JP3019502U - House with earthquake-resistant evacuation room - Google Patents

Abstract

(57) [Summary] [Purpose] A house with an earthquake-resistant evacuation room that is easy to construct and does not require major remodeling of an existing house, yet is extremely safe against earthquakes, inexpensive, and has immediate effects. provide. [Structure] In a desired room of an existing building, an evacuation room B of a steel frame assembly structure having an opening communicating with an adjacent room is installed.
The evacuation room B includes a steel frame base 1 installed on the base floor of the room g to be installed, a plurality of steel frame columns 2 and 2'joined to at least a corner of the steel frame base 1, and a steel frame. Pillar 2,
Steel frame beam 3 connected to the upper end of 2 ', and steel frame base 1
And a plurality of steel frame wall panels 4 fixed between the steel columns 2, 2'and the steel beams 3.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a house with an earthquake-resistant evacuation room.

[0002]

[Prior art]

 Houses are important for living, sales and business, and are required to have high safety. From this point of view, building design standards have been established for the foundations, columns, beams, and wall opening areas, and construction is being carried out in accordance with these. However, if the house is a wooden house that has been deteriorated for a considerable number of years after construction, a beam, girder, column, etc. will be subjected to a load exceeding the seismic resistance when an earthquake with a large seismic intensity occurs. The strength members are damaged and destroyed, and at the same time, the roof acts as a heavy load. As a result, the entire building collapses, causing problems such as loss of human life due to this collapse, underlay of damaged members, furniture, and household goods, serious injury, and damage or loss of valuable items. . As a countermeasure to this, it is necessary to put a hand into the whole house and modify the foundation, beams, columns, etc. to a seismic resistant structure, or to construct a new seismic resistant structure, but all of these methods cost a lot of money. It took time and was poor in economic efficiency and immediate effect.

[0003]

[Problems to be solved by the device]

 The present invention was made by research to solve the above-mentioned problems, and the purpose thereof is that it can be easily installed without requiring major modification of existing houses. Yet, it is to provide a house with a seismic-resistant room that is extremely safe against earthquakes, inexpensive, and has immediate effects. In addition, the present invention is also safe when a heavy object such as a construction machine, a chimney, or an adjacent house is dropped or collapsed from above. In the present invention, the term "house" refers to a building in which a person is engaged in family life, sales, business, etc., such as a general house, a store, a sales office, a business office, a factory, or a combination of them with a general house. Including all. In addition, the house structure is particularly suitable in the case of wood, and also includes wood / steel frame and steel frame structures, including 2-story, 3-story, and single-story buildings.

[0004]

[Means for Solving the Problems]

 In order to achieve the above object, the present invention has a construction in which an evacuation chamber of a steel frame assembly structure having an opening communicating with an adjacent room is installed in a desired room of an existing building. The room to be installed is on the first floor of the existing building, and the evacuation room has a shape and size corresponding to the room to be installed and is installed on the base floor of the room. A plurality of steel frame columns connected to at least the corners, a steel frame beam connected to the upper end of the steel frame column, and a plurality of steel frame wall panels fixed between the steel frame base and the steel columns and the steel beam. have. The steel frame base is made by connecting one or more reinforcing girders to the frame-shaped frame and connecting them, and diagonal girders to the corner area. The steel frame wall panel is provided at a portion corresponding to the existing wall area other than the opening of the chamber to be installed, and is connected by bracing the frame frame, preferably with a finishing surface plate. It has a built structure. The steel beam will be located under the existing ceiling. The steel-framed beam is formed by connecting at least one reinforcing girder to and connecting to a frame-shaped frame, and preferably, the reinforcing girders are connected to and connected to the frame-shaped frame in a lattice shape. More preferably, a steel frame panel provided with braces on the frame is fixed to the reinforcing girder or the frame. A surface plate is stretched over the entire steel frame beam or the required area for finishing. A desired floor such as flooring, folding, etc. is provided on the steel frame foundation.

[0005]

[Action]

 According to the present invention, the evacuation chamber B, which is made up of a steel frame assembly structure having a space inside, is installed in the desired room g of the existing building A, so that the basic structure of the existing house A is not damaged and the appearance is not damaged at all. , A room can be made into a high-strength, strong and earthquake-resistant room. Therefore, if a large earthquake occurs, the columns, beams, walls, etc. of the existing building A will receive the seismic load as the first stage, and even if these collapse or collapse without being able to withstand the seismic load, the second stage Evacuation room B receives the earthquake load. Since the evacuation room B has a steel frame structure that is designed to be earthquake-resistant, it will not be collapsed or collapsed, and will surely stand on the base floor. Further, since the evacuation room B has an open structure that communicates with the adjacent rooms b and c, it is possible to immediately escape from the outside into the room in the event of an earthquake. Also, by storing important items such as valuables and evacuation supplies in this steel structure evacuation room B, it is possible to prevent damage or loss of those items during an earthquake. Moreover, since the structure of the existing building is used in a room of a fixed size and shape, and because it has a steel frame assembly structure, it can be easily installed indoors at low cost and in a short period of time.

The evacuation room B is located on the first floor of the existing building A, has a shape and size corresponding to the room g to be installed, and has a steel frame base 1 installed on the base floor h of the room g and the steel frame. A plurality of steel columns 2 and 2'connected to at least the corners of the base 1, a steel frame beam 3 connected to the upper ends of the steel columns 2 and 2 ', a steel frame base 1 and a steel column Since it has a plurality of steel frame wall panels 4 fixed between 2 and 2'and the steel beam 3, it is possible to enhance the seismic resistance effect, and in particular, the steel frame wall panel 4 is connected to the frame and brace. In the case of the above construction, seismic resistance can be further improved by arranging the steel frame wall panels 4 in a well-balanced manner. In addition to this, the steel frame beam 3 connects the frame-shaped frame 3a with the reinforcement girders 3b and 3b ', and also connects the steel framed panel 3c to the space between the frame-shaped frame 3a and the reinforcement girders 3b and 3b'. When the steel frame panel 3c is connected and fixed, especially when the frame frame 31 is braced over the brace 32, the horizontal brace effect allows sufficient surface rigidity to prevent a strong earthquake. In addition to high strength that can be endured, the existing ceiling j and the collapsing material on it can be reliably received, and it is possible to prevent the entry into the evacuation room, which can further enhance safety.

In addition, the steel frame base 1 is provided with a frame-shaped frame 1a, one or more reinforcing girders 1b and 1b ′ hung on the inside of the frame-shaped frame 1a, and diagonal girders connected to all or some corner areas. 1c, the frame-shaped frame 1a is composed of a plurality of beam members 10a, 10a, 100a, 100a and is assembled by using the connecting fittings 11 and the fasteners 12. On the other hand, the reinforcing girders 1b, 1b 'and the diagonal girders 1c are assembled by the connecting fittings 11 and the fasteners 12, and the frame-like frame 3a of the steel frame beam 3 is composed of a plurality of beam members 30a, 30a, 300a, 300a. Is installed using the connecting metal fittings 11 and the fasteners 12, and the reinforcing girders 3b and 3b 'are assembled to the frame-shaped frame 3a by the connecting metal fittings 11 and the fasteners 12. The steel frame base 1 and the steel frame beam 3 can be easily assembled in the room g, and the steel frame wall panel 4 and the steel frame panel 3c are mass-produced as independent parts in advance, and this can be installed in the room g. Walls and ceilings can be easily formed by loading. Therefore, a highly earthquake-resistant evacuation room can be obtained within a short period of time without requiring skill.

[0008]

【Example】

 1 to 4 show an embodiment in which a house with an earthquake-resistant evacuation room according to the present invention is applied to a wooden house for general houses. A is an existing house, which has a entrance a, a Japanese-style room b, a kitchen c, a toilet d, and a bathroom e on the first floor, and a plurality of rooms f such as a children's room on the second floor. B is an evacuation room according to the present invention, which is installed in at least one room g on the first floor. The room g is preferably a room that communicates with other rooms b and c, a corridor m, or the like at a plurality of places either directly or through opening / closing doors. Although it may be a bedroom or the like depending on the position and purpose of use in the building, a room in which residents easily gather, such as a living room or a tea room, is generally preferable.

The evacuation chamber B has, as a basic structure, a steel frame base 1 installed on a base floor h in a room g to be installed, and a plurality of steel frame bases 1 connected to at least a corner portion of the steel frame base 1. Steel columns 2, 2 ', a steel frame beam 3 connected to the upper ends of the steel columns 2, 2', and at least one piece fixed between the steel frame base 1 and the steel column 2 and the steel beam 3 Steel frame wall panel 4. The evacuation room B has a flat area in accordance with the size of the room g to be installed (for example, 3 tatami mat, 4.5 tatami mat, 6 tatami mat, 8 tatami mat, etc.).

Details of an example of the evacuation chamber B are shown in FIGS. 4 to 12. First, as shown in FIG. 4 and FIG. 5, the steel frame base 1 has a frame-shaped frame 1a and one or more reinforcing girders 1b and 1b 'which are bridged and connected to the inside of the frame-shaped frame 1a. Then, preferably, diagonal girders 1c are further bridged and connected to all or part of the corner areas. The frame-shaped frame 1a has a contour shape conforming to the chamber g to be installed, and has an outer dimension that is equal to or appropriately small as the effective inner dimension of the installation chamber g. In this embodiment, the frame-shaped frame 1a has a rectangular shape when seen in a plan view. The frame-shaped frame 1a is directly installed on the base floor h made of soil or poured concrete in the room g to be installed, or on the base floor h as shown in FIGS. At least the corners are supported by a flat plate 5 made of concrete or having a seismic isolation function.

The frame-shaped frame 1a comprises two sets of beam members 10a, 10 made of lightweight shaped steel such as channel steel, C-shaped steel or square steel (having a rectangular closed cross section). It is assembled by arranging a, 100a and 100a in parallel and tightening the contact parts with the connecting fitting 11 and the fastener 12. In this embodiment, the reinforcing girder 1b is composed of three long bars and the reinforcing girder 1b 'is composed of four short bars. Each of the reinforcing girders 1b and 1b 'is made of lightweight shaped steel, for example, channel steel, C-shaped steel or square steel, and the three reinforcing girders 1b are the long beam members 10a and 10a, as shown in FIG. 5 (b). 10a are equally spaced, and four short reinforcing girders 1b 'are arranged between the beam member 100a and the reinforcing girders 1b. It is assembled by doing.

The connecting fitting 11 is made of an angle member, for example, as shown in FIG. 10. The angle member is preferably attached to one side surface of the beam member 10a, 10a, 100a, 100a by welding or the like, and is provided on the remaining one side surface. The bolt holes are aligned with the bolt holes previously formed in the beam members 10a, 10a, 100a, 100a and the reinforcing girders 1b, 1b ', and the nuts are screwed through the bolts as the fasteners 12 to join them. When the reinforcing girders 1b and 1b 'are made of square steel, a steel plate is used as the connecting fitting 11, and this is welded to the end portions of the reinforcing girders 1b and 1b', and the right and left projections of the plate are extended. The portion may be brought into contact with the beam members 10a, 10a, 100a, 100a or the reinforcing girder 1b of the connection partner, and the nut may be screwed and tightened by inserting a bolt from the plate into the connection partner. Each of the diagonal girders 1c is made of lightweight steel such as channel steel, C-shape steel or square steel. Both ends of the diagonal girders are secured to the beam members 10a, 10a, 100a and 100a with the connecting metal fittings 11 and the bolts and nuts as the fasteners 12. It is assembled by doing.

Next, the steel columns 2 and 2 ′ are each made of lightweight shaped steel, for example, square steel, and the steel columns 2 are erected at the corners of the frame-like frame 1 a. Further, the steel frame columns 2 ′ are erected to support one side of the steel frame wall panel 4 in a frame-shaped frame portion having the steel frame wall panel 4. The corners of the steel columns 2 and 2 are integrally provided with base metal members 20a and 20b having a similar shape to the plane triangle at the top and bottom, respectively, by welding or the like, and bolt holes are arranged in the base metal members 20a and 20b, respectively. It is set up. The base metal fitting 20a at the bottom is installed so as to straddle the beam members 10a and 100a as shown in FIG. 10, and the bolts as the fasteners 12 are inserted through the bolt holes previously provided in the beam members 10a and 100a. By being screwed and tightened, it is firmly connected to the frame-shaped frame 1a. Similarly, the intermediate steel column 2 ′ is also integrally provided with planar rectangular base metal fittings 20a and 20b having bolt holes at the top and bottom, respectively, by welding or the like, and the base metal fitting 20a at the bottom is formed of the beam member 10a or 100a. It is firmly connected to the frame-shaped frame 1a by installing a bolt as a fastener 12 through a bolt hole provided on the beam members 10a and 100a in advance and screwing and tightening a nut. .

