KR101301143B1 - Seismic retrofit structure of pilotiies construction - Google Patents

Abstract

The present invention relates to a seismic reinforcing structure of a piloti structure. Such a seismic reinforcement structure of the piloti structure according to the present invention is disposed along the bottom surface of the upper structure, having a predetermined height and installed in the vertical direction to support the upper structure; A damper module including a core wall disposed on the bottom of the structure and installed in the vertical direction, the damper module including a reinforcing plate for increasing rigidity of the column, coupled to the column, It is characterized in that the external force causing the deformation is induced to disperse into the pillar.
The seismic reinforcing structure of the piloti structure according to the present invention is to increase the rigidity (rigidity) by the reinforcing plate to be assembled to the pillar of the piloti structure, the external force to deform the structure is dispersed and induced into the pillar, is assembled to the pillar A damper is installed between the lower reinforcing plate and the lower reinforcing plate to induce dissipation of strain energy. The core wall formed in the piloti structure is reinforced by attachment of a reinforcing panel made of steel sheet and carbon fiber sheet, thereby increasing the strength and As the cracks are prevented from advancing, the seismic reinforcement function of the piloti structure is improved.

Description

Seismic retrofit structure of pilotiies construction

The present invention relates to a seismic reinforcing structure of the piloti structure, more specifically, to increase the rigidity of the pillar body of the piloti structure, and to dissipate the deformation energy due to the external force induced by the pillar through the damper. The present invention relates to a seismic reinforcing structure of a piloti structure for improving the function.

The piloti structure is a structure that supports the upper structure with a plurality of pillars installed at a predetermined height from the floor surface that forms the foundation of the building, and secures a ground floor space of a predetermined size. Since it can be used as a parking space, or the like, it is currently being applied to a lot of buildings such as general multi-family houses or apartments.

On the other hand, the piloti structure may further include a core wall disposed inside the pillar installed along the bottom circumference of the upper structure, such a core wall may be used as a stairway to the upper structure.

As such, the piloti structure having the pillar and the core wall may be deformed or damaged when subjected to an external force due to the occurrence of an earthquake. 1 shows a piloti structure 100 that is damaged by an external force due to an earthquake, etc., a shear crack phenomenon is concentrated in the core wall 20 constituting the piloti structure 100 can be confirmed that the core wall 20 is damaged. have. Since the core wall 20 has a small plastic deformation capacity, shear failure occurs during an earthquake, so the seismic performance is small. As shown in FIG. 2, as the core wall 20 has a rigidity higher than that of the column body 10, the external force induced to the column body 10 becomes small, and the column body 10 is elastically deformed. While the elastic deformation within the section, most of the external force is concentrated to the core wall 20 is a phenomenon caused by the rapid decrease in the strength. {The external force concentration on the core wall is derived through the following [Formula 1] to [Formula 4].}

Equation 1 F = Kδ (F: external force, K: horizontal stiffness, δ: strain amount)

Equation 2 δ = δ₁ = δ₂ (δ₁: deformation amount of core wall, δ₂: deformation amount of pillar)

P = P₁ + P₂ (P: total external force induced by pilot structure, P₁: external force induced by core wall, P₂: external force induced by column)

Equation 4 K₁>K₂->P₁> P₂

Therefore, the development of a technology that prevents the external force from being concentrated in the core wall to prevent damage to the core wall having a small plastic deformation capacity, and to improve the seismic reinforcement function of the piloti structure is presently required.

The present invention has been created to solve the above problems, a new form of piloti to minimize the deformation or damage of the piloti structure while the rigidity of the pillars constituting the piloti structure is increased so as to induce external force to the pillars The purpose is to provide a seismic reinforcing structure of the structure.

In addition, the present invention is a damper module consisting of a reinforcing plate with a damper is assembled to the column body to increase the stiffness and the energy absorption amount due to plastic deformation at the same time as a new form that can improve the seismic reinforcement function of the piloti structure The purpose of the present invention is to provide a seismic reinforcing structure of the piloti structure.

In addition, the present invention provides a new type of piloti that can prevent the core wall from being damaged by the development of a crack due to external force by allowing the core wall constituting the piloti structure to be reinforced with an attachment of a reinforcement panel made of a steel sheet and a carbon fiber sheet. The purpose is to provide a seismic reinforcing structure of the structure.

In addition, the present invention is the installation of the damper module consisting of the lower reinforcing plate, the upper reinforcing plate, the damper is made of prefabricated structure is easy to seismic reinforcement construction of the piloti structure, while the new type of piloti applicable to the existing piloti structure The purpose is to provide a seismic reinforcing structure of the structure.

The seismic reinforcing structure of the piloti structure of the present invention for achieving the above object is disposed along the bottom surface of the upper structure, having a predetermined height and installed in the vertical direction to support the upper structure; A damper module disposed on a bottom surface of the structure and including a core wall installed in a vertical direction, the damper module including a reinforcing plate for increasing rigidity of the pillar and coupled to the pillar; And it is characterized in that the external force causing the deformation of the core wall is induced to be distributed to the pillar.

In the earthquake-resistant reinforcing structure of the piloti structure according to the present invention, the column body to which the reinforcing plate is coupled is characterized by having greater rigidity than the core wall.

In the seismic reinforcement structure of the piloti structure according to the present invention, the pillar body coupled to the damper module has a stress-strain curve composed of elastic deformation sections and plastic deformation sections formed in a straight pattern to induce dispersion into the columns. It is characterized by being able to dissipate energy while plastic deformation by the external force.

In the seismic reinforcing structure of the piloti structure according to the present invention as described above, the damper module is characterized in that it is disposed in the vertical direction and fixed to the outside of the column body.

In the earthquake-resistant reinforcement structure of the piloti structure according to the present invention, the damper module and the lower reinforcing plate is joined to the lower portion of the pillar body; An upper reinforcing plate which is separated from the lower reinforcing plate and spaced upwardly and joined to an upper portion of the pillar; It is disposed between the lower reinforcing plate and the upper reinforcing plate is connected to the lower reinforcing plate and the upper reinforcing plate, characterized in that it comprises a damper that absorbs energy during external force operation.

In the seismic reinforcing structure of the piloti structure according to the present invention, the damper is characterized in that any one selected from the group of hysteretic damper, friction damper, oil damper, viscoelastic damper having a hysteretic behavior (hysteretic behavior).

In the earthquake-resistant reinforcing structure of the piloti structure according to the present invention, the damper is characterized in that both ends are fixed to the lower reinforcing plate and the upper reinforcing plate, made of a steel bar having a circular cross section.

In the seismic reinforcement structure of the piloti structure according to the present invention, the lower reinforcing plate, the upper reinforcing plate, the damper is separated from each other to form a prefabricated structure is damaged damper between the lower reinforcing plate and the upper reinforcing plate Characterized in that it can be replaced.

In the seismic reinforcement structure of the piloti structure according to the present invention, the damper fixing end is disposed to protrude outward from the upper end of the lower reinforcing plate and the lower end of the upper reinforcing plate, and the lower reinforcing plate and the upper reinforcing plate Both ends of the damper is fixed to the damper fixing end so that the damper is spaced apart from the pillar.

In the seismic reinforcement structure of the piloti structure according to the present invention, the lower reinforcing plate and the upper reinforcing plate is formed to be spaced apart from the outer peripheral surface of the pillar by a predetermined distance, the lower end of the lower reinforcing plate and the upper reinforcing An upper end of the plate is fixed to the pillar body.

In the seismic reinforcement structure of the piloti structure according to the present invention as described above, the lower end of the lower reinforcing plate is fixed to the anchor bolt and fixed to the protruding anchor bolt and fixed to the anchor bolt protruding to the pillar, respectively, The lower reinforcing plate and the lower body of the lower reinforcing plate by the bonding material injected into the space between the lower end of the lower reinforcing plate is characterized in that the body is integrally bonded to each other.

In the seismic reinforcing structure of the piloti structure according to the present invention as described above, the upper end of the upper reinforcing plate is fixed to the anchor bolt and fixed to the upper structure and fixed to the anchor bolt protruding to the pillar body, respectively, for the upper reinforcement The upper end of the upper reinforcing plate and the column body are integrally bonded to each other by a bonding material injected into a space between the lower end of the plate and the column body.

The bonding material in the seismic reinforcement structure of the piloti structure according to the present invention is characterized in that any one selected from mortar and epoxy.

In the earthquake-resistant reinforcing structure of the piloti structure according to the present invention, the length of the lower reinforcing plate and the upper reinforcing plate is characterized in that it is determined according to the stress distribution characteristics of the pillar by external force.

In the seismic reinforcement structure of the piloti structure according to the present invention, the damper module is installed on one or more pillars, the pillar body has a rectangular horizontal cross-section, the lower reinforcing plate and the upper reinforcing plate and the damper is the pillar And at least one outer side of the sieve.

In the seismic reinforcement structure of the piloti structure according to the present invention, the core wall is coupled to the reinforcement panel so that the strength of the core is increased so that cracks due to external forces causing deformation of the pillar and the core wall are prevented from developing. Characterized in that.

In the seismic reinforcement structure of the piloti structure according to the present invention as described above, the reinforcement panel is characterized in that it comprises a steel sheet.

In the seismic reinforcement structure of the piloti structure according to the present invention as described above, the reinforcement panel is characterized in that it comprises a carbon fiber sheet.

In the seismic reinforcing structure of the piloti structure of the present invention as described above, the external force for deforming the structure by increasing the rigidity by the reinforcing plate assembled to the pillar of the piloti structure is induced to be dispersed into the column, As a damper is installed between the lower reinforcing plate and the lower reinforcing plate assembled in the sieve to induce the dissipation of strain energy, the seismic reinforcing function of the piloti structure is improved. In addition, the seismic reinforcing structure of the piloti structure of the present invention is reinforced by the attachment of the reinforcement panel made of steel sheet and carbon fiber sheet is reinforced core core formed in the piloti structure, the strength is increased, it is prevented that the crack due to the external force is advanced As a result, the stability of the piloti structure is improved. In addition, the present invention is the installation of the components for the seismic reinforcement of the piloti structure is made of prefabricated construction, while the construction is easy, there is an advantage that can be applied to the existing piloti structure.

1 is a view for showing a damaged state by the action of an external force on a common piloti structure having a pillar and a core wall;
FIG. 2 is a diagram for showing stress-strain curves of each of the core wall and the pillar which constitute the piloti structure; FIG.
3 is a view for showing the basic configuration of the seismic reinforcement structure of the piloti structure according to the present invention;
4 is a view for showing the technical idea of the seismic reinforcing structure of the piloti structure according to the present invention;
5 is a view for showing a stress-strain curve of each of the core wall and the column to which the seismic reinforcement structure of the piloti structure according to the present invention is applied;
6 is a view for showing a seismic reinforcement structure of the piloti structure according to an embodiment of the present invention;
Figure 7 is a view for showing the front configuration of the seismic reinforcement structure of the piloti structure according to an embodiment of the present invention;
8 is a view for showing a damper module applied to the seismic reinforcement structure of the piloti structure according to an embodiment of the present invention;
9 to 12 are views for showing a structure in which the damper module is applied to the earthquake-resistant reinforcement structure of the piloti structure according to an embodiment of the present invention the column body is constructed;
13 is a view for showing the dimensions of the simplified piloti structure used in the earthquake test;
14 is a graph showing the relative displacement distribution of each layer of the piloti structure of FIG.
15 is a graph showing the relative displacement distribution of each layer of the piloti structure of FIG. 13 to which the seismic reinforcement structure of the piloti structure according to the embodiment of the present invention is applied;
FIG. 16 is a graph for showing a load-displacement relationship curve of the piloti structure of FIG. 13; FIG.
17 is a graph showing a load-displacement relationship curve of the piloti structure of FIG. 13 to which the seismic reinforcement structure of the piloti structure is applied according to an embodiment of the present invention;
FIG. 18 is a bar graph comparing two-layer relative displacements of the piloti structure of FIG. 13 and the piloti structure of FIG. 13 to which the seismic reinforcement structure of the piloti structure according to the embodiment of the present invention is applied;
FIG. 19 is a bar graph comparing the two-layer absolute acceleration of the piloti structure of FIG. 13 and the piloti structure of FIG. 13 to which the seismic reinforcement structure of the piloti structure according to the embodiment of the present invention is applied.

3 is a view for showing the basic configuration of the seismic reinforcement structure of the piloti structure according to the present invention, Figure 4 is a view for showing the technical concept of the seismic reinforcement structure of the piloti structure according to the present invention, Figure 5 A diagram showing the stress-strain curves of each of the core wall and the column to which the seismic reinforcement structure of the piloti structure is applied.

The piloti structure 100 includes a pillar 10 and a core wall 20, the pillar 10 has a predetermined height and is installed in the vertical direction to support the upper structure 200, a plurality of pillars Sieve 10 is disposed along the bottom circumference of the superstructure 200. The core wall 20 is installed on the bottom surface of the upper structure 200 in the vertical direction, such a core wall 20 may be utilized as a step going up to the upper structure 200.

The seismic reinforcement structure of the piloti structure according to the present invention that can be applied to the piloti structure 100 as shown in Figure 3, the damper module 30 is coupled to the pillar body 10 of the piloti structure 100, the core wall The reinforcement panel 40 is coupled to the configuration 20. Here, the damper module 30 is installed on one or more pillars 10, and the damper module 30 is provided to correspond to the total number of pillars 10 constituting the piloty structure 100, and each pillar body is provided. The damper module 30 may be installed in the 10, or the damper module 30 may be selectively installed in the pillar body 10 in which the damper module 30 needs to be installed.

The damper module 30 is disposed to be fixed to the outside of the column body 10 in the vertical direction, such a damper module 30 is a reinforcing plate for increasing the rigidity (rigidity) of the column body 10 ( 31 and 32, wherein the reinforcing plates 31 and 32 are coupled to the column body 10 to generate an external force that causes deformation of the column body 10 and the core wall 20. To induce dispersion. Here, the column body 10 to which the reinforcing plates 31 and 32 are coupled will have greater rigidity than the core wall 20. As a result, most of the external force is guided to the plurality of pillars 10, thereby minimizing the external force induced to the core wall 20, thereby preventing cracking or breakage of the core wall 20. In addition, as the plurality of pillars 10 are provided to distribute external force, excessive deformation or damage of the pillars 10 may be prevented.

As such, the phenomenon in which the external force is induced into the column body 10 to which the reinforcing plates 31 and 32 are coupled can be confirmed through the following [Formula 1] to [Formula 4].

Equation 1 F = Kδ (F: external force, K: horizontal stiffness, δ: strain amount)

Equation 2 δ = δ₁ = δ₂ (δ₁: deformation amount of core wall, δ₂: deformation amount of pillar)

Equation 3 P = P (+ P₂ (P: total external force induced by pilot structure, P₁: external force induced by core wall with reinforcement panel, P₂: external force induced with column with damper module)

Equation 4 K₁ <K₂-> P₁ <P₂

In addition, the damper module 30 according to the present invention is configured such that the damper 33 is disposed between the lower reinforcing plate 31 and the upper reinforcing plate 32 which are formed to be spaced apart from each other in the vertical direction as shown in FIG. Is done. Here, the lower reinforcing plate 31 is to be bonded to the lower portion of the column body 10, the upper reinforcing plate 32 is to be bonded to the upper portion of the column body is separated from the lower reinforcing plate 31 to the upper side Spaced apart. The damper 33 connects the lower reinforcing plate 31 and the upper reinforcing plate 32 to absorb energy during external force operation. The damper 33 may be one of various configurations. A hysteretic damper having hysteretic behavior due to the displacement difference between the lower reinforcing plate 31 and the upper reinforcing plate 32 may be used. In particular, a circular hysteresis damper consisting of a steel rod having a circular cross section and having both ends fixed to the lower reinforcing plate 31 and the upper reinforcing plate 32 may be used. Since the damper of the circular cross section is not directional, plastic dampers can be smoothly and stably responded to external forces induced in various directions. Here, since the damper 33 plastically deformed by the displacement difference between the lower reinforcing plate 31 and the upper reinforcing plate 32 generated by the horizontal displacement of the piloti structure 100 absorbs energy, the hysteresis In addition to the damper, a friction damper may be used as the damper 33. In addition, an oil damper or a viscoelastic damper may also be used as the damper 33. The oil damper or viscoelastic damper controls the displacement difference between the lower reinforcing plate 31 and the upper reinforcing plate 32 to improve the damping performance of the structure. By doing so, the seismic reinforcement function is performed.

Here, the pillar 10 may have a rectangular horizontal cross section having a plurality of outer surfaces, in this case, the lower reinforcing plate 31, the upper reinforcing plate 32, and the damper 33 are the pillars 10. It may be disposed on one or more outer side of the. That is, the lower reinforcing plate 31, the upper reinforcing plate 32, and the dampers 33 are disposed one by one in correspondence with each outer side surface of the column body 10, and the lower reinforcing portion is reinforced on the entire outer surface of the column body 10. The plate 31 and the upper reinforcing plate 32 and the damper 33 may be arranged, respectively, and the lower reinforcing plate 31 and the upper reinforcing plate 32 and the damper 33 need to be installed. The lower reinforcing plate 31, the upper reinforcing plate 32, and the damper 33 may be selectively provided to a part of the outer side surface of the pillar 10. Of course, the pillar 10 may have a circular horizontal cross-section, in which case the lower reinforcing plate 31 and the upper reinforcing plate 32 and the damper 33 of the column 10 having a circular horizontal cross-section It may be installed on a portion or may be installed while wrapping the entire pillar 10.

On the other hand, the vertical length of the lower reinforcing plate 31 and the upper reinforcing plate 32 is preferably determined in accordance with the stress distribution characteristics of the column body 10 by the external force. That is, the vertical length of the lower reinforcing plate 31 and the vertical length of the upper reinforcing plate 32 may be changed, and the vertical length of the lower reinforcing plate 31 and the upper reinforcing plate 32 may vary. May be different.

The pillar body 10 to which the damper module 30 having the above configuration is coupled has a stress-strain curve composed of elastic deformation sections and plastic deformation sections formed in a straight pattern as shown in FIG. 5. Accordingly, the plastic deformation capacity of the column body 10 to which the damper module 30 is coupled is improved, and the column body 10 to which the damper module 30 is coupled is plastically deformed by external force, thereby absorbing and dissipating strain energy. It becomes possible. When the pillar body 10 to which the damper module 30 is coupled is plastically deformed to dissipate strain energy as described above, as shown in FIG. 5, the core wall 20 is elastically deformed within the elastic deformation section while the strain is reduced as shown in FIG. 5. Thus, deformation and breakage of the core wall 20 can be prevented.

Here, the lower reinforcing plate 31 and the upper reinforcing plate 32 constituting the damper module 30 according to the present invention when the action of the external force as shown in Figure 4 is elastically deformed, forming the damper module 30 The damper 33 is plastically deformed. As the deformation energy due to external force is converted into elastic deformation energy and plastic deformation energy through the damper module 30, excessive deformation or breakage of the pillar 10 may be effectively prevented. Will be.

On the other hand, the core wall 20 is coupled to the reinforcement panel 40 to increase the strength, thereby causing the core wall 20 by the external force causing the deformation of the column body 10 and the core wall 20. It is possible to effectively prevent cracks from forming, or from developing cracks. Here, the reinforcement panel 40 may be configured to include a steel sheet and a carbon fiber sheet.

The seismic reinforcing structure of the piloti structure according to the present invention constituted as described above is simultaneously increased in rigidity and plastic deformation capacity by the damper module 30 assembled to the pillar 10. While most of the external force is induced to be distributed to the plurality of pillars 10, dissipation of strain energy is induced through plastic deformation of the damper 33, as well as a reinforcement panel 40 including a steel sheet and a carbon fiber sheet. ) Is coupled to the core wall 20 so that the strength of the core wall 20 is improved, so that the seismic reinforcement function of the piloti structure 100 is improved and stability is increased.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings 6 to 12. On the other hand, in the drawings and detailed description showing and referring to the configuration and operation easily understood by those skilled in the art from the general pilot structure, seismic reinforcement structure of the structure, etc. are briefly or omitted. In the drawings and specification, there are shown in the drawings and will not be described in detail, and only the technical features related to the present invention are shown or described only briefly. Respectively.

6 is a view for showing the seismic reinforcement structure of the piloti structure according to an embodiment of the present invention, Figure 7 is a view for showing the front configuration of the seismic reinforcement structure of the piloti structure according to the embodiment of the present invention, 8 is a view showing a damper module applied to the seismic reinforcement structure of the piloti structure according to the embodiment of the present invention.

6 to 8, in the seismic reinforcing structure of the piloti structure according to the embodiment of the present invention, one column 10 is disposed at each of the bottom edges of the upper structure 200 so that the bottom of the upper structure 200 is disposed. It is coupled to the beam 220 forming a, and applied to the structure in which the core wall 20 is formed in the center of the upper structure 200, the seismic reinforcement structure of the present invention is not limited to such a structure, various embodiments Of course you can have.

Here, the pillar 10 has a rectangular horizontal cross-sectional shape.

In the seismic reinforcing structure of the piloti structure according to the embodiment of the present invention, the damper module 30 is installed on each of the entire pillars 10, and the lower reinforcing plate 31 and the upper reinforcing plate constituting the damper module 30. The 32 and the damper 33 are also provided in each of the whole outer surface of each pillar 10. Of course, the damper module 30 may be installed to be limited to the selected pillar body 10, and the lower reinforcing plate 31, the upper reinforcing plate 32, and the damper 33 also have one pillar 10. It may be installed to be limited to the outer surface selected from the outer surface of the.

The damper module 30 is disposed and fixed in the vertical direction outside the side of the column body 10, the lower reinforcing plate 31, the upper reinforcing plate 32, the damper 33 forming the damper module 30. The prefabricated structure is separated and coupled to each other so that only the damaged damper 33 can be replaced between the lower reinforcing plate 31 and the upper reinforcing plate 32 when the damper 33 is damaged. Here, the lower reinforcing plate 31 and the damper 33, the damper 33 and the upper reinforcing plate 32 may be coupled to each other by welding.

