KR101787375B1 - Earthquake-resistance assembling block unit for non-bearing wall sturucture and unreinforced masonry structure - Google Patents

Abstract

The present invention relates to a seismic block and a masonry wall for enhancing an earthquake-proof performance capable of reinforcing not only the earthquake resistance of a non-bearing wall of a building but also the earthquake resistance of a bearing wall, By including reinforcing bars, economic efficiency can be expected by improving the seismic performance while maintaining the same construction method as that of masonry wall construction. Further, the stability of the masonry wall due to the stability of the masonry structure can be minimized, The collapse caused by the impact or the like prevents the block constituting the masonry wall from causing injury to persons.

Description

BACKGROUND OF THE INVENTION Field of the Invention [0001] The present invention relates to an earthquake-resistant building structure for an earthquake-

The present invention relates to a seismic isolation structure for partially segregating a seismic wave in a main frame of a building to reduce a tensile force applied to the wall surface by the seismic wave and thereby to reduce the damage to the wall surface, And a coarse-grained wall.

Generally, partition wall or general wall structure (hereinafter referred to as 'coarse wall'), which is to be laid in the interior of a building, is a masonry-type masonry wall for the purpose of partitioning the interior space. In domestic seismic design standards, The wall is regarded as an unstructured structure and the influence of the wall structure on the building is not considered. Such a masonry wall is a non-masonry wall which is structurally separated from the basic masonry of the building and is neglected in reflecting the earthquake-proof structure in designing the masonry. This fact is reported by Francisco Javier Palleres of ICITECH, "The earthquake response characteristics of buildings are reported clearly and extensively, but the current seismic calculations do not consider blocking walls, considering only buildings and framing," explains the coarse- And that it is a separate structure from the basic frame. Here, the mooring type refers to a structure type in which masonry such as bricks, blocks, and stones are adhered to each other by mortar serving as an adhesive.

The reason why the masonry wall is constructed independently from the basic frame of the building is that the owner of the masonry structure can freely integrate the interior space according to his or her taste or purpose, So that it can be transformed.

Here, the masonry-type masonry wall has advantages such as short construction period, low construction cost, excellent appearance, high fire resistance performance and durability and relatively strong resistance to vertical force, while resistance against lateral force due to earthquake There is a problem that the ability is significantly deteriorated.

For this reason, when a sudden shock such as a wormhole or an earthquake occurs near the building, the building receives the impact as it is, and the masonry wall of non-proof structure collapses without overcoming the impact. In addition, the masonry wall in the form of masonry filled walls may have an effect of increasing the stiffness by restraining the masonry structure against the earthquake, but such a masonry restraint has a disadvantage that it causes the brittle failure behavior of the frame. In addition, in the case of the brick wall having relatively large weight, the rockfall could directly damage the nearby people when the wall collapses.

In order to solve this problem, conventionally, the masonry wall is formed of a simple synthetic resin partition. However, this has a limitation in maintaining a stable space partition as well as an effect of sound insulation between the compartment spaces, and it is a structure of a masonry wall which is not preferred when securing a secure space is required.

On the other hand, in order to overcome the above-mentioned problem, there has been proposed a masonry wall and a construction method which have been conventionally provided with vibration resistance and stable space dividing performance. The prior art for this purpose is to integrate bricks and bricks together with one or more reinforcing bars. However, in the conventional art, it is difficult to deform or dismantle the masonry wall after the completion of the masonry, because the masonry wall must be laid along with the masonry wall when the masonry is completed. Thus, it is practically impossible to newly construct masonry walls in the completed masonry. Of course, it is possible to adjust the length of the reinforcing bar to enable the expansion / contraction of the coarse wall. However, in this case, a large number of reinforcing bars must be inserted into the contracting wall.

For reference, when planning and / or designing the structure of the concrete block masonry building with 4 or more floors, the safety of the structure of the building should be verified by the structural calculation of the architectural structural engineer according to the National Qualifications Act, If building construction is to be done, reinforced concrete block structure should be used and the local construction technology review committee under Article 5 of the Construction Technology Management Act should be deliberated.