The steel frame girder 3 is connected to the steel columns 2 and 2 ′, and as shown in FIGS. 1, 2, 4 and the like, is in contact with the existing ceiling j of the room g to be installed or has a slight gap therebetween. It is located so that it can be held. The steel-framed beam 3 has the same structure as the steel-framed foundation 1, that is, at least one frame-shaped frame 3a and at least one reinforcing girder 3b, 3b 'that is connected to the inside of the frame-shaped frame 3a. Have Preferably, the steel frame panel 3c is further fixed to the space formed by the frame-shaped frame 3a and the reinforcing girders 3b and 3b '. The frame-shaped frame 3a has a contour shape conforming to the chamber g to be installed, and has an outer dimension equal to or reasonably small as the effective inner dimension of the installation chamber g. In this embodiment, the frame-shaped frame 3a has a rectangular shape when seen in a plan view.

The frame-shaped frame 3a is similar to the frame-shaped frame 1a of the steel-framed base 1, and two sets of beam members 30a each of which are made of light-weight section steel, for example, channel steel, C-section steel or square steel. , 30a, 300a, 300a are arranged in parallel, and as shown in FIG. 11, they are assembled by tightening the contact parts with the connecting fitting 11 and the fastener 12. For the details, the description of the frame-shaped frame 1a is cited. The reinforcing girders 3b and 3b 'may be a plurality of parallel reinforcing girders, but are preferably formed in a lattice shape as shown in FIG. In this embodiment, the reinforcing girder 3b is composed of three long bars, and the reinforcing girder 3b 'is composed of eight short bars. Each of the reinforcing girders 3b and 3b 'is made of lightweight shaped steel, for example, square steel, and the three reinforcing girders 3b are equally spaced between the long beam members 30a and 30a as shown in FIG. The short reinforcing girders 3b ′ are arranged between the beam member 300a and the reinforcing girders 3b and between the reinforcing girders 3b 1 and 3b, and by tightening with the connecting fitting 11 and the fastener 12 respectively as shown in FIGS. 7 and 11. It is assembled in a grid pattern. In this example, since the reinforcing girders 3b and 3b 'are made of square steel, a plate made of steel is used as the connecting fitting 11, and these plates are welded to both ends of the reinforcing girders 3b and 3b', and the plates are projected to the left and right. The portion is brought into contact with the beam members 30a, 30a, 300a, 300a or the reinforcing girder 3b of the coupling partner, and the bolt as the fastener 12 is inserted from the plate to the coupling partner and the nut is screwed and tightened. As shown in FIG. 11 etc., the above-mentioned steel-framed beam 3 is placed on each top base metal fitting 20b of the steel-column 2, 2 ', and is used as a fastener 12 in a bolt hole previously provided in those beam members 30a, 300a. By tightening the nuts through the bolts and tightening the nuts, the steel columns 2 and 2'are firmly coupled and integrated.

The above-described steel frame panel 3c cooperates with the frame-shaped frame 3a and the reinforcing girders 3b and 3b 'in the event of an earthquake to support the load applied from above and prevent distortion, and the existing ceiling j A function to prevent the ceiling debris and the structures on it from collapsing and falling into the space with the steel frame base 1 (more precisely, the floor described below), that is, the evacuation room Exert. As shown in FIGS. 7 and 11, the steel frame panel 3c preferably includes a frame frame 31 formed by welding lightweight angle steel and the like, and a brace 32 including a flat bar and the like crossed over the frame frame 31. Further includes a surface plate 33 stretched via a talc attached to the frame 31 and is connected and fixed to the reinforcing girders 3b and 3b 'and the beam members 30a and 300a. The frame frame 31 of the steel frame panel 3c is provided with a bolt hole at a required position, for example, an intermediate position of each side, and the reinforcing girders 3b and 3b 'and the beam members 30a and 300a corresponding to the bolt holes are connected with a metal fitting. 13 is attached, the frame 31 is placed on it, and is fastened by fasteners 12 such as bolts and nuts. The connecting fitting 13 is made of, for example, an angle member, half of which is preliminarily welded to the reinforcing girders 3b, 3b 'and the beam members 30a, 300a, and a bolt hole is provided in the half of which is horizontally projected. The steel frame panel 3c is fixed by receiving the frame frame 31 in this half portion, aligning both bolt holes, inserting a bolt, and screwing and tightening a nut. The surface plate 33 is made of, for example, a fire-resistant or flame-retardant structural plywood such as a gypsum board to which a thin layer finishing material such as paper or cloth is attached, and the surface plate 33 is provided on the steel frame panel 3c in advance. It may be provided, or may be provided after connecting and fixing the steel frame panel 3c to the reinforcing girders 3b, 3b 'and the beam members 30a, 300a.

It should be noted that the steel frame panel 3c may or may not be provided entirely in the space formed by the frame-shaped frame 3a of the steel frame beam 3 and the reinforcing girders 3b, 3b '. For example, in order to expose the fluorescent lamps directly attached to the existing ceiling j, expose the cooling and heating equipment, or insert the cords or the hangings of the hanging type lighting equipment, the steel frame panel 3c is partially attached. You may make the area which is not provided. When the space between the reinforcing girders 3b, 3b 'is narrow, the steel frame panel 3c is completely abolished, and the surface plate 33 is stretched directly on the upper surface or the lower surface of the steel frame beam 3 through a wooden member or the like. Good.

It is preferable that one or more steel frame wall panels 4 are provided on each side of the steel frame base 1 and the steel frame beam 3. More preferably, it is provided in a region other than the adjacent chambers b and c of the chamber g to be installed, the passage opening k with the corridor m, and the opening k'opening to the outside of the building such as a window. Therefore, the evacuation room B has an open structure in which a plurality of places are open. In this embodiment, the steel frame wall panel 4 is provided in an L-shape in a pair of diagonal areas as shown in FIG. Further, in this embodiment, the steel frame wall panel 4 is composed of two upper and lower parts for facilitating loading into the chamber g as shown in FIGS. 8 to 10. Then, half of the connecting fittings 14 made of an angle member or the like is fixed by welding or the like to the middle portion in the height direction between the steel columns 2 and 2 ', and these connecting fittings 14 and 14 are made of lightweight channel steel. A horizontal crosspiece 4a made of a throat is passed and fastened and fixed by a fastener 12 such as a bolt and nut.

As shown in FIGS. 8 to 10, each of the upper and lower steel frame wall panels 4 is composed of a frame frame 41 formed by welding lightweight angle steel and the like, and a flat bar or the like crossed over the frame frame 41. And a brace 42, and preferably, a surface plate 43 is provided through a wooden board 44 attached to the frame 41. The surface plate 43 has the same structure as that of the steel frame panel 3c, and may be stretched in advance on the frame frame 41. The steel frame wall panel 4 may be attached to the steel frame base 1 and the steel columns 2, 2 '. Alternatively, it may be stretched after being assembled and fixed to the cross rail 4a and the steel frame beam 3. Further, the frame frame 41 of the steel frame wall panel 4 is provided with a plurality of bolt holes at required positions, for example, two at four sides, and the corresponding frame-shaped frame 1a of the steel frame base 1 is provided. The steel frame columns 2 and 2'and the frame-like frame 3a of the horizontal rail 4a and the steel frame beam 3 are welded to each other by a half of a connecting tool 14 made of an angle member as shown in FIG. It is fixed. Corresponding bolt holes are provided in the protruding half of the connecting fittings 14, and the bolt holes of the frame 41 of the steel frame wall panel 4 are aligned with these, and the fasteners 12 such as bolt nuts are used. By fastening, the steel frame wall panel 4 is rigidly connected to the steel frame base 1, the steel columns 2 and 2 ′, the cross rail 4 a and the steel frame beam 3.

In FIGS. 1 and 2, reference numeral 6 denotes a floor stretched above the steel frame base 1. As shown in FIG. 12, the floor 6 may be any flooring, tatami mat, or the like, and is stretched so as not to have a step difference with the floors of the adjacent rooms b and c. In the case of flooring, a plurality of large pulls 6b are arranged and fixed on a plurality of abutments 6a which are fixed on the frame-shaped frame 1a of the steel frame base 1 and the reinforcing girders 1b at intervals, and then the large pulls 6b are fixed. A tar tree 6c is fixed to and supported by a wooden floor, and an optional finishing material 6d such as plywood is stretched on it. In the case of a tatami mat, a tatami mat 6d 'as a finishing material is arranged on the tall tree 6c.

The present invention can take various modes and is not limited to the above-mentioned embodiments. For example, the steel frame base 1 is not limited to the one shown in FIG. 5, but may be one in which one or more reinforcing girders 1b are simply laid over the frame-shaped frame 1a and rigidly connected. As shown, one or more reinforcing girders 1b may be simply bridged over the frame-shaped frame 1a to be rigidly connected, and diagonal girders 1c may be bridged over each corner area.

Further, the number of the steel frame wall panels 4 may be one as shown in FIG. 14 instead of the upper and lower two. In this case, the upper and lower sides of the frame 41 are connected and fixed to the steel-frame base 1 and the steel-frame beam 3 by the connecting metal fittings 14 and 14 and the fasteners 12 as in the embodiment of FIGS. The left and right sides are connected and fixed to the steel columns 2 and 2 ′ by the connecting fittings 14 and the fasteners 12 at a plurality of places.

[0023]

[Operation of the embodiment]

 In obtaining the evacuation room B shown in the embodiment, first, the floor of the room g to be installed is removed, and the flat plates 5 are arranged on at least four corners on the base floor h. Then, the steel frame base 1 is installed on the flat plate 5. This may be carried in by carrying the steel frame base 1 assembled beforehand beforehand into the chamber g in which it should be installed, or by carrying only the frame-shaped frame 1a outside and carrying it into the chamber g in which it should be installed, and the reinforcing girder 1b. , 1b 'and the diagonal girder 1c may be carried in separately and assembled and connected to the frame-like frame 1a. Alternatively, the beam members 10a, 10a, 100a, 100a may be carried into the chamber g in which they are to be installed and then assembled and connected as the frame-shaped frame 1a. The connecting work can be easily performed by operating the fastener 12 with a tool as described above.

Next, the steel columns 2 and 2 ′ are loaded into the chamber g where they are to be installed, the steel columns 2 and 2 ′ are placed on the frame-shaped frame 1 a of the steel frame base 1, and the base metal fitting 20 a at the lower end is placed. , 20a and the fastener 12 are rigidly connected to the frame-like frame 1a. Then, the steel frame beams 3 are arranged on the steel columns 2 and 2'and rigidly connected. This may be performed by previously assembling and connecting the entire steel frame beam 3 to the outside, carrying it in the chamber g in which it should be installed, and lifting up. Alternatively, only the frame-shaped frame 3a of the steel frame beam 3 is externally assembled and carried in, placed on the steel frame columns 2 and 2 ', and coupled with the base metal fitting 20b of the steel frame columns 2 and 2'by the fasteners 12, The reinforcing girders 3b and 3b 'and the steel frame panel 3c are separately carried in, the reinforcing girders 3b and 3b' are connected and integrated with the frame-shaped frame 3a by the connecting metal fittings 13 and the fasteners 12, and the frame-shaped frame 3a is reinforced with the reinforcing girder 3b. , 3b ′ may be fitted with the steel frame panel 3c to be connected and fixed. Further, the frame-shaped frame 3a is disassembled into the beam members 30a, 30a, 300a, 300a constituting the frame-shaped frame 3a, carried into the chamber g to be installed, placed on the steel columns 2 and 2 ', and fastened. It is also possible to connect the steel columns 2 and 2 ′ with the tool 12 and configure the frame-shaped frame 3 a, and then arrange each of the steel frame panels 3 c in a required space and connect and fix them with the fastener 12.

The steel-framed wall panel 4 is preferably loaded at the end so as to have a sufficient working space, and the frame-shaped frame 1a of the steel-framed base 1, the steel-framed columns 2 and 2 ′, the horizontal rails 4a and the steel-framed frame It is connected and fixed to the frame-shaped frame 3 a of the beam assembly 3 by a fastener 12. Through the above steps, the evacuation room B of the present invention is completed. This evacuation room B has a steel frame base 1, steel frame columns 2 and 2 ', and a steel frame beam 3, and a steel frame wall panel 4 is connected between the steel frame columns 2 and 2', and the steel frame wall panel 4 is connected. Is extremely sturdy because it has a brace 42 provided on the frame 41. Moreover, the steel-framed beam 3 also has a plurality of steel-framed panels 3c, which are provided with the braces 32 horizontally in the frame 31 and have high surface rigidity. Therefore, the function of preventing distortion and supporting the fall of the existing ceiling j or a structure above it is sufficiently fulfilled. Therefore, even in an aged building, only the room g where the evacuation room B is located has extremely high seismic resistance, all other rooms collapsed or damaged, and the structure directly above the second floor collapsed. 3 and a plurality of steel frame panels 3c prevent entry into the evacuation room B and are safe. Moreover, unlike the capsule, which has only one entrance and exit like the capsule, the evacuation chamber B has a plurality of openings k leading to the adjacent chambers b and c and the corridor m. Therefore, when an earthquake occurs, you can immediately escape to the evacuation structure even if you are in another room. Also, if valuables, emergency disaster prevention supplies, preserved food, etc. are placed in the evacuation room B, or if they are placed in the space between the floor 6 and the steel frame base 1, damage and loss will be prevented reliably. can do.

Even if the house is collapsed or collapsed due to an earthquake, the evacuation chamber B remains, and the evacuation chamber B includes the steel frame base 1, the steel columns 2, 2 ′, the steel frame beams 3, and a plurality of surrounding places. The steel frame wall panel 4 forms a box-shaped skeletal structure, the floor 6 is at the bottom, and the steel frame beam 3 has a steel frame panel 3c with horizontal braces as a ceiling. Therefore, by appropriately extending the steel-framed wall panel 4 and adding sheets and the like, it is possible to live a present life as a simple house that can endure aftershocks.

[0027]

[Effect of device]

 According to claim 1 of the present invention described above, since the evacuation chamber B of the steel frame assembly structure having the openings k and k ′ communicating with the adjacent chambers b and c is installed in the desired room g of the existing building A, When an earthquake occurs, you can easily enter the room from other rooms or corridors, and you can avoid the fact that even if the house collapses or is damaged due to the earthquake, it will become the underlay of the building materials. Also, because it is installed entirely in the existing room, it is easier, faster, and more economical than modifying the entire building into a seismic-resistant structure with reinforcements, etc., and the evacuation structure is a steel frame assembly type. Since the members can be brought into the room and assembled there, the excellent effect that the existing room can be easily installed in a short period without being destroyed is obtained. According to claim 2, the evacuation room B has a shape and dimensions corresponding to the room g to be installed on the first floor of the existing building A, and the steel frame base 1 installed on the base floor of the room, and the steel frame A plurality of steel frame columns 2 and 2 ′ that are connected to at least the corners of the assembly base 1, a steel frame beam 3 that is connected to the upper ends of the steel frame columns 2 and 2 ′, a steel frame base 1 and a steel frame column 2 and 2'and a plurality of steel frame wall panels 4 fixed between the steel beam 3 and the steel frame wall panel 4 enhances the seismic resistance effect, so that the construction is easy and it is possible to use the adjacent room. Seismic resistance can be made extremely high even if there are multiple openings to communicate with each other.In addition, unlike a capsule with a narrow ceiling, the indoor effective area is large and the effective height is high, which makes living easier. Also, because the surrounding area is not covered with walls, cooling and heating can be maintained. Excellent effect that can be utilized to obtain. According to claim 3, the steel frame beam 3 is constructed by bridging the reinforcing girder 3b on the frame-shaped frame 3a, and further connecting and fixing the steel frame panel 3c in the space between the frame-shaped frame 3a and the reinforcing girder 3b. Therefore, when the existing ceiling and the structure above it are damaged by an earthquake, it is possible to reliably prevent the entry and drop into the space inside the evacuation room. According to the fourth aspect, since the steel frame panel 3c has a structure in which the braces are bridged over the frame frame 31, it is possible to ensure sufficient surface rigidity by the horizontal brace effect in addition to the effect of the third aspect. As a result, it is possible to increase seismic resistance and to reliably catch damage to the existing ceiling, damage to it, and falling collapsed structures. Furthermore, since the steel frame panel 3c is a member independent of the steel frame beam 3, it is possible to carry in the required number and easily construct it indoors. Also, install the steel frame panel 3c outside the required range. Since it can be omitted, it has an excellent effect such that the illumination light from the lighting equipment installed on the existing ceiling j can be sufficiently taken into the evacuation room B, and the hanging lighting equipment can be freely installed into the evacuation room B. can get. According to claim 5, since the steel frame wall panel 4 is configured by bridging and connecting the brace 42 to the frame frame 41, the seismic resistance can be further increased, and the steel frame base 1, the steel frame Since it is a member independent of the pillars 2 and 2'and the steel frame beam 3, it can be easily carried in indoors by bringing in the required number, and it should be installed in a position that conforms to the opening conditions of the existing room g. It has an excellent effect that it can be installed in a well-balanced manner. According to claim 6, the steel-frame base 1 and the steel-frame beam 3 are composed of a plurality of beam members and girder members, which are assembled by the connecting fittings 11 and the fasteners 12. The excellent effect is that it can be assembled easily and quickly indoors.

[Brief description of drawings]

FIG. 1 is a vertical side view showing an example of a house with an earthquake-resistant evacuation room according to the present invention.

FIG. 2 is a vertical sectional front view showing an example of a house with an earthquake-resistant evacuation room according to the present invention.

FIG. 3 is a sectional view taken along line XX of FIG.

FIG. 4 is a partially cutaway front view of a house with an earthquake-resistant evacuation room according to the present invention.

5 (a) is a plan view of the steel frame base 1, and FIG. 5 (b) is FIG. 1Y-Y.
It is sectional drawing which follows the line.

6 is a cross-sectional view taken along the line ZZ in FIG.

FIG. 7 is a partially enlarged view of FIG.

FIG. 8 is an enlarged view of a steel frame wall panel portion in the present invention.

FIG. 9 is a partial cross-sectional view showing the connection between the steel frame wall panel and the steel frame beam.

FIG. 10 is a partial perspective view showing an arrangement of a steel frame base, a steel frame column and a steel frame wall panel according to the present invention.

FIG. 11 is a partial perspective view showing the connection between a steel frame column, a steel frame wall panel and a steel frame beam according to the present invention.

FIG. 12 is a partial cross-sectional view showing the combination of the steel frame foundation and the floor according to the present invention in a flooring type and a tatami type.

FIG. 13 is a plan view showing another example of the steel frame base in the present invention.

FIG. 14 is a front view showing another example of the steel frame wall panel according to the present invention.

[Explanation of symbols]

 A Existing building B Evacuation room b, c room g Room to be installed h Base floor 1 Steel frame base 1a Frame frame 1b, 1b 'Reinforcing girder 1c Diagonal girder 2, 2'Steel column 3 Steel frame beam 3a Frame frame 3b , 3b 'Reinforcement girder 3c Steel frame panel 4 Steel frame wall panel 10a, 30a, 100a, 300a Beam member 11 Connecting fitting 12 Fastener 31,41 Frame frame 32,42 Brace

Claims (6)

[Scope of utility model registration request] 1. An evacuation room B of a steel frame assembly structure having openings k, k'that communicate with adjacent rooms in a desired room g of an existing building A.
A house with an earthquake-resistant evacuation room, which is characterized by the installation of 2. The room g to be installed is on the first floor of the existing building A, and the evacuation room B has a shape and size corresponding to the room g to be installed and is installed on the base floor h of the room g. Steel frame base 1
And a plurality of steel frame columns 2 and 2'coupled to at least the corners of the steel frame platform 1, a steel frame beam 3 coupled to the upper ends of the steel frame columns 2 and 2 ', and a steel frame platform 1 And steel columns 2,
The house with an earthquake-resistant evacuation room according to claim 1, comprising a plurality of steel frame wall panels 4 fixed between 2'and the steel beam 3. 3. A steel frame base on which the room g to be installed is on the first floor of the existing building A and the evacuation room B has a shape and size corresponding to the room g to be installed and is installed on the base floor of the room. 1, a plurality of steel frame columns 2 and 2'coupled to at least the corners of the steel frame platform 1, a steel frame beam 3 coupled to the upper ends of the steel frame columns 2 and 2, and a steel frame platform 1, a plurality of steel-framed wall panels 4 fixed between the steel-framed columns 2 and 2 ′ and the steel-framed beam 3, and the steel-framed beam 3 is provided on the frame-shaped frame 3 a with the reinforcing girders 3.
b and 3b 'are bridged and connected, and the steel frame panel 3c is provided in the space between the frame 3a and the reinforcing girders 3b and 3b'.
The house with an earthquake-resistant evacuation room according to claim 1, wherein the house is connected and fixed. 4. The house with an earthquake-resistant evacuation room according to claim 3, wherein the steel frame panel 3c is constructed by bridging and connecting the braces 32 to the frame 31. 5. The house with an earthquake-resistant evacuation room according to claim 2 or 3, wherein the steel frame wall panel 4 is constructed by bridging and connecting a brace 42 to the frame 41. 6. A frame-shaped frame 1a, one or more reinforcing girders 1b, 1b 'hung on the inside of the frame-shaped frame 1a, and an oblique girder bridged and connected to all or some corner areas. 1 c, the frame-shaped frame 1 a has a plurality of beam members 10
a, 10a, 100a, 100a, which are assembled by using the connecting fitting 11 and the fastener 12, and the reinforcing girders 1b and 1b 'and the diagonal girder 1c are connected to the frame-shaped frame 1a by the connecting fitting 11 and the fastener 12. The frame-shaped frame 3a of the steel-framed beam 3 is assembled by using the plurality of beam members 30a, 30a, 300a, 300a by using the connecting fittings 11 and the fasteners 12, and the reinforcing frame is attached to the frame-shaped frame 3a. The house with an earthquake-resistant evacuation room according to claim 2 or 3, wherein 3b and 3b 'are assembled by a connecting fitting 11 and a fastener 12.