The lower reinforcing plate 31 has a lower fixing end 311 formed at the lower end thereof so that the lower reinforcing plate 31 is integrally joined to the lower end 1 of the base 1 and the lower end of the pillar 10. The upper reinforcing plate 32 has an upper fixing end 321 formed at the upper end thereof, and the beam 220 constituting the upper structure 200 and the upper reinforcing plate 32 are integrally joined to the upper end of the column body 10. Be sure to In addition, the damper 33 has a circular cross section so as not to have directivity during deformation, and a steel bar, which is a hysteretic damper having hysteretic behavior, is not limited thereto.

Here, the damper fixing end 34 is disposed to protrude outward from the upper end of the lower reinforcing plate 31 and the lower end of the upper reinforcing plate 32, and the lower reinforcing plate 31 and the upper reinforcing plate 32 are disposed. Both ends of the damper 33 is fixed to the damper fixing end 34 of the damper 33 so that the damper 33 is spaced apart from the pillar body 10 by a predetermined distance. Accordingly, the deformation amount of the damper 33 is accommodated through the spaced space between the damper 33 and the pillar body 10 when the damper 33 is deformed, so that the deformation of the damper 33 is not constrained, thereby preventing the damper 33 and the pillar. The generation of the load due to the interference between the sieves 10 can be prevented.

One damper 33 may be disposed between the lower reinforcing plate 31 and the damper fixing end 34 of the upper reinforcing plate 32, or two dampers 33 may be disposed. The number of dampers 33 disposed between the lower reinforcing plate 31 and the damper fixing end 34 of the upper reinforcing plate 32 is not limited thereto.

Here, the lower reinforcing plate 31 and the upper reinforcing plate 32 constituting the damper module 30 are formed to be spaced apart from the outer surface of the pillar 10 by a predetermined distance. Accordingly, when the column body 10 is deformed by the action of an external force, the deformation amount of the column body 10 is accommodated through the spaced space between the lower reinforcing plate 31 and the upper reinforcing plate 32, thereby providing the columnar body 10. ) Is not constrained so that generation of a load due to interference between the pillar body 10 and the reinforcing plates 31 and 32 can be prevented.

On the other hand, the reinforcement panel 40 of the structure containing a steel plate and a carbon fiber sheet is joined to the core wall 20, and the strength of a load can be increased.

9 to 12 are views for showing a configuration in which the damper module is applied to the earthquake-resistant reinforcement structure of the piloti structure according to an embodiment of the present invention the column body.

Damper module 30 is applied to the seismic reinforcement structure of the piloti structure according to an embodiment of the present invention as shown in Figure 9 at the lower end of the lower reinforcing plate 31, the lower fixing end 311 from the column 10 The lower fixing end 311 is fixed to the anchor bolt protruding from the anchor bolt protruding from the anchor bolt and fixed to the base 10 to be fixed to the bottom surface (1) forming a base. Next, as shown in FIG. 10, the lower reinforcing plate by the bonding material 35 injected into the space between the lower fixed end 311 and the pillar body 10 disposed at the lower end of the lower reinforcing plate 31. The lower fixed end 311 and the pillar 10 disposed at the lower end of the 31 are integrally bonded to each other. Here, as the bonding material 35, mortar 351 may be used, or an epoxy may be used. When the mortar 351 is used as the bonding material 35, it is preferable that non-contraction mortar is used.

Then, as shown in FIG. 11, the lower reinforcing plate 31, the damper 33, and the upper reinforcing plate 32 are sequentially coupled to each other so that the damper module 30 is formed, such a damper module 30 as described above. The silver is spaced apart a certain distance from the outer surface of the pillar 10 to be formed while wrapping the pillar (10). Lastly, as shown in FIG. 12, the upper fixing end 321 is disposed at the upper lower end of the upper reinforcing plate 32 to be fixed to the beam 220 of the upper structure 200 and the anchor bolt and the pillar 10. After fixing the upper fixing end 321 to each of the anchor bolt protruding fixed to the upper end of the), by the bonding material 35 injected into the spaced space between the upper fixing end 321 and the column body (10) The upper fixed end 321 and the columnar body 10 are to be integrally bonded to each other. Mortar 351 may also be used as the bonding material 35 that integrally joins the upper fixed end 321 and the pillar 10, or an epoxy may be used. When the mortar 351 is used as the bonding material 35, it is preferable that non-contraction mortar is used.

