KR102129397B1 - A column earthquake-proof structure of HANOK(traditional korean style house) - Google Patents

Abstract

The present invention relates to a quake-separated structure of a hanok, and more specifically, when an earthquake or vibration occurs due to an external force, it is configured to restrain the detachment of the pillar from the main stone in the upper direction and restore the original position after the column is moved to the side, It is about the seismic isolation structure of a pillar of Hanok, which has increased the seismic isolation efficiency.
To this end, the pillars of Hanok architecture; A main foundation supported on the ground and supporting the pillars; It is installed between the pillar and the main stone, and when the vibration occurs in the building caused by external force, the pillar is moved and restored by external force to cushion the external force. A pair of isolating pads overlapping in the downward direction and having concave round grooves formed in opposite directions on opposite portions; A ball member made of a sphere interposed between round grooves of the isolating pad includes: a diameter of the ball member is a size capable of separating a pair of isolating pads from each other, and the isolating pad is upper and lower. A pierced through hole is formed, and a fixing pin passing through the through hole of the seismic pad is installed on the main stone, and an insertion groove having a diameter larger than the diameter of the fixing pin is formed on the pillar, and the fixing pin is located in the insertion groove. It provides a seismic isolation structure of a pillar of hanok, characterized in that.

Description

A column earthquake-proof structure of HANOK (traditional korean style house)}

The present invention relates to a pillar isolation structure of a hanok, and more particularly, to a pillar isolation structure of a hanok that enhances the seismic isolation efficiency by suppressing the separation of the pillars in the upper direction and allowing the pillars to move and be restored to the side. .

Hanok refers to a building built in the traditional Korean architectural style. First, the foundation is to be built on the site to be built, the main stone is placed on the place where the pillars are to be built, and the pillars are placed on the main pillars. Intersect to form space.

Then, a room floor having an ondol is formed on the inner floor of the space, and between the pillars and the pillars are blocked with earth bricks or windows to partition the room and the floor, and roofs are formed by placing tiles on the rafters or buoys.

At this time, the girders and pillars are used to support the load on the roof of the hanok. The wooden girders are vulnerable to bending moments caused by the load, and are structurally weak due to twisting or cracking after construction.

Accordingly, in order to distribute the load on the roof, a pillar is also built inside the hanok to construct it.

However, since the hanok of the above-described structure is not considered to have a seismic isolation design compared to a western-style building, it is made of a vulnerable structure that is difficult to withstand its eddy force in the event of vibration due to earthquake and external force.

Accordingly, there was a high risk of secondary accidents, such as falling roof tiles even in the event of a small earthquake.

In particular, there is no problem in structural stability when the vertical load by magnetic force is greater than the horizontal load by wind and earthquake, but there is a risk of the collapse of the pillar.

As described above, as the pillar of the hanok is made of a structure supporting the roof, the design of the pillar that becomes the main axis is important. Conventionally, there is no device and seismic design for safety inspection of the pillar, and vibration due to earthquake and external force It is a fragile structure with a high risk of collapsing during occurrence, which increases the rigidity of the pillar structure of hanok and requires seismic isolation.

Republic of Korea Registration No. 10-1754939

The present invention has been devised to solve the above problems, and the object of the present invention is to provide a separate seismic coupling means between the main foundation and the pillars, wherein the seismic coupling means has a column flow in the direction of pillar movement due to external force. The goal was to provide a Hanok's pillar seismic isolation structure to maximize the seismic efficiency in the left and right directions as well as in the up and down directions by allowing it to be returned to its original position and fixing the pillars and cornerstones through steel joining.

The present invention to achieve the above object, for this purpose, the pillars of the hanok building; A main foundation supported on the ground and supporting the pillars; It is installed between the pillar and the main stone, so that when the vibration occurs in the building caused by external force, the pillar is moved and restored by external force so as to buffer the external force. A pair of isolating pads overlapping in the downward direction and having concave round grooves formed in opposite directions on opposite portions; A ball member made of a sphere interposed between round grooves of the seismic pad includes: A diameter of the ball member is a size capable of separating a pair of seismic pads from each other, and the seismic pad has upper and lower sides. A through hole is formed, a fixing pin passing through the through hole of the seismic pad is installed on the main foundation, an insertion groove having a diameter larger than the diameter of the fixing pin is formed on the pillar, and the fixing pin is located in the insertion groove It provides a seismic isolation structure of a pillar of hanok, characterized in that.

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At this time, the insertion groove portion is fixed to the joint member having an opening groove opened toward the fixing pin, and the fixing pin is provided with a connecting member having a diameter larger than the diameter of the opening groove, and the connecting member is made of a stretchable material. It is preferably inserted into the opening groove while being stretched, and the bottom surface of the connecting member is configured to be hung and supported inside the opening groove.

In addition, a plurality of the round grooves are formed around the through hole, and it is preferable that the through hole of the isolating pad located at the top of the pair of isolating pads has a larger diameter than the through hole of the isolating pad located at the bottom.

In addition, between the isolating pad and the pillar, an interlocking bracket having an extension piece extending from the isolating pad toward a neighboring pillar is further interposed, and an extension piece of the interlocking bracket can be fixed with a beam or seal connecting between adjacent pillars. It is desirable.

Pillar seismic isolation structure of hanok according to the present invention has the following effects.

First, by interposing a pair of isolating pads in the up and down direction between the pillar and the main stone, and constructing a ball member between the isolating pads, the pillar can be moved to the original position based on the main stone. .

Accordingly, the pillar can flexibly respond to the external force, thereby increasing the efficiency of seismic isolation of the entire hanok.

Second, by fixing the fixing pin protruding upward on the main stone, and fixing the conical connection member on the upper end of the fixing pin, the inside of the lower part of the pillar is configured so that the connecting member can be hung and supported, thereby making the pillar the main stone It can be suppressed to deviate upward as a reference.

Accordingly, when an external force occurs due to an earthquake, the pillar has an effect of increasing the seismic efficiency in the up, down, left, and right directions.

Third, of the pair of isolating pads, the upper isolating pads are further provided with interlocking brackets extending from both sides of the upper isolating pads, and the interlocking brackets are fixed with beams or seals connecting adjacent pillars, Pillar isolation efficiency can also affect beams or linings.

Accordingly, since the movement of the entire hanok column can be interlocked, there is an effect of further increasing the seismic isolation efficiency.

Fourth, by connecting an elastic means between the main stone and the pillar, it is possible to increase the efficiency of the pillar being moved and restored by external force, and it is possible to limit excessive movement of the isolating pad.

1 is an exploded perspective view showing a quake seismic structure of a hanok according to a preferred embodiment of the present invention
Figure 2 is a front view showing an exploded column isolation structure of a hanok according to a preferred embodiment of the present invention
Figure 3 is a front view showing an exploded column isolation structure of a hanok according to a preferred embodiment of the present invention
Figure 4 is a cross-sectional view showing the seismic coupling means of the pillar isolation structure of a hanok according to a preferred embodiment of the present invention
Figure 5 is a cross-sectional view showing a pillar isolation structure of a hanok according to a preferred embodiment of the present invention
6 and 7 are functional diagrams showing the action of the pillar isolation structure of a hanok according to a preferred embodiment of the present invention
Figure 8 is a perspective view showing the interlocking bracket of the pillar isolation structure of a hanok according to another embodiment of the present invention
9 is a front view showing a pillar isolation structure of a hanok according to another embodiment of the present invention
Figure 10 is a cross-sectional view showing a seismic pad of the pillar isolation structure of a hanok according to another embodiment of the present invention.

The terms or words used in the present specification and claims are not to be construed as being limited to ordinary or lexical meanings, and the inventor is based on the principle that the concept of terms can be properly defined in order to best describe his or her invention. It should be interpreted in a sense and concept consistent with the technical idea of the present invention.

Hereinafter, a pillar isolating structure of a hanok according to a preferred embodiment of the present invention will be described with reference to FIGS. 1 to 7.

In the case of an earthquake or vibration caused by external force, Hanok's pillar isolating structure can suppress the separation of the pillar in the upper direction and increase the isolation efficiency by allowing the pillar to move and return to its original position by an external force in the lateral direction.

For this, the pillar isolation structure of the hanok includes a pillar 100, a main foundation 200, and an isolation coupling means 300, as shown in FIGS. 1 and 2.

The pillar 100 is a structure supporting the roof of a hanok, and serves to support beams, purlins, and the like of the roof.

The pillar 100 is made of wood, and is supported by the main foundation 200.

In the lower portion of the pillar 100, an insertion groove portion 110 opened downward is formed.

The insertion groove 110 is a space for installation of a joining member, which will be described later.

Next, the main stone 200 serves as a base for supporting the pillar 100, and is made of stone.

At this time, the fixing pin 210 protruding upward of the main foundation 200 is installed on the main foundation 200.

The fixing pin 210 has a configuration in which a connecting member described later is installed, and serves to guide the position of the isolating pad on the main foundation 200.

The fixing pin 210 is preferably embedded in the main stone 200.

Next, the seismic coupling means 300 is interposed between the pillar 100 and the main stone 200, and serves to couple the pillar 100 to the main stone 200, but when the vibration occurs in the building, the pillar ( 100) Suppress the departure and provide the movement of the pillar 100 to the side to increase the buffering efficiency.

The seismic coupling means 300 includes a seismic pad 310, a ball member 320, a joining member 330, and a connecting member 340.

The vibration isolating pad 310 is configured to move the pillar 100 when vibration is caused by external force, and is configured as a pair between the pillar 100 and the main stone 200.

The isolation pad 310 is composed of an upper isolation pad 311 and a lower isolation pad 312, as shown in FIGS. 1 and 2.

The upper isolating pad 311 is formed with a through hole 311a and a round groove 311b on the opposite surface of the lower isolating pad 312.

At this time, for convenience of description, the through hole formed in the upper isolation pad 311 is referred to as an upper through hole 311a, and the round groove formed in the upper isolation pad 311 is referred to as an upper round groove 311b.

The upper through hole 311a is a portion through which the fixing pin 210 passes, guides the position of the upper isolation pad 311, and the movement of the upper isolation pad 311 based on the fixing pin 210 is smoothly achieved. It plays a role to help.

At this time, the diameter of the upper through hole 311a is larger than the diameter of the fixing pin 210, and is made to a size that can smoothly move the upper isolation pad 311 by external force.

The upper round groove 311b is formed in a concave groove shape capable of accommodating the upper portion of the ball member 320.

4, the upper round groove 311b is formed to become deeper toward the center from the edge, so that the movement of the upper isolating pad 311 based on the ball member 320 can be smoothly performed.

The upper round groove 311b is formed in plurality on the upper isolating pad 311 around the upper through hole 311a.

The number of upper round grooves 311b is not limited, but it is preferable that the number of upper round grooves 311b is provided in four so that the pillars 100 can move in all directions.

The lower isolating pad 312 constitutes a lower portion of the isolating pad 310 and is opposed to the upper isolating pad 311.

That is, the upper isolation pad 311 corresponds to the pillar 100, and the lower isolation pad 312 corresponds to the main foundation 200.

The lower isolation pad 312 also forms a through hole 312a and a round groove 312b.

At this time, for convenience of description, the through hole formed in the lower isolation pad 312 is referred to as a lower through hole 312a, and the round groove formed in the lower isolation pad 312 is referred to as a lower round groove 312b.

The lower through hole 312a is a portion through which the fixing pin 210 passes, and guides the position of the lower isolation pad 312.

At this time, the diameter of the lower through hole 312a corresponds to the diameter of the fixing pin 210.

Since the lower isolation pad 312 does not need to move on the main foundation 200, there is no need to generate a large gap between the fixing pin 210 and the lower through hole 312a, and the diameter of the lower through hole 312a is fixed pin. If it is large enough to allow 210 to pass, it may be used.

Accordingly, as illustrated in FIG. 4, it is natural that the diameter of the lower through hole 312a is smaller than the diameter of the upper through hole 311a.

The lower round groove 312b is opposed to the upper round groove 311b, and the shape and size of the lower round groove 312b is preferably the same as the shape and size of the upper round groove 311b.

Then, the ball member 320 is interposed between the upper isolating pad 311 and the lower isolating pad 312, is provided as a medium for the movement of the upper isolating pad 311.

The ball member 320 is formed of a sphere, and is located in the round grooves 311b and 312b.

The upper portion of the ball member 320 is accommodated in the upper round groove 311b, and the lower portion of the ball member 320 is accommodated in the lower round groove 312b.

At this time, the diameter of the ball member 320 is a size that allows the upper isolating pad 311 and the lower isolating pad 312 to be spaced apart from each other while the ball member 320 is located in the round grooves 311b and 312b. to be.

And, the joining member 330 is a medium for connecting the main foundation 200 and the pillar, together with the connecting member 340, and is fixed to the insertion groove 110 of the pillar 100.

Considering the material of the pillar 100 made of wood, the material of the joining member 330 is preferably a metal.

This is because the materials of the fixing pin 210 and the connecting member 340 coupled to the bonding member 330 are metal, so as to increase mutual rigidity.

The joining member 330 corresponds to the insertion groove portion 110, and is preferably made of a hollow cylindrical shape.

At this time, an opening groove 331 that is opened downward is formed in the lower portion of the bonding member 330.

Then, the connecting member 340 is coupled to the bonding member 330, and connects the main stone 200 and the pillar 100, and serves to suppress the pillar 100 from being displaced upward when vibration occurs in the building.

The connecting member 340 is fixed to the upper end of the fixing pin 210, and is inserted and disposed inside the bonding member 330, so that the bonding member 330 interferes with the connecting member 340 and moves upward. It can be redeemed.

The connecting member 340 may be fixed to the fixing pin 210 through welding. The connecting member 340, as shown in Figure 5, since the lower portion is open toward the bottom, the operator connects the fixing pin 210 through the opened lower portion of the connecting member 340, the connecting member 340 It can be fixed by welding to the inner side of the contact.

On the other hand, the connecting member 340 is located inside the bonding member 330 through the opening groove 331, is formed so as not to escape through the opening groove 331.

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To this end, the connecting member 340 is preferably made of a triangular conical section.

In addition, the connecting member 340 is made of a stretchable material, and the maximum diameter of the connecting member 340 is formed larger than the diameter of the opening groove 331.

Accordingly, the connecting member 340 is smoothly inserted through the opening groove 331, and is contracted after being caught in the opening groove 331 and is positioned while being restored inside the bonding member 330, so that the connecting member 340 As shown in 5, it is caught in the opening groove 331 and does not exit downward.

Hereinafter, it will be described with respect to the coupling and operation of the pillar isolation structure of hanok made of the above-described configuration.

The lower isolation pad 312 is positioned on the main foundation 200.

At this time, the fixing pin 210 passes through the lower through-hole 312a of the lower isolation pad 312, and the lower isolation pad 312 is seated on the main foundation 200.

Next, the ball member 320 is positioned in each lower round groove 312b formed in the lower seismic pad 312.

At this time, the ball member 320 is located in the center of the lower round groove 312b.

Next, the upper isolation pad 311 is covered on the ball member 320.

At this time, the upper round groove 311b of the upper isolation pad 311 receives the upper portion of the ball member 320, and the fixing pin 210 passes through the upper through hole 311a.

At this time, the upper isolating pad 311 and the lower isolating pad 312 are spaced apart in the vertical direction, as shown in FIG.

