KR20230072188A - Framework structure for prefabricated house - Google Patents

Abstract

A modular framework structure for a prefabricated house according to the present invention comprises a connector (100), which has a junction part (102a) and an extension part (102b) protruding in three to six directions from the junction part (102a) and is coupled to a beam (200) and a column (300) through the extension part (102b). The connector (100) comprises: a connector housing (102) forming the junction part (102a) and the extension part (102b); an internal insulation material (101) filled in the junction part (102a); and an external insulation cap (103) enclosing the junction part (102a). The extension part (102b) is hollow and is inserted into the beam (200) and the column (300). Therefore, the modular framework structure facilitates non-professionals in house design and allows simulation of the final confirmed house structure.

Description

Frame structure for prefabricated houses {FRAMEWORK STRUCTURE FOR PREFABRICATED HOUSE}

The present invention relates to the field of construction, and more particularly to frame structures for prefabricated houses.

In general, the construction of a new house takes at least three months, and goes through the construction process from start of construction, foundation work, column or wall formation, roof work, interior and exterior, windows, auxiliary facilities, and other construction processes. Each of these construction processes has a problem in that the construction of the house is prolonged and the work is advanced, the risk of safety accidents increases accordingly, and the construction cost increases due to the employment of professionals who have been skilled for a long time.

Recently, a prefabricated house technology for constructing a house by simply assembling using prefabricated panels has been developed and is widely used.

Such technologies related to prefabricated houses have been proposed in Korean Patent Publication No. 2018-0009254 and Korean Patent Registration No. 1753881.

Patent Document 1 discloses a method for constructing a prefabricated country house by assembling ready-made materials such as C-beams and square tubes through a simple assembly method and a prefabricated country house constructed by this method.

Patent Document 2 enables direct heat transfer to the interior of the house through the wall without installing pipes on the wall, and while the thermal energy supplