KR102210420B1 - Wooden house with seismic structure - Google Patents

Abstract

The present invention relates to a wooden house with an earthquake-proof structure, which is manufactured by using wood. The wooden house with the earthquake-proof structure is configured to be prevented from collapsing even under vibration or shaking caused by an earthquake. The wooden house with the earthquake-proof structure includes: a wooden house manufactured by using the wood, a support frame installed on a lower side of the wooden house to support the wooden house; earthquake-proof parts installed on one side and the other one side of a lower portion of the support frame to absorb the vibration or impact transmitted through the support frame; and a baseplate which is installed on the surface of the ground and in which the earthquake-proof parts are mounted on one side and the other side of an upper portion.

Description

Wooden house with seismic structure {WOODEN HOUSE WITH SEISMIC STRUCTURE}

The present invention relates to a wooden house having a seismic structure, and more particularly, in a wooden house manufactured using wood, a wooden house with a seismic structure implemented to prevent collapse even by vibration or vibration caused by earthquakes. It's about housing.

In general, as a method of reinforcing the structural material of a wooden building, a method of arranging an inclined brace or an angle brace, or fixing a reinforcing metal ball to a joint between a foundation and a column, and a column and a girder is adopted. .

The method of fixing the reinforcing metal ball is adopted to prevent the column, girder, etc. from separating from the joint. For example, an L-shaped metal ball in which a metal plate is bent in an L shape is placed at the edge of the joint between the base and the column, and the bolt , A method of fixing with wood fixing screws, nails, etc., a T-shaped metal ball cut into a T-shaped metal plate is attached to the outer surface of the joint between the base and the column, and fixed with bolts, wood fixing screws, nails, etc. Methods and the like are being employed.

In addition, as a method of reinforcing the structural material of a wooden building, a large area of steel plate is disposed so as to cover the entire outer wall surface, and fixed using bolts, wood fixing screws, nails, etc. to the foundation, column, girder, and crossbeam. Is also adopted, and according to this method, it can be strongly reinforced because it can receive external shocks over a large area.

However, in the case of a conventional seismic structure of a wooden structure, it is difficult to easily provide a seismic design for a wooden structure because the structure is complex and requires a lot of manpower and cost to install it.

On the other hand, the above-described background technology is technical information that the inventor possessed for derivation of the present invention or acquired during the derivation process of the present invention, and is not necessarily a known technology disclosed to the general public prior to filing the present invention. .

Korean Patent Publication No. 10-2002-0092151 Korean Utility Model Registration No. 20-0358918

One aspect of the present invention is implemented to efficiently absorb vibrations or shocks transmitted from the ground or from the wooden house itself by adding a seismic structure to the lower side of a wooden house manufactured using wood. Provide a wooden house with a seismic structure.

The technical problem of the present invention is not limited to the technical problem mentioned above, and other technical problems that are not mentioned will be clearly understood by those skilled in the art from the following description.

A wooden house with a seismic structure according to an embodiment of the present invention, a wooden house manufactured using wood; A support frame installed below the wooden house to support the wooden house; An earthquake-proof unit installed on one lower side and the other side of the support frame to absorb vibration or shock transmitted through the support frame; And a base plate installed on the ground surface and on which the seismic part is seated on one side of the upper side and the other side.

In one embodiment, the support frame, a first horizontal bar on which the lower one side of the wooden house is seated; A second horizontal bar on which the other lower side of the wooden house is seated; And a plurality of vertical bars installed along between the first horizontal bar and the second horizontal bar.

In one embodiment, the seismic part, a seating frame on which one lower side or the other side of the support frame is seated; And a vibration absorbing unit that is installed along a lower side of the seating frame and individually absorbs vibrations or shocks transmitted through the seating frame by using an elastic force.

In one embodiment, the vibration absorbing unit, the upper support for supporting the lower side of the seating frame; A support pillar having the upper pedestal installed on the upper portion thereof, and attenuating the vibration transmitted through the upper pedestal using an elastic force; And a lower pedestal installed below the support pillar and formed in a symmetrical structure with the upper pedestal and seated in an upper groove formed on the upper portion of the base plate to support the support pillar.

