary mount can be greatly reduced. Moreover, in this seismic isolation method, since the compressive force is applied from the direction in which the foundation extends, there is no need to reinforce the foundation from the entire side surface, for example, in order to give the foundation integrity. The foundation can be reinforced.
[0068]
  In the seismic isolation method for masonry buildings according to claim 3,In the seismic isolation method for a masonry building according to claim 2, by installing loading bodies on both end faces of the foundation and tensioning the PC steel wire to fix the loading body, the extending direction with respect to the foundation InIt is supposed to apply compressive force. As a result, the foundation can be reinforced and integrated with a simple structure, and the cost and amount of work for provisional reception of a masonry building can be greatly reduced.
[Brief description of the drawings]
[Figure 1]It is an elevation sectional view showing an example of a foundation part of a masonry building and a reinforcing structure applied thereto.
FIG. 2 is a diagram schematically showing an embodiment of the present invention, and is a vertical sectional view showing a foundation of a masonry building subjected to seismic isolation.
FIG. 3 is a diagram showing a procedure of a seismic isolation method for a masonry building according to the present invention, and a vertical section showing a situation when reinforcing a cloth foundation of a masonry building before the seismic isolation FIG.
FIG. 4 is an elevational sectional view showing a situation when a cloth foundation of a reinforced masonry building is provisionally received by a sanddle.
FIG. 5 is a vertical sectional view showing the situation when a seismic isolation device is installed below the fabric foundation of the reinforced masonry building.
FIG. 6 is a diagram showing an embodiment of the present invention, and is a front sectional view showing a foundation part of a masonry building after a seismic isolation construction is performed.
FIG. 7A in FIG.₂-A₂It is arrow sectional drawing.
FIG. 8B in FIG.₂-B₂It is arrow sectional drawing.
FIG. 9 is a diagram showing a procedure of a seismic isolation method for a masonry building according to the present invention, and shows a situation of a cloth foundation showing a situation when PC steel wires are arranged along the cloth foundation of the masonry building. It is sectional drawing.
FIG. 10 is a side view for illustrating a situation when the ground below the reinforced fabric foundation is excavated and the fabric foundation is temporarily received.
FIG. 11 is a diagram for illustrating the prior art of the present invention, in which a temporary mount for temporarily receiving the fabric foundation is installed below the fabric foundation of the masonry building before the seismic isolation It is an elevation sectional view for showing the situation at the time of doing.
FIG. 12 is an elevational sectional view showing a situation when the temporary mount is supported from the ground via a support frame.
FIG. 13 is a vertical sectional view for illustrating a situation when the seismic isolation device is installed below the fabric foundation.
[Explanation of symbols]
  121,221  Masonry building
  129, 229, 234  Cloth foundation (foundation)
  136 PC steel bar (tension material)
  122,222 ground
  123 Bottom
  128,228 Seismic isolation device
  130 Beam material
  231 PC steel wire (tension material)
  235 load

Claims (3)

Saishi the building and interposed isolator between the ground supporting the foundation and the foundation of the building masonry to seismic sinkers, orthogonal to the extending direction of the foundation to the foundation The foundation is reinforced by applying a compressive force from the direction in which it is pushed, and then the ground below the foundation is excavated, and the seismic isolation device is interposed between the foundation and the ground. Seismic isolation method,
In reinforcing the foundation, reinforced concrete beam members are integrally installed on both sides of the foundation over the entire length of the foundation , and the foundation and the beam material are extended to the foundation and the beam material. by tensioning the tension member to provide a tension member which penetrates in a direction perpendicular to the direction in which the resident, by prestressing force to the beam member and said base, characterized in that the action of the compressive force Seismic isolation method for masonry buildings. A seismic isolation method for isolating the building by installing a seismic isolation device between the foundation of the masonry building and the ground supporting the foundation,
By placing a tendon on both sides of the foundation and tensioning the tendon, the foundation is reinforced by applying a compressive force to the foundation from its extending direction. A seismic isolation method for a masonry building, wherein the seismic isolation device is interposed between the foundation and the ground. A seismic isolation method for masonry buildings according to claim 2,
In reinforcing the foundation, on both end faces in the longitudinal direction of the foundation, a loading body is installed in parallel with the end face, and a tension material is disposed on both side faces of the foundation , and both ends of the tension material are connected to the ends. Supported by the load,
By tensioning the tendon and fixing both ends thereof to the loaded body, a prestressing force is applied to the foundation in the extending direction of the foundation via the above-described loading body, thereby applying the compressive force. Seismic isolation method for masonry buildings, characterized by

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