Next, the connection member 340 is fixed to the fixing pin 210 exposed above the upper isolation pad 311.

At this time, the connecting member 340 may be fixed to the fixing pin 210 through welding as described above.

Next, the bonding member 330 is fixed to the insertion groove 110 of the column 100, and the column to which the bonding member 330 is fixed is seated on the upper isolation pad 311.

At this time, the cone-shaped connecting member 340 is inserted through the opening groove 331 of the joining member 330, and the connecting member 340 is caught in the opening groove 331 and contracted and then restored, and then the opening groove 331 is restored. Through is inserted into the bonding member 330.

Since the largest diameter of the connecting member 340 is larger than the diameter of the opening groove 331, as shown in FIG. 5, the connecting member 340 is pulled out of the bonding member 330 from the opening groove 331 Does not occur.

As such, a series of processes of combining the pillars 100 with the main stone 200 are performed for each pillar 100 of the hanok building.

On the other hand, when the vibration due to an earthquake or external force occurs in the hanok building where the pillars 100 are combined on the main foundation 200 as described above, the external force also acts on the pillars 100.

At this time, the pillar 100 is moved by an external force, and the upper isolating pad 311 to which the pillar 100 is fixed is left on the drawing based on the ball member 320 as shown in FIGS. 6 and 7. Or move to the right.

Thereafter, as the upper isolation pad 311 is restored to its original position by the clouds of the ball member 320, the pillar 100 is also returned to its original position as shown in FIG. 5.

At this time, since there is a gap between the fixing pin 210 and the upper through hole 311a, the movement of the upper isolation pad 311 can be freely performed within the gap.

As can be seen from this, even if vibration occurs in the pillar 100, the pillar isolating structure of the hanok according to the preferred embodiment of the present invention is made to move by vibration rather than resisting the vibration, By damping the force due to vibration, it is possible to alleviate the impact transmitted to the pillar (100).

That is, when a lateral force due to an earthquake or external force occurs in a hanok building, the upper isolating pad 311 can move in all directions through the ball member 320 regardless of the direction of the lateral force, thereby increasing the vibration isolation efficiency due to the lateral force. .

In addition, the joining member 330 fixed to the insertion groove 110 of the pillar 100 is locked by the connection member 340, even when the force direction due to external force acts upward, the pillar 100 It can suppress that it deviates upwards.

On the other hand, between the pillar 100 and the pillar 100 of a hanok building, a beam or seal is installed to support the pillar 100 by connecting it.

At this time, the above-described seismic coupling means 300 may be configured to be interlocked with a beam or a person.

This is presented as another embodiment of the present invention, and will be described with reference to FIGS. 8 and 9.

Prior to the description, the same configuration as in the preferred embodiment is denoted by a reference numeral and a detailed description will be omitted.

As shown in Figure 8, the interlocking bracket 400 is provided.

The interlocking bracket 400 is interposed between the upper isolation pad 311 and the pillar 100.

The interlocking bracket 400 is composed of a plate 410 corresponding to the upper isolating pad 311 and an extension piece 420 extending from the plate 410 to both sides of the isolating pad 310.

The extension piece 420 corresponds to a beam or seal connecting between the pillars 100, and a fixing hole 421 is formed in the extension piece 420.

The interlocking bracket 400 having such a configuration is interposed between the upper isolating pad 311 and the pillar 100, as shown in FIG. 9, and the extension piece 420 is fixed to the beam or seal through a screw.

As the interlocking bracket 400 is installed in this way, it is possible to maximize the seismic efficiency of the entire hanok building because it can be interlocked with the beam or the room when the seismic coupling means 300 described above acts.

On the other hand, the seismic pad 500 of the seismic coupling means 300 may be provided with an elastic means (500).

This is to increase the restoring force of the upper isolating pad 311, and to limit excessive movement of the upper isolating pad 311.

This is presented as another embodiment of the present invention, and will be described with reference to FIG. 10 attached.

Prior to the description, the same configuration as in the above-described embodiment is denoted by a reference numeral, and detailed description is omitted.

10, an elastic means 500 is installed between the upper isolation pad 311 and the lower isolation pad 312.

At this time, the elastic means 500 is preferably a spring.

Thus, since the elastic means 500 connects both sides of the seismic pad 310, the upper seismic pad 311 prevents the problem that the upper seismic pad 311 may excessively move away from the lower seismic pad 312, and the ball member ( 320) by providing the restoring force of the upper isolation pad 311, the restoration process of the upper isolation pad 311 can be made flexibly.

In addition, a central guide groove 313 is formed in the lower round groove 312b of the lower isolation pad 312.

The central guide groove 313 guides the position of the ball member 320 on the lower round groove 312b to the center, and restricts excessive movement of the pillar 100 by preventing the ball member 320 from moving during minute vibration. Plays a role.

The central guide groove 313 is formed in the form of a recess in the center of the lower round groove 312b, and its cross section is preferably made of an arc.

Due to the configuration of the central guide groove 313, the ball member 320 is normally located in the central guide groove 313, and the movement of the ball member 320 is limited to minute vibrations, so the upper isolating pad 311 and The movement of the pillar 100 fixed to the upper isolation pad 311 is also limited.

As described so far, the hanok pillar seismic structure according to the present invention suppresses the column departure when the earthquake or vibration occurs due to external force, and moves the pillar by the external force to the side to restore it to its original position. This collapse or breakage can be suppressed as much as possible.

In particular, it is possible to maximize the seismic efficiency of hanok using this principle.

In the above, the present invention has been described in detail with respect to the described embodiments, but it is apparent to those skilled in the art that various modifications and variations are possible within the technical scope of the present invention, and it is natural that such modifications and modifications belong to the appended claims.

100: pillar 110: insert groove
200: main stone 210: fixing pin
300: vibration isolation coupling means 310: vibration isolation pad
311: upper isolation pad 311a: upper through hole
311b: upper round groove 312: lower isolation pad
312a: lower through hole 312b: lower round groove
313: Central guide groove 320: Ball member
330: bonding member 331: opening groove
340: connecting member 400: interlocking bracket
410: Plate 420: Extension
421: fixing hole 500: elastic means

Claims (5)

Pillars of hanok architecture;
A main foundation supported on the ground and supporting the pillars;
It is installed between the pillar and the main stone, so that when the vibration occurs in the building by external force, the pillar is moved and restored by external force to cushion the external force.
The seismic coupling means,
A pair of isolating pads that are overlapped in the up and down directions, and the recessed round grooves are formed in opposite portions of the opposite portions;
The ball member made of a sphere interposed between the round grooves of the seismic pad includes:
The diameter of the ball member is a size that can space a pair of isolation pads from each other,
The through-hole penetrating the upper and lower holes is formed in the isolating pad,
A fixing pin passing through the through hole of the seismic pad is installed on the main foundation stone,
The pillar is formed with an insertion groove having a diameter larger than the diameter of the fixing pin, and the fixing pin is a pillar isolating structure of a hanok, characterized in that located in the insertion groove. delete According to claim 1,
A joining member having an opening groove opened toward the fixing pin is fixed to the insertion groove portion,
The fixing pin is provided with a connecting member having a diameter larger than the diameter of the opening groove,
The connecting member is made of a stretch material and is inserted into the opening groove while being stretched, and the bottom surface of the connecting member is configured to be supported by hanging inside the opening groove. The method of claim 1 or 3,
A plurality of round grooves are formed around the through hole,
Among the pair of isolating pads, the borehole of the isolating pad located on the upper side has a larger diameter than that of the isolating pad located on the lower side. The method of claim 1 or 3,
An interlocking bracket is formed between the isolating pad and the pillar, and an extension piece extending from the isolating pad toward the adjacent pillar is further interposed.
Column extension structure of a hanok, characterized in that a beam or seal connecting between adjacent pillars can be fixed to the extension piece of the interlocking bracket.

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