In an embodiment, the upper pedestal includes four support plates formed in a flat plate shape to support the lower side of the seating frame; Four support bars that are connected and installed so that the upper part is rotatable at the lower side of the edge of the support plate facing the edge of the other support plate located in the diagonal direction, and the lower part is connected to the upper part of the support column so as to be rotatable; And the support plate is connected and installed so that the upper part is rotatable at the lower side of the opposite edge of the edge where the support bar is installed, the lower part is connected to the upper part of the support column, and the edge of the support plate is elastic force. It may include; 4 elastic bars supported by using.

In an embodiment, the elastic bar includes: a first bar connected to and installed at a lower side of a corner opposite to an edge on which the support bar is installed in the support plate so that an upper portion thereof is rotatable; A second bar connected to and installed at a lower portion of the support column so as to be rotatable below a position at which the lower portion of the support bar is installed; A case in which a lower portion of the first bar is inserted into the inner space to slide and the upper portion of the second bar is inserted into the inner space to slide; And an elastic body installed between the lower side of the first bar and the upper side of the second bar in the inner space of the case to form an elastic force in a direction in which the lower side of the first bar and the upper side of the second bar are separated from each other; can do.

In one embodiment, the support pillar includes an upper support that is connected to each individual groove of a "+"-shaped fastening groove formed on the upper part so that the lower part of each of the four support bars is rotatable; A lower support having a symmetrical structure with the upper support, and having the lower support connected to the lower part; A column body in which a lower portion of the upper support is slidably moved by being inserted into the inner space, and an upper portion of the lower support is inserted into the inner space to be slid; And an elastic body installed between the upper support and the lower support in the inner space of the pillar body to form an elastic force in a direction in which a lower side of the upper support and an upper side of the lower support are separated from each other.

In one embodiment, a wooden house having a seismic structure according to another embodiment of the present invention is installed along a spaced space between the seating frame and the base plate to prevent the seating frame from sitting down; It may contain more.

In one embodiment, the frame support portion, a base frame formed in the shape of a square plate to be seated on the upper side of the base plate; An elastic support frame having a lower side inserted into the seating groove formed on the upper side of the base frame, and supporting the seating frame seated on the upper side using an elastic force; And an auxiliary support frame formed in a flat plate shape and connected to the elastic support frame so as to be rotatable, and supporting the seating frame by standing upright when the spaced space between the seating frame and the base plate cannot be supported by only the elastic support frame. It may include.

In one embodiment, the elastic support frame, at least one elastic body installed in the seating groove; A support plate formed into a flat plate having a shape corresponding to the shape of the seating groove; A frame main body seated on the upper side of the support plate; An insertion protrusion protruding from the lower side of the frame body to correspond to the shape of the seating groove, and being inserted into the seating groove and supported by the support plate; A receiving groove formed on an upper portion of the frame body in a shape corresponding to the shape of the auxiliary support frame to be opened to one side of the frame body; Lower fastening grooves respectively formed under the walls of both sides of the entrance of the receiving groove; And inclined fastening grooves that are respectively formed to be inclined to be inclined from the lower side of the wall on both sides of the receiving groove to the upper side of the inlet of the receiving groove.

In one embodiment, the auxiliary support frame, the support body formed in a shape corresponding to the shape of the receiving groove; Lower fastening protrusions protruding from both lower sides of the support body so as to be fastened to the lower fastening groove; And a rotation guide portion formed on one or both sides of the lower part of the support body so as to be fastened to the inclined fastening groove and to be moved along the inclined fastening groove.

In one embodiment, the rotation guide unit, the sliding groove formed in the vertical direction along one side of the support body; A sliding guide groove extending in a vertical direction along both side walls of the sliding groove; A moving part inserted into the sliding groove and sliding in the vertical direction; A separation preventing protrusion protruding from both sides of the moving part so as to prevent the moving part from being separated from the sliding groove and fastened to the sliding guide groove; A sliding protrusion protruding from the front surface of the moving part so as to be moved along the inclined fastening groove; And an elastic support part installed in an upper space and a lower space of the sliding guide groove to which the moving part is fastened so that the moving part can be supported by using an elastic force in the sliding guide groove.

In one embodiment, the inclined fastening groove may have an end positioned at the entrance of the receiving groove bent upward so as to prevent the sliding protrusion from returning to the inside of the receiving groove.

According to one aspect of the present invention described above, by adding a seismic structure for absorbing vibration or shock to the lower side of a wooden house manufactured using wood, it efficiently absorbs vibration or shock transmitted from the ground or from the wooden house itself. , The construction is simple, the construction cost is low, and it can provide an effect that can exhibit excellent earthquake resistance.

The effects of the present invention are not limited to the above-mentioned effects, and various effects may be included within a range apparent to those of ordinary skill in the art from the contents to be described below.

1 is a view showing a schematic configuration of a wooden house having a seismic structure according to an embodiment of the present invention.
2 is an exploded perspective view of the present invention.
3 is a view showing the vibration absorbing unit of FIG. 2.
4 is a view showing the upper pedestal of FIG. 3.
5 to 7 are views showing the support pillar of FIG. 3.
8 is a view showing a frame support according to the present invention.
9 and 10 are views showing a connection relationship between the base frame of FIG. 8 and the elastic support frame.
11 is a view showing the rotation induction part of FIG. 10.

DETAILED DESCRIPTION OF THE INVENTION The detailed description of the present invention described below refers to the accompanying drawings, which illustrate specific embodiments in which the present invention may be practiced. These embodiments are described in detail sufficient to enable a person skilled in the art to practice the present invention. It is to be understood that the various embodiments of the present invention are different from each other but need not be mutually exclusive. For example, certain shapes, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the present invention in relation to one embodiment. In addition, it is to be understood that the location or arrangement of individual components within each disclosed embodiment may be changed without departing from the spirit and scope of the present invention. Accordingly, the detailed description to be described below is not intended to be taken in a limiting sense, and the scope of the present invention, if properly described, is limited only by the appended claims, along with all scopes equivalent to those claimed by the claims. Like reference numerals in the drawings refer to the same or similar functions over several aspects.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the drawings.

1 is a view showing a schematic configuration of a wooden house having a seismic structure according to an embodiment of the present invention.

Referring to FIG. 1, a wooden house 10 having a seismic structure according to an embodiment of the present invention includes a wooden house 100, a support frame 200, an earthquake-proof part 500, and a base plate 600. Include.

The wooden house 100 is manufactured using wood, and is seated on the upper side of the support frame 200, and supports vibration or shock generated in a living space or vibration or shock transmitted from the ground. It is possible to have a seismic performance by reducing through 500 and the base plate 600.

The support frame 200 is installed on the lower side of the wooden house 100 to support the wooden house 100, and is mounted on the upper side of the earthquake-resistant part 500 to transmit vibration or impact from the wooden house 100. It is transmitted to the seismic unit 500.

Referring to FIG. 2, the support frame 200 includes a first horizontal bar 210, a second horizontal bar 220, and a plurality of vertical bars 230.

The first horizontal bar 210 is spaced apart from the second horizontal bar 220 by the vertical bar 230 and is installed in parallel, and a lower side of the wooden house 100 is seated.

The second horizontal bar 220 is spaced apart from the first horizontal bar 210 by the vertical bar 230 and is installed in parallel, and the other lower side of the wooden house 100 is seated.

The vertical bar 230 is installed along between the first horizontal bar 210 and the second horizontal bar 220.

The seismic unit 500 corresponds to a configuration that is installed on one side and the other side of the lower portion of the support frame 200 and absorbs vibration or shock transmitted through the support frame 200 to perform the seismic function of the present invention. .

Referring to FIG. 2, the seismic part 500 may include a seating frame 510 and a vibration absorbing part 300.

The seating frame 510 transmits vibration or shock to a plurality of vibration absorbing units 300 installed along the lower side or the other side of the support frame 200.

A plurality of vibration absorbing units 300 are installed along the lower side of the seating frame 510, and individually absorb vibrations or shocks transmitted from the support frame 200 through the seating frame 510 using elastic force, or Vibration or shock transmitted from the ground to the support frame 200 or may be individually absorbed.

The base plate 600 is installed on the ground surface, and the seismic part 500 is seated on one upper side and the other side.

In one embodiment, the base plate 600 has an upper groove 610 formed at each position where the vibration absorbing unit 300 is seated along the upper side so that the vibration absorbing unit 300 is seated to perform a stable seismic function. It would be desirable to be able to do it.

The wooden house 10 having a seismic structure having the configuration as described above is transmitted from the ground or from the wooden house itself by adding a seismic structure for absorbing vibration or shock to the lower side of the wooden house manufactured using wood. By efficiently absorbing the resulting vibration or shock, it is possible to exhibit excellent earthquake resistance while the construction is simple and the construction cost is low.

3 is a view showing the vibration absorbing unit of FIG. 2.

Referring to FIG. 3, the vibration absorbing unit 300 includes an upper pedestal 310, a support pillar 320, and a lower pedestal 330.

The upper pedestal 310 is connected to the upper side of the support pillar 320 and supports the lower side of the seating frame 510.

In one embodiment, the upper pedestal 310 is configured to support the lower side of the seating frame 510, and each support plate 311 (see FIG. 4) supporting the seating frame 510 is individually rotated or By supporting using an elastic force, even when the seating frame 510 is inclined to one side, it can be stably supported and effectively attenuated by vibration or shock transmitted from the seating frame 510.

In the support pillar 320, the upper pedestal 310 is connected to the upper portion and the lower pedestal 330 is connected to the lower portion, and the vibration transmitted through the upper pedestal 310 is attenuated using an elastic force.

The lower pedestal 330 is installed under the support pillar 320, forms a symmetrical structure with the upper pedestal 310, and is seated in an upper groove 610 formed on the upper portion of the base plate 600, so that the support pillar ( 320).

4 is a view showing the upper pedestal of FIG. 3.

Referring to FIG. 4, the upper pedestal 310 includes four support plates 311, four support bars 312, and four elastic bars 313.

The support plate 311 is formed in a flat plate shape to support the lower side of the seating frame 510, and the lower side is supported by the support bar 312 and the elastic bar 313.

The support bar 312 is connected and installed so that the upper part is rotatable at the lower side of the edge of the support plate 311 opposite to the edge of the other support plate 311 positioned in the diagonal direction, and the lower part of the support column 320 It is connected and installed so that it can be rotated at the top.

The elastic bar 313 is connected so that the upper part is rotatable at the lower side of the opposite edge of the corner where the support bar 312 is installed in the support plate 311, and the lower part is rotatable on the upper part of the support column 320 It is connected and installed, and supports the edge of the support plate 311 using an elastic force.

In one embodiment, the elastic bar 313 may include a first bar 3131, a second bar 3132, a case 3133, and an elastic body 3134.

The first bar 3131 is connected and installed so that the upper part is rotatable at the lower side of the edge opposite to the edge where the support bar 312 is installed in the support plate 311.

The second bar 3132 is connected and installed so that the lower part is rotatable below the position where the lower part of the support bar 312 is installed from the upper part of the support pillar 320.

In the case 3133, the lower portion of the first bar 3131 is inserted into the inner space and slidably moved, and the upper portion of the second bar 3132 is inserted into the inner space and slid.

The elastic body 3134 is installed between the lower side of the first bar 3131 and the upper side of the second bar 3132 in the inner space of the case 3133, and the lower side and the second bar 3132 of the first bar 3131 The upper side of it forms an elastic force in a direction away from each other.

The upper pedestal 310 having the configuration as described above is provided on the upper portion of the support pillar 320, that is, by the support bar 312 and the elastic bar 313 that are connected to be rotatably installed on the upper support portion 321. Using the supported support plate 311, the seating frame 510 can be efficiently supported even if it is inclined in any direction, as well as the vibration transmitted from the seating frame 510 using the elastic force of the elastic bar 313 It is possible to implement a structure that can effectively attenuate or impact.

5 to 7 are views showing the support pillar of FIG. 3.

Referring to FIG. 5, the support pillar 320 includes an upper support 321, a lower support 322, a pillar body 323, and an elastic body 324.

The upper support 321, each of the four support bars 312 in each of the individual grooves (325a, 325b, 325c, 325d) (see Fig. 6) of the fastening groove 325 in the form of "+" formed on the top It is connected and installed so that the lower part is rotatable, and connected to the upper part of the lower support 322.

The lower support 322 has a symmetrical structure with the upper support 321, and the lower support 330 is connected to and installed at the lower part, and is connected to the lower part of the pillar body 323.

That is, the lower support 322 is provided with a configuration such as the fastening groove 325 of the upper support 321 as a vertically symmetrical structure, but a description thereof will be omitted below in order to avoid overlapping descriptions.

As shown in FIG. 7, the column body 323 is inserted into an inner space 326 in which a lower portion of the upper support 321 is formed in a cylindrical shape and slides, and the upper portion of the lower support 322 is an inner space 326 ) And slides.

The elastic body 324 is installed between the upper support 321 and the lower support 322 in the inner space 326 of the column body 323 so that the lower side of the upper support 321 and the upper side of the lower support 322 It creates elastic force in the direction away from each other.

The support pillar 320 having the configuration as described above is installed between the upper pedestal 310 and the lower pedestal 330 and transmitted from the upper pedestal 310 or the lower pedestal 330 by using an elastic force. By absorbing the elastic bar 313, the stability of the device as a whole can be further improved by attenuating residual vibrations or shocks that are not absorbed even by primary vibration or shock absorption by the above-described elastic bar 313.

The wooden house 10 having a seismic structure according to the configuration as described above is installed along the spaced space between the seating frame 510 and the base plate 600 to prevent the seating frame 510 from sitting down. It may further include a frame support (400).

8 is a view showing a frame support according to the present invention.

Referring to FIG. 8, the frame support part 400 is installed along the spaced space between the seating frame 510 and the base plate 600 formed by the vibration absorbing part 300 so that the seating frame 510 sits down. Prevent it.

In this case, the height of the frame support part 400 may be freely adjusted in correspondence with the interval between the bar base plate 600 and the seating frame 510, which is adjusted in multiple steps, as described later.

In the wooden house 10 having a seismic structure having the configuration as described above, the seating frame 510 spaced upward from the base plate 600 by the vibration absorbing unit 300 sits down due to the separation space. It is to insert the frame support part 400 in the corresponding space to prevent it.

In one embodiment, the frame support 400 may include a base frame 410, an elastic support frame 420, and an auxiliary support frame 430.

The base frame 410 is formed in the shape of a square plate, is seated on the upper side of the base plate 600, and the elastic support frame 420 is connected and installed on the upper side.

The elastic support frame 420, the lower side is inserted and installed in the seating groove 411 formed on the upper side of the base frame 410, supports the seating frame 510 seated on the upper side using an elastic force, and assists the upper side. The support frame 430 is connected and installed so as to be rotatable.

The auxiliary support frame 430 is formed in the shape of a flat plate and is connected to the elastic support frame 420 so as to be rotatable, and the space between the seating frame 510 and the base plate 600 is formed only by the elastic support frame 420. If it is not supported, it stands upright to support the seating frame 510.

That is, when the frame support part 400 cannot fill the space between the seating frame 510 and the base plate 600 only by the height of the base frame 410 and the elastic support frame 420, as described later The auxiliary support frame 430 may be rotated up and down from the elastic support frame 420 to compensate for the insufficient height.

9 and 10 are views showing a connection relationship between the base frame of FIG. 8 and the elastic support frame.

9 and 10, the elastic support frame 420, at least one elastic body 421, the support plate 422, the frame body 423, the insertion protrusion 424, the receiving groove 425, the lower fastening It includes a groove 426 and an inclined fastening groove 427.

The elastic body 421 is installed in a seating groove 411 formed on the upper side of the base frame 410 corresponding to the shape of the insertion protrusion 424 to support the support plate 422.

The support plate 422 is formed in a flat plate having a shape corresponding to the shape of the seating groove 411, is inserted into the seating groove 411 and supported by the elastic body 421, and the insertion protrusion 424 is seated on the upper side. .

The frame body 423 is seated on the upper side of the support plate 422 by the insertion protrusion 424 formed at the lower side, and the receiving groove 425 is formed on the upper side.

The insertion protrusion 424 is formed protruding from the lower side of the frame body 423 corresponding to the shape of the seating groove 411, and is inserted into the seating groove 411 and supported by the support plate 422.

The receiving groove 425 is formed on the upper portion of the frame body 423 in a shape corresponding to the shape of the auxiliary support frame 430 to open to one side of the frame body 423, and the auxiliary support frame 430 in the inner space Is accepted.

The lower fastening grooves 426 are respectively formed at the lower portions of the walls on both sides of the entrance of the receiving groove 425 to fasten the lower fastening protrusions 432 to be described later.

The inclined fastening grooves 427 are formed so as to be inclined from the lower sides of both side walls of the receiving groove 425 to the upper side of the inlet of the receiving groove 425 to the upper side of the entrance of the receiving groove 425, respectively, the sliding protrusions 4335 of the rotation guide portion 433 to be described later ).

In one embodiment, the inclined fastening groove 427 has an upper end positioned at the entrance of the receiving groove 425 so as to prevent the sliding protrusion 4335 from being fastened and returning to the inside of the receiving groove 425 It may be formed to be bent (4271).

In one embodiment, the auxiliary support frame 430 includes a support body 431, a lower fastening protrusion 432, and a rotation guide portion 433.

The support body 431 is formed in a shape corresponding to the shape of the receiving groove 425 and is accommodated in the receiving groove 425, and the upper side is lifted from the receiving groove 425 using the lower fastening protrusion 432 as a rotation axis. It is raised.

The lower fastening protrusions 432 are protruding from both sides of the lower part of the support body 431 so as to be fastened to the lower fastening groove 426.

The rotation induction part 433 is formed on one or both sides of the lower part of the support body 431 so that it is fastened to the inclined fastening groove 427 and can be moved along the inclined fastening groove 427.

That is, the lower fastening protrusion 432 corresponds to the rotation axis of the support body 431, and the rotation guide portion 433 slides along the inclined fastening groove 427 as the support body 431 rotates and then inclines. It is fastened to the bent portion 4241 of the fastening groove 427 to perform a function of preventing the support body 431 from moving.

11 is a view showing the rotation induction part of FIG. 10.

Referring to Figure 11, the rotation guide portion 433, a sliding groove (4331), a sliding guide groove (4332), a moving part (4333), a separation preventing protrusion (4334), a sliding protrusion (4335) and an elastic support part (4336) Includes.

The sliding groove 4331 is formed in a vertical direction along one side of the support body 431 to form a space for the moving part 433 to move in the vertical direction, and sliding guide grooves 4332 are formed on both walls. Is formed.

The sliding guide groove 4332 is formed to extend in the vertical direction along the wall surfaces of both sides of the sliding groove 4331, and the separation preventing protrusion 4334 is fastened to form a space for moving in the vertical direction so that the moving part 433 slides. It prevents separation from the groove 4331.

The moving part 433 is inserted into the sliding groove 4331 and slides in the vertical direction, and separation preventing protrusions 4334 are formed on both sides thereof, respectively.

Separation preventing protrusions 4334 are formed to protrude on both sides of the moving part 433 so as to prevent the moving part 433 from being separated from the sliding groove 4331 and are fastened to the sliding guide groove 4332.

The sliding protrusion 4335 is formed to protrude from the front surface of the moving part 433 so that it can be moved along the inclined fastening groove 427.

The elastic support part 4336 is installed in the upper space and the lower space of the sliding guide groove 4332 to which the moving part 433 is fastened so that the moving part 433 can be supported by using an elastic force in the sliding guide groove 4332 do.

The rotation guide unit 433 having the configuration as described above can move the moving unit 433 in which the sliding protrusion 4335 is installed so that the sliding protrusion 4335 can be moved along the inclined fastening groove 427 By installing so as to be, the sliding protrusion 4335 may be moved elastically according to the rotation of the support body 431, and it may be automatically fastened to the bent portion 4231.

The above-described embodiments are for illustrative purposes only, and those of ordinary skill in the art to which the above-described embodiments belong can easily transform into other specific forms without changing the technical idea or essential features of the above-described embodiments. You can understand. Therefore, it should be understood that the above-described embodiments are illustrative and non-limiting in all respects. For example, each component described as a single type may be implemented in a distributed manner, and similarly, components described as being distributed may also be implemented in a combined form.

The scope to be protected through the present specification is indicated by the claims to be described later rather than the detailed description, and should be interpreted as including all changes or modified forms derived from the meaning and scope of the claims and the concept of equivalents thereof. .

10: wooden house with seismic structure
100: wooden house
200: support frame
300: vibration absorber
400: frame support
500: seismic resistance
600: base plate

Claims (13)

Wooden houses manufactured using wood;
A support frame installed below the wooden house to support the wooden house;
An earthquake-proof unit installed on one lower side and the other side of the support frame to absorb vibration or shock transmitted through the support frame; And
Includes; a base plate installed on the ground surface and on which the seismic part is seated on one side of the upper side and the other side,
The support frame,
A first horizontal bar on which one lower side of the wooden house is seated;
A second horizontal bar on which the other lower side of the wooden house is seated; And
Including; a plurality of vertical bars installed along the between the first horizontal bar and the second horizontal bar,
The seismic part,
A seating frame on which one lower side or the other side of the support frame is seated; And
A plurality of vibration absorbing units are installed along the lower side of the seating frame and individually absorbing vibrations or shocks transmitted through the seating frame using elastic force.
The vibration absorbing unit,
An upper support for supporting the lower side of the seating frame;
A support pillar having the upper pedestal installed on the upper portion thereof, and attenuating the vibration transmitted through the upper pedestal using an elastic force; And
Including; a lower pedestal installed below the supporting pillar and seated in an upper groove formed on the upper portion of the base plate to support the supporting pillar by forming a symmetrical structure with the upper pedestal,
The upper pedestal,
Four support plates formed in a flat plate shape to support the lower side of the seating frame;
Four support bars that are connected and installed so that the upper part is rotatable at the lower side of the edge of the support plate facing the edge of the other support plate located in the diagonal direction, and the lower part is connected to the upper part of the support column so as to be rotatable; And
The support plate is connected and installed so that the upper part is rotatable at the lower side of the opposite edge of the corner where the support bar is installed, the lower part is connected to the upper part of the support column, and the edge of the support plate uses elastic force. A wooden house having a seismic structure including;
delete delete delete delete The method of claim 1, wherein the elastic bar,
A first bar connected to and installed at a lower side of a corner opposite to the corner on which the support bar is installed in the support plate so that the upper part is rotatable;
A second bar connected to and installed at a lower portion of the support column so as to be rotatable below a position at which the lower portion of the support bar is installed;
A case in which a lower portion of the first bar is inserted into the inner space to slide and the upper portion of the second bar is inserted into the inner space to slide; And
An elastic body installed between the lower side of the first bar and the upper side of the second bar in the inner space of the case to form an elastic force in a direction in which the lower side of the first bar and the upper side of the second bar are separated from each other; , A wooden house with a seismic structure.
The method of claim 6, wherein the support pillar,
An upper support that is connected and installed so that the lower part of each of the four support bars is rotatable in each individual groove of the "+"-shaped fastening groove formed on the upper part;
A lower support having a symmetrical structure with the upper support, and having the lower support connected to the lower part;
A pillar body in which a lower portion of the upper support is slidably moved by being inserted into the inner space, and an upper portion of the lower support is inserted into the inner space to be slid; And
Containing, a seismic structure comprising an elastic body installed between the upper support and the lower support in the inner space of the pillar body to form an elastic force in a direction in which the lower side of the upper support and the upper side of the lower support are separated from each other. Wooden house.
The method of claim 1,
A frame support portion installed along a spaced space between the seating frame and the base plate to prevent the seating frame from collapsing; further includes,
The frame support,
A base frame formed in the shape of a square plate and seated on the upper side of the base plate;
An elastic support frame having a lower side inserted into the seating groove formed on the upper side of the base frame, and supporting the seating frame seated on the upper side using an elastic force; And
An auxiliary support frame that is formed in a flat plate shape and is connected to the elastic support frame so as to be rotatable, and supports the seating frame by standing upright when the spaced space between the seating frame and the base plate cannot be supported by only the elastic support frame; Including, a wooden house with a seismic structure.
delete The method of claim 8, wherein the elastic support frame,
At least one elastic body installed in the seating groove;
A support plate formed into a flat plate having a shape corresponding to the shape of the seating groove;
A frame main body seated on the upper side of the support plate;
An insertion protrusion protruding from the lower side of the frame body to correspond to the shape of the seating groove, and being inserted into the seating groove and supported by the support plate;
A receiving groove formed on an upper portion of the frame body in a shape corresponding to the shape of the auxiliary support frame to be opened to one side of the frame body;
Lower fastening grooves respectively formed under the walls of both sides of the entrance of the receiving groove; And
Including, a wooden house having a seismic structure, including; inclined fastening grooves each extending so as to be inclined to the upper side of the entrance of the receiving groove from the lower side walls of both sides of the receiving groove.
The method of claim 10, wherein the auxiliary support frame,
A support body formed in a shape corresponding to the shape of the receiving groove;
Lower fastening protrusions protruding from both lower sides of the support body so as to be fastened to the lower fastening groove; And
A wooden house having a seismic structure comprising; a rotation guide portion formed on one or both sides of the lower portion of the support body so as to be fastened to the inclined fastening groove to move along the inclined fastening groove.
delete delete

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