FIG. 13 is a view for showing the dimensions of the simplified piloti structure used in the earthquake test, FIG. 14 is a graph for showing the distribution of the relative displacement of each layer of the piloti structure of FIG. 13, and FIG. 15 is an embodiment of the present invention. FIG. 16 is a graph showing the relative displacement distribution of each of the piloti structures of FIG. 13 to which the seismic reinforcement structure of the piloti structure is applied. FIG. 16 is a graph for showing a load-displacement relationship curve of the piloti structure of FIG. 13. FIG. 18 is a graph showing a load-displacement relationship curve of the piloti structure of FIG. 13 to which the seismic reinforcement structure of the piloti structure is applied, and FIG. 18 is a piloti structure according to the embodiment of the present invention. 13 is a bar graph comparing the two-layer relative displacements of the piloti structure of FIG. 13 to which the seismic reinforcement structure of the structure is applied, and FIG. 19 is the piloti structure of FIG. In the advanced steel it has been applied a bar graph comparing the absolute acceleration of the two-layer structure of Figure 13 in piloti piloti structure according to an embodiment of the invention.

13 to 19 are to show the results of the earthquake test to determine the dynamic response characteristics in the excitation conditions of the low-rise building to which the piloto structure is applied.

The seismic test was performed for the piloti structure of FIG. 13 and the piloti structure of FIG. 13 to which the seismic reinforcing structure of the piloti structure according to the embodiment of the present invention was applied. The excitation of each piloti structure was performed using a El-Centro NS wave to adjust the scale. In order to consider the total weight of the actual building, 18 tons of mass were added to the first and second floors.

14 and 15 are graphs of the relative displacement of each layer of the piloti structure while varying the scale of the vibration wave for excitation. FIG. 13 shows the piloti structure of FIG. 13 and the embodiment of the present invention when the scale is 50% and 100%. Although the relative displacement of each layer of the piloti structure of FIG. 13 to which the seismic reinforcement structure of the piloti structure is applied is similar, the seismic reinforcement structure of the piloti structure according to the exemplary embodiment of the present invention is better than that of the piloti structure of FIG. It can be seen that the relative displacement of each layer of the piloti structure of FIG. 13 to which the is applied is significantly lowered, thereby improving stability. This is because, in the case of the piloti structure of FIG. 13, the relative displacement response increases as the strength and stiffness of the core wall at the 150% scale is reduced.

FIG. 16 and FIG. 17 are load-displacement relationship curves in which the load-displacement relationship of the piloti structure is tracked while varying the scale of the vibration wave for excitation, and the load at the time of destruction of the piloti structure of FIG. 13 is about 30 kN. When the seismic reinforcement structure of the piloti structure according to the embodiment of the present invention is applied to the breakdown load of the piloti structure of Figure 13 can be confirmed that the load, the seismic reinforcement structure of the pilot structure according to the embodiment of the present invention It can be seen that the improvement.

FIG. 18 is a bar graph comparing the two-layer relative displacements of the piloti structure of FIG. 13 and the piloti structure of FIG. 13 to which the seismic reinforcement structure of the piloti structure according to the embodiment of the present invention is applied, according to an embodiment of the present invention; FIG. When the seismic reinforcement structure of the structure is applied, the relative displacement of the second floor is lowered, thereby improving stability. In addition, in the case of the piloti structure of FIG. 13, when the excitation is more than 180%, the two-layer relative displacement value is not calculated, whereas the piloti structure of FIG. 13 to which the seismic reinforcement structure of the piloti structure according to the embodiment of the present invention is applied is destroyed. Since it is not deformed continuously, it can be seen that the seismic performance is improved when the seismic reinforcing structure of the piloti structure according to the embodiment of the present invention is applied.

FIG. 19 is a bar graph comparing the two-layer absolute acceleration of the piloti structure of FIG. 13 and the piloti structure of FIG. 13 to which the seismic reinforcement structure of the piloti structure according to the embodiment of the present invention is applied; FIG. In case of excitation of more than% scale, the two-layer absolute acceleration value is not calculated, whereas the piloti structure of FIG. 13 to which the seismic reinforcement structure of the piloti structure according to the embodiment of the present invention is applied does not destroy and maintains its shape while continuing to vibrate. In the application of the seismic reinforcing structure of the piloti structure according to the embodiment of the present invention, it can be seen that the seismic performance is improved.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

1: bottom surface 10: pillar
20 core wall 30 damper module
31: lower reinforcing plate 311: lower fixing end
32: upper reinforcing plate 321: upper fixed end
33: damper 34: damper fixed end
35: bonding material 351: mortar
40: reinforcement panel 100: piloti structure
200: superstructure 220: beam

Claims (18)

A pillar body disposed along a bottom circumference of the upper structure and having a predetermined height and installed in a vertical direction to support the upper structure; A damper module disposed on a bottom surface of the structure and including a core wall installed in a vertical direction, the damper module including a reinforcing plate for increasing rigidity of the pillar and coupled to the pillar to be connected to the pillar. And the external force causing the deformation of the core wall and the dispersion to the pillar body,
The damper module may include: a lower reinforcing plate disposed in the up and down direction outside the pillar and fixed to the lower portion of the pillar; An upper reinforcing plate which is separated from the lower reinforcing plate and spaced upwardly and joined to an upper portion of the pillar; Is disposed between the lower reinforcing plate and the upper reinforcing plate is connected to the lower reinforcing plate and the upper reinforcing plate, and comprises a damper that absorbs energy during external force operation,
The lower reinforcing plate, the upper reinforcing plate, the damper has a prefabricated structure that is separated and coupled to each other so that the damaged damper can be replaced between the lower reinforcing plate and the upper reinforcing plate, the interior of the piloti structure Progressive steel structure. The method of claim 1,
The pillar body to which the reinforcing plate is coupled has a greater rigidity than that of the core wall body. The method of claim 1,
The pillar body coupled to the damper module has a stress-strain curve composed of an elastic strain section and a plastic strain section formed in a straight pattern to dissipate energy while plastically deforming by an external force induced by the pillar. Seismic reinforcement structure of the piloti structure characterized in that it is. delete delete The method of claim 1,
The up and down lengths of the lower reinforcing plate and the upper reinforcing plate are determined according to the stress distribution characteristics of the pillar by external force. The method of claim 1,
The damper module is installed on one or more pillars,
The pillar body has a rectangular horizontal cross-section, wherein the lower reinforcing plate, the upper reinforcing plate and the damper is disposed on at least one outer surface of the pillar body seismic reinforcement structure. The method of claim 1,
The damper is any one selected from the group of hysteretic damper, friction damper, oil damper, viscoelastic damper having a hysteretic behavior (seismic behavior) structure. The method of claim 8,
Both ends of the damper is fixed to the lower reinforcing plate and the upper reinforcing plate, the seismic reinforcement structure of the piloti structure, characterized in that consisting of a steel rod having a circular cross section. delete The method of claim 1,
The damper fixing end is disposed to protrude outward from the upper end of the lower reinforcing plate and the lower end of the upper reinforcing plate, and both ends of the damper are fixed to the damper fixing ends of the lower reinforcing plate and the upper reinforcing plate. The seismic reinforcement structure of the piloti structure characterized in that the spaced apart from the pillar. The method of claim 1,
The lower reinforcing plate and the upper reinforcing plate is formed to be spaced apart from the outer peripheral surface of the pillar by a predetermined distance,
The lower end of the lower reinforcing plate and the upper end of the upper reinforcing plate seismic reinforcement structure, characterized in that fixed to the pillar body. 13. The method of claim 12,
The lower end of the lower reinforcing plate is fixed to the anchor bolt protruding and fixed to the bottom surface constituting the base and the anchor bolt protruding fixed to the pillar, respectively,
The seismic reinforcing structure of the piloti structure, characterized in that the lower end of the lower reinforcing plate and the column body is integrally bonded to each other by a bonding material injected into the space between the lower end of the lower reinforcing plate and the column body. 13. The method of claim 12,
The upper end of the upper reinforcing plate is fixed to the anchor bolt protruding fixed to the upper structure and the anchor bolt protruding to the pillar body, respectively,
The seismic reinforcing structure of the piloty structure, characterized in that the upper end of the upper reinforcing plate and the column body is integrally bonded to each other by a bonding material injected into the space between the lower end of the upper reinforcing plate and the column body. The method according to claim 13 or 14,
The bonding material is a seismic reinforcing structure of the piloti structure, characterized in that any one selected from mortar and epoxy. The method of claim 1,
The core wall has a seismic reinforcement structure of the piloti structure, characterized in that to prevent the cracks due to the external force causing the deformation of the pillar body and the core wall is coupled to the reinforcement panel is increased. 17. The method of claim 16,
The reinforcement panel is a seismic reinforcement structure of the piloti structure characterized in that it comprises a steel sheet. The method according to claim 16 or 17,
The reinforcement panel is a seismic reinforcement structure of the piloti structure characterized in that it comprises a carbon fiber sheet.

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