On the other hand, when the indoor space structure is varied according to the level of the building, the rough wall is not located at a certain point but can be arranged differently for each floor. However, in order to solve the above-mentioned problem of the non-bearing walls, when the masonry walls are mated with general bearing walls, the load bearing on the bottom of the building is increased to increase the risk of collapse of the floor .

Therefore, the masonry wall used as the partition wall must have a proof wall structure in order to improve the earthquake resistance. On the other hand, it is difficult to design the partition wall in the design of the building in order to reduce the load burden of the masonry wall to the floor. there was.

In order to solve the above-mentioned problems, an earthquake-proof slit and a twist bar reinforcing technique have been disclosed in an experimental study on a reinforcing method for enhancing the seismic performance of existing structures having a masonry bearing wall (Shin Dae-woong 2015.02, Seoul National University).

The earthquake-proof slit reinforces the earthquake-proof slit between the basic frame of the building and the coarse wall of the partition wall functioning as the non-bearing wall to prevent brittle fracture of the basic frame by the coarse wall, .

On the other hand, the twisted bar increases the strength and rigidity of the masonry wall and controls the behavior of the masonry wall after the masonry wall is broken. However, the twisted bar has a disadvantage in reducing ductility between the masonry wall and the basic masonry.

As a result, the above-mentioned prior art reinforces the twisted bar and the earthquake-resistant slit to the masonry wall to complement the disadvantages of each structure, thereby enhancing the strength of the masonry wall against the vertical load and the horizontal load.

However, in the above-mentioned prior art, the twist bar simply passes through the building block of the masonry wall, and it is difficult to construct the masonry wall, the working time is not short, and the precise construction is also difficult. .

Prior Art Document 1. Patent Publication No. 10-2012-0084478 (published July 30, 2012)

Accordingly, it is an object of the present invention to overcome the above-mentioned problems, and it is an object of the present invention to provide an improved method of constructing a rough wall structure by improving the seismic performance while maintaining the same construction method as the conventional rough wall construction, And to provide an earthquake-proof block and a masonry wall for an earthquake-proof construction of a non-reinforced non-reinforced non-reinforced wall which minimizes the influence on a building frame.

The present invention also provides a seismic isolation structure for an earthquake-proof construction of a non-reinforced non-reinforced non-reinforced wall which prevents a block constituting a masonry wall from being damaged due to collapse due to an external impact or the like, .

According to an aspect of the present invention,

And a plurality of reinforcing bars arranged so that the end portions protrude from the outer surface of the main body.

According to another aspect of the present invention,

In a masonry wall in which a plurality of general blocks are assembled in a staggered manner,

A plurality of earthquake-resistant blocks assembled in a triangular shape are formed in each corner section of the rough wall;

The earthquake-proof block is a masonry wall comprising a main body and a plurality of reinforcing bars whose ends are projected along the circumferential surface of the main body.

The present invention can improve the seismic performance and the economic efficiency while maintaining the same construction method as that of the masonry wall construction. Further, it is possible to minimize the influence of the masonry wall on the masonry structure due to the stability corresponding to the masonry structure, There is an effect that the block formed on the masonry wall does not cause personal injury due to collapse due to an external impact or the like.

1 is a perspective view showing an embodiment of a vibration-isolating block according to the present invention,
FIG. 2 is a cross-sectional view showing a longitudinal section of a vibration-isolating block according to the present invention,
3 is a front view schematically showing an embodiment of an artificial wall to which a vibration-isolating block according to the present invention is applied,
Fig. 4 is an enlarged view of P1 in Fig. 3 schematically showing another embodiment of a joint structure between seismic blocks according to the present invention,
FIG. 5 is a perspective view explaining another embodiment of a joint structure between seismic blocks according to the present invention as shown in FIG. 4 (b)
6 is a view schematically showing deformation and generated stress of the masonry wall according to the present invention by a frame of a building subjected to an external impact,
FIG. 7 is a front view schematically showing another embodiment of a masonry wall to which a vibration-isolating block according to the present invention is applied,
8 is a perspective view showing a state in which the body of the vibration-isolating block according to the present invention is constituted by a hollow block,
9 is a perspective view showing another embodiment of a reinforcing bar constructed in the vibration-isolating block according to the present invention,
FIG. 10 is a perspective view showing the coupling between seismic isolation blocks shown in FIG. 8,
FIG. 11 is a plan view showing a state of coupling between seismic isolation blocks shown in FIG. 8,
FIG. 12 is a side view showing a state in which reinforcing bars are engaged by coupling between seismic isolation blocks shown in FIG. 8,
13 is a perspective view showing another embodiment of the masonry wall according to the present invention,
Fig. 14 is a view showing a cross-sectional view of the masonry wall shown in Fig. 13,
FIG. 15 is a cross-sectional view of the masonry wall viewed in the 'A' direction in FIG. 14,
FIG. 16 is a partial cross-sectional view showing a combined wall of the building according to the present invention combined with a basic frame of a building,
17 is a perspective view showing an embodiment of a reinforcing panel according to the present invention,
18 is a perspective view showing another embodiment in the case where the body of the vibration-isolating block according to the present invention is constituted by a hollow block,
Fig. 19 is a view showing a sectional view of the vibration-isolating block shown in Fig. 18,
20 is a perspective view showing still another embodiment of the masonry wall according to the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The above and other features and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings, There will be. The present invention is capable of various modifications and various forms, and specific embodiments are illustrated in the drawings and described in detail in the text. It is to be understood, however, that the invention is not intended to be limited to the particular forms disclosed, but on the contrary, is intended to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view showing an embodiment of a vibration-isolating block according to the present invention, and FIG. 2 is a cross-sectional view showing a longitudinal section of a vibration-isolating block according to the present invention.

The earthquake-proof blocks 100 and 100 'according to the present embodiment include a main body 110 made of a cement mortar material such as a general brick or the like and reinforcing bars 120 having end portions protruding along the circumferential surface of the main body 110. Here, the reinforcing bar 120 may be a conventional circular reinforcing bar or a deformed reinforcing bar. Preferably, the reinforcing bar 120 is provided with a deformed reinforcing bar to ensure the strength of the reinforcing bars 100 and 100 '.

The end portions of the reinforcing bars 120 are arranged in two rows along the circumferential surface of the main body 110 in the rectangular parallelepiped body 110 as shown in FIG. 1 in the present earthquake-proof blocks 100 and 100 '. At this time, the ends of the reinforcing bars 121 located on the plane and the bottom of the main body 110 and the ends 122 of the reinforcing bars located on the left and right sides are different from each other due to the characteristics of the reinforcing bars 120 do.

Although the reinforcing end portions 121 and 122 located in the main body 110 are two rows in the main body 110, they may be arranged in three rows or may be arranged in different rows. And 122 may vary, and thus the reinforcement structure of the reinforcing bars 120 may vary.

The main body 110 'of the present embodiment is coated with a cement mortar M (see FIG. 3) having an enhanced adhesive strength for adhesion between the seismic block 100 and 100' as shown in FIG. 1 (b) Bonding grooves 111 and 112 for widening the area of adhesion of the peripheral surface of the main body 110 'to the cement mortar are formed. Further, for the stable binding between the reinforcing bars 120 and the main body 110 'and the cement mortar, the binding grooves 111 and 112 are formed at the protruding points of the reinforcing ends 121 and 122.

In addition, the earthquake-proof block 100 'of the present embodiment is formed with the grooved grooves 113 on the front surface or the back surface of the body 110' which can be exposed to the outside. In this embodiment, the front surface or the rear surface of the concave groove 113 has a quadrangular shape conforming to the quadrangular shape of the main body 110 ', but the present invention is not limited thereto.

In FIG. 2, although the intersection points of the reinforcing bars 120 are shown without being bound to each other, the reinforcing rods 120 can be firmly bundled and fixed using wires to stably maintain the reinforcing rope 120.

Fig. 3 is a front view schematically showing one embodiment of a building wall to which a vibration-isolating block according to the present invention is applied, Fig. 4 is an enlarged view of P1 in Fig. 3 schematically showing another embodiment of a joint structure between seismic- .

The present invention is not limited to the above-described embodiments, but may be modified and changed without departing from the scope of the present invention. In this case, the seismic isolation block 100 is configured such that a plurality of corner sections A to D are combined with each other in the tetragonally shaped masonry wall 10, and a plurality of general blocks 200 are assembled in the other sections.

As mentioned in 'Seismic Performance Evaluation of Non-reinforced Masonry Buildings in Korea through Nonlinear Dynamic Analysis (Kim Jeong-hyun 2015.02, Graduate School of Busan National University)', the major failure mode that the masonry wall 10 receives is' horizontal joint slip shear failure mode 'And' rigid rotation failure mode ',' sign length failure mode 'and' both end compression failure mode '. This failure mode is obtained by separating the external force on the basis of the behavior of the external force applied to the masonry wall 10 and the basic frame 20 of the building Bd except the horizontal joint slip shear failure mode is installed at each corner of the masonry wall 10. [ Is directly impacted on the surface of the substrate.

Therefore, the present building wall 10 is reinforced with the corner sections A to D of the building wall 10 so that the seismic block 100 is maintained in a stable mate- rial state while resisting the impact applied by the basic frame 20 do.

The earthquake-proof blocks 100a to 100c combined with the corner sections A to D of the building wall 10 of the present embodiment are arranged in the upper left corner section A in the case of the basic frame 20 of the building Two earthquake-resistant blocks are disposed in an edge layer (hereinafter, referred to as 'base layer') of the masonry wall 10 to be brought into contact with the inner wall of the building wall 10, One anti-earthquake block is disposed in the lower layer (hereinafter referred to as 'second layered layer'), and the one-half earthquake-resistant block is disposed in the last lower layer (hereinafter referred to as 'third layered layer'). 3 shows the basic combination structure of the seismic block 100 to be placed in each of the corner sections A to D up to the three-tiered lamination. The seismic block 100 ) Is not limited to the number and the type, if the number and the arrangement type of the basic combination structure include the above-mentioned basic combination structure. The basic combination structure is four layers including the base layer and the first to third layers. However, since the vertical length of the vibration-isolating block 100 of the present embodiment is 2: 1, the corner sections A to D In order to match the ratio of the length to the length in contact with the basic frame 20 by 50:50. Accordingly, in the present embodiment, if there are two earthquake-resistant blocks 100 combined with the base layer, the corner sections A to D form four layers, and if the base layer is a combination of three earthquake blocks 100, A to D form six layers.

However, since the longitudinal and longitudinal lengths of the seismic block 100 do not coincide with each other, the number and the number of the seismic block 100 to be combined with the foundation layer are adjusted, ) Of the corner sections (A to D), which are constituted essentially of the corner sections (A to D). However, the lateral length and the longitudinal length of the corner sections A to D in the building wall 10 of the present embodiment are variously modified in accordance with the shape of the masonry wall 10 in contact with the basic frame 20, Of course.

Since the pressure applied by the basic frame 20 concentrates on each corner section A to D of the masonry wall 10, the stress that can be primarily supported by the basic framework 20 is not applied to the corner section (A to D). Since the pressure applied by the basic frame 20 should concentrate on the corner sections A to D as much as possible, the corner sections A to D must have a wide contact surface with the basic frame 20 to receive the pressure. Therefore, the base layer in contact with the transverse portion of the basic frame 20 in the corner sections A to D has the largest number of the seismic blocks 100 in the corner sections A to D and is combined with the basic frame 20 Of the corner sections A to D which contact the longitudinal section of the base layer is also matched with the lateral length corresponding to the longitudinal length corresponding to the number of the seismic block 100 combinations of the base layer.

3, the end portions 121 and 122 of the reinforcing bars 120 protrude from the circumferential surfaces of the seismic blocks 100a, 100b and 100c. Therefore, the adjacent seismic blocks 100a and 100b And 100c are disposed so as to face each other or to be staggered as shown in Fig. 4 (a). The reinforcing end portions 121 and 122 may be a length (refer to 'P1' in FIG. 3) facing the reinforcing end portions 121 and 122 of the adjacent seismic block 100a, 100b, or 100c, 100b may be a length that straddles the reinforcing end portions 121, 122 of the adjacent seismic block 100a, 100b, 100c as shown in FIG.

Subsequently, cement mortar M is applied between the seismic blocks 100a, 100b, and 100c to bond the seismic blocks 100a, 100b, and 100c together. At this time, the cement mortar M is not limited to adhesion to the peripheral surface of the vibration-proofing blocks 100a, 100b, 100c but also to the ends of the reinforcing bars 121, 122. As a result, the adjacent earthquake-proof blocks 100a, 100b and 100c can expand the contact area with the cement mortar M by the reinforcing end portions 121 and 122 protruding outwardly, and furthermore, 20, the reinforcing end portions 121, 22 are supported by the hardened mortar M, so that the current placing posture can be maintained.

As a result, each corner section A to D of the coarse wall 10 of the present embodiment has sufficient stress to a stable external pressure.

3, the general block 200 does not have the separate reinforcing end portions 121 and 122 such as the seismic block 100, and thus the circumferential surface is flat. Therefore, the joint structure of the seismic block 100 and the general block 200 has relatively lower stress than the joint structure between the seismic blocks 100, but has higher stress than the joint structure between the general blocks 200.

As shown in Fig. 4 (b) The coarse wall 10 may further include a linker 130 connecting the reinforcing ends 122 of the adjacent seismic blocks 100a and 100b to each other.

The shape, material, and material of the linker 130 of the present embodiment may be varied as long as the reinforcing end portions 122 can be connected to each other while facing each other. This embodiment will be described in more detail below.

FIG. 5 is a perspective view explaining another embodiment of a joint structure between a seismic block according to the present invention as shown in FIG. 4 (b).

The linker 130 of the present embodiment has the rings 131 and 132 inserted into the reinforcing end portions 122a and 122b of the adjacent seismic block 100a and 100b and the linking portions 131 and 132 integrally connecting the rings 131 and 132 Member 133 as shown in Fig. The width of the connecting member 133 is narrower than that of the rings 131 and 132 so that the rings 131 and 132 and the connecting member 133 are different from each other. Holes may be formed so that the reinforcing end portions 122a and 122b may be respectively fitted.

In addition, the linker 130 may be a general wire used for fastening portions intersecting with each other in the reinforced reinforcing bars 120. The worker who constructs the masonry wall 10 can connect the plurality of reinforcing end portions 122a and 122b integrally by weaving the reinforcing end portions 122a and 122b facing each other using the linker 130 of the wire function have.

FIG. 6 is a view schematically showing deformation and generated stress of a masonry wall according to the present invention by a frame of a building subjected to an external impact.

The above-described building walls 10a, 10b and 10c of the present embodiment function to divide a space by being laid out in a building Bd. In general, an edge portion of the building wall Bd is divided into a basic frame 20 ).

On the other hand, in a building Bd subjected to an earthquake or other external impact, a direct force F is applied to the basic frame 20, and when the force F is a lateral force, ) Tilting occurs as shown in the drawing. At this time, since the basic frame 20 has the earthquake resistance and the stress that can sustain the force of the reference value or more, deformation occurs without collapse corresponding to the force F. On the other hand, 10a, 10b, 10c can be collapsed under the pressure of the basic frame 20 due to the deformation. At this time, the section in which the basic frame 20 exerts the highest pressure on the masonry walls 10a, 10b, 10c is the corner sections A to D of the masonry walls 10a, 10b, 10c. However, in the present embodiment, the structural walls 10a, 10b and 10c have a sufficient stress due to the combination of the seismic blocks 100 in the corner sections A to D, Lt; / RTI > In addition, the pressure applied by the basic frame 20 is absorbed to minimize the transmission of the pressure to the general block 200. As a result, the building walls 10a, 10b and 10c of the present embodiment can maintain the shape corresponding to the pressure applied by the basic frame 200 due to the seismic performance of the seismic block 100 disposed in the curler sections A to D And the risk of collapse due to this can be minimized.

Fig. 7 is a front view schematically showing another embodiment of a masonry wall to which a vibration-isolating block according to the present invention is applied.

The present embodiment is configured such that the vibration-isolating block 100 is combined with the center section E of the masonry wall 10 'in addition to the corner sections A to D and the corner sections A to D, And the center section E are combined so as to be connected by the structure of the seismic block 100. That is, not only the corner sections A to D are combined by the seismic block 100 but also the center section E is also combined by the seismic block 100, The frame sections A to D and the central section E are connected to each other by the frame 100 so that a relatively rigid cross-shaped frame is reinforced in the rough wall 10 '.

As a result, the wall 10 'of the present embodiment absorbs the pressure of the basic frame 20 in the building Bd concentrated on the side surface, particularly the corner sections A to D, primarily by the corner sections A to D So that it is possible to minimize the impact of the general block 200 absorbed by the center section E and to prevent the collapsing of the pressure-applied masonry wall 10 '.

FIG. 8 is a perspective view showing a body of a vibration-isolating block according to the present invention constructed as a hollow block, and FIG. 9 is a perspective view showing another embodiment of a reinforcing bar formed in the vibration-isolating block according to the present invention.

The earthquake-proof blocks 300a and 300b according to the present embodiment are formed by arranging one or two or more hollows 311 through which the main body 310 passes vertically and constituting a perforation 312 on one side or both sides thereof. In this embodiment, the main body 310 has three hollows 311 and two side walls 312, but the number of the hollows 311 and 312 is not limited thereto.

Also, the present earthquake-proof blocks 300a and 300b constitute reinforcing bars 320a and 320b for rigid binding with other neighboring earthquake-resistant blocks, and the reinforcing bars 320a and 320b of the present embodiment penetrate the hollow 311 And a second body 322a and a second body 322b which are arranged laterally so that the end portion protrudes into the openwork 312. [ In the reinforcing bars 320a and 320b of the present embodiment, two first panties 321 are paired with each other in the hollows 311 and three pairs of second pantyholes 322a and 322b are arranged side by side. Here, the reinforcing bars 320a of the first vibration-isolating block 300a are arranged such that the second pillar body 322a forms three layers, and the second pillar bodies 322a of the upper layer, middle layer and lower layer are one, two, do. On the other hand, the reinforcing bars 320b of the second earthquake-proof block 300b are laid out so that the second pillar body 322b forms two layers, and the second pillar bodies 322b of the upper and lower layers are laid two and two.

On the other hand, the first pillar body 321 of the present embodiment is laid so as to protrude from the plane of the earthquake-proof blocks 300a and 300b, but does not protrude from the bottom surface. This is because even if the seismic blocks 300a and 300b of the upper layer compress the seismic blocks 300a ', 300b' and 300b 'of the lower layer by self weight while the earthquake-proof blocks 300a and 300b are cooperated, And the bottoms of the bottom seismic blocks 300a ', 300b', 300b "do not interfere with each other.

The first and second bodies 321 and 322b of the reinforcing bars 320a and 320b are connected to each other by the brackets 330 and 340 so that the reinforcing rods 320a and 320 can maintain the above- have. The first bracket 330 mediates the interconnection between the second bodies 322a and 322b and the second bracket 340 mediates the interconnection between the first body 321 and the second bodies 322a and 322b Lt; / RTI >

The brackets 330 and 340 may be simple wires so that the operator can tie the wires to the first and second bodies 321 and 322a and 322b and connect the first body 321 and the second body 322a , And a 'frame' connecting the 'rings' with each other, and a reinforcing bars 320a and 320b for connecting the 'rings'.

FIG. 10 is a perspective view showing the coupling between the seismic isolation blocks shown in FIG. 8, FIG. 11 is a plan view showing the coupling between the seismic isolation blocks shown in FIG. 8, FIG. 2 is a side view showing a state in which reinforcing bars are engaged with each other. FIG.

The earthquake-proof blocks 300a and 300b of the above-described structure are formed so as to be continuous with each other so that the openings 312 of the first and second earthquake-proof blocks 300a and 300b face each other, The earthquake-proof blocks 300a and 300b are coordinated with each other.

The second body 322a of the reinforcing bars 320a of the first earthquake-proof block 300a is composed of the upper layer, the middle layer and the lower layer as described above. The reinforcing bars 320b of the second earthquake- Is composed of an upper layer and a lower layer. Accordingly, as shown in FIG. 12, the second body 322a of each of the first and second vibration-isolating blocks 300a and 300b is inserted into the hollow space and engaged with the first and second earthquake-resistant blocks 300a and 300b, All. Therefore, even if the second body 322a and 322b are disposed so as to protrude from the openings 312 of the first and second seismic blocks 300a and 300b, the first and second seismic blocks 300a and 300b face each other They do not interfere with each other.

Further, when the cement mortar (not shown) is applied for bonding between the first and second vibration-proof blocks 300a and 300b, the second pores 322a and 322b function as a reinforcing bar while the first and second vibration- And 300b can be firmly coupled with each other.

The reinforcing bars 320a and 320b of the present embodiment are provided with a pair of reinforcing bars 320a and 320b arranged in one hollow 311 so as to be laid without mutual interference when the first and second pawls 321 and 322b intersect with each other, It is preferable that the interval between the shoulders 321 and the interval between the second bone bodies 322a and 322b is equal to or greater than the outer diameter of the body.

FIG. 13 is a perspective view showing another embodiment of the masonry wall according to the present invention, FIG. 14 is a sectional view of the masonry wall shown in FIG. 13, And Fig.

The supporting wall 400 is inserted into at least one of the hollow 311 and the openings 312 of the first and second vibration-proof blocks 300a and 300b, And the first and second earthquake-resistant blocks 300a and 300b.

Generally, the cement mortar for adhesive function is applied and connected between the first and second vibration-proof blocks 300a and 300b in the process of assembling the masonry wall. In this embodiment, the support roots 400 are connected to the hollow 311 and the hollow 312 and then cement mortar can be cured into the hollow 311 or the openwork 312 to cure it. Accordingly, the section where the first and second earthquake-proof blocks 300a and 300b are assembled is structured to have greatly improved seismic resistance and rigidity, and the section constituting the structure is formed at each corner of the masonry wall, Greatly increases the vibration resistance.

The support roots 400 may be of the same size as the rods 320a and 320b so that the support roots 400 are not interposed between the second ribs 322a and 322b when inserted between the bars 320a and 320b, You can deploy.

FIG. 16 is a partial cross-sectional view showing a combined wall structure according to the present invention combined with a basic frame of a building, and FIG. 17 is a perspective view showing an embodiment of a reinforcing panel according to the present invention.

A reinforcing panel 500 is provided on one side of the basic frame 20 to which the presently constructed wall wall is connected so that the basic frame 20 and the wall wall are bound to each other through the reinforcing panel 500. The reinforcing panel 500 includes a base 510 fixed to the basic frame 20 via an anchor or the like and protrusions 520 and 520 'configured to protrude from the base 510.

The base 510 may have a generally plate shape but preferably a groove 511 corresponding to the open hole 312 of the seismic block 300a or 300b is formed as shown in FIG. And 300b of the second projected body 322a. As a result, the contact cross-sectional area of the cement mortar for bonding the reinforcing panel 500 to the vibration-damping blocks 300a and 300b is widened, so that the firm bonding strength between the reinforcing panel 500 and the vibration-damping blocks 300a and 300b can be increased. Meanwhile, the base 510 is preferably made of a material capable of efficiently bonding with the cement mortar for bonding the earthquake-proof blocks 300a and 300b of the masonry wall to the basic masonry 20. Therefore, the present embodiment is the same mortar as the material of the earthquake-proof blocks 300a and 300b.

The protrusions 520 and 520 'protrude from the base 510 corresponding to the reinforcing bars 320a and 320b and may be made of a metal such as the reinforcing bars 320a and 320b. The protrusions 520 and 520 'of the reinforcing panel 500 of this embodiment are preferably formed at positions that do not interfere with the reinforcing bars 320a and 320b of the seismic blocks 300a and 300b. A first projection 520 formed to engage only with the second body 322a of the first earthquake-proof block 300a and a second projection 520 formed to engage only with the second body 322b of the second earthquake- (520 '). The first projection 520 has the same structure as the second body 322b of the second seismic block 300b and the second projection 520'is formed by the second body 322a of the first seismic block 300a. .

The protrusions 520 and the reinforcing bars 320a and 320b are coupled to the cement mortar to realize a strong binding between the seismic blocks 300a and 300b and the basic frame 20 of the masonry wall.

Fig. 18 is a perspective view showing another embodiment in which the main body of the vibration-isolating block according to the present invention is constituted by a hollow block, Fig. 19 is a view showing a sectional view of the vibration- Fig. 8 is a perspective view showing still another embodiment of the coarse wall according to the invention.

The earthquake-proof blocks 300a and 300b of the present embodiment pour mortar into the hollows 311 in which the reinforcing bars 320a and 320b are laid, and cure them to form a filling module CO. Accordingly, the reinforcing bars 320a and 320b, which are embedded in the vibration-proof blocks 300a and 300b, can ensure stable stability without shaking.

On the other hand, the filling module CO constitutes the cavity 311a under the hollow 311 and the lower end of the first bone body 321b laid on the hollow 311 is arranged so as not to protrude into the cavity 311a. This is because even if the seismic blocks 300a and 300b of the upper layer compress the seismic blocks 300a ', 300b', and 300b 'of the lower layer by self weight while the seismic block 300a and 300b are combined, So that the first bodies 321 of the blocks 300a and 300b and the lower bodies of the earthquake-proof blocks 300a ', 300b' and 300b 'do not interfere with each other.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

10, 10 ', 10a to 10c; Masonry wall 20; Basic frame
100, 100 ', 100a to 100c, 300a, 300b; Seismic block
110, 110 ',310; A body 111, 112; Binding groove
113; Concave grooves 120, 320a, 320b; rebar
121, 122 ', 122a, 122b; A reinforcing end 130; Linker
131, 132; Ring 133; Connecting member
200; General block 400; Support
500; Reinforcing panel 510; Base
520; spin
A to D; Corner section E; Central section

Claims (8)

1. A seismic block comprising a main body and a plurality of reinforcing bars arranged such that the end portions protrude from the outer surface of the main body,
Wherein the main body is a hollow block constituted by one or two or more hollows passing vertically and constituting a hollow structure on one side or both sides thereof;
Wherein the reinforcing bars are composed of a first body and a second body arranged in the longitudinal direction so as to penetrate through the hollow and a second body arranged in the lateral direction so that the end portions protrude from the concave hole. The method according to claim 1,
Wherein the main body has a coupling groove formed at a point where the end of the reinforcing bar protrudes. delete The method according to claim 1,
Wherein the second core body is laid out in three layers, and the upper layer, middle layer and lower layer are laid one, two and one, respectively, or two layers are laid out, and the upper and lower layers are laid two at each. The method according to claim 1,
Wherein the first annular body is disposed so as to protrude only in a plane of the main body. In a masonry wall in which a plurality of general blocks are assembled in a staggered manner,
A plurality of earthquake-resistant blocks assembled in a triangular shape are formed in each corner section of the rough wall; Wherein the seismic block includes a body and a plurality of reinforcing bars arranged such that an end of the reinforcing block protrudes from an outer surface of the body;
A base provided on one side of the basic frame of the building and connected to the masonry wall and having a groove; The upper and lower layers are formed as three layers arranged one by one, two and one, and the upper and lower layers are formed by two layers A reinforcing panel
Further comprising a plurality of projecting walls. The method according to claim 6,
Wherein the earthquake-proof block is combined with the center section of the masonry wall, and the corner section and the center section are connected to each other by the masonry structure of the earthquake-proof block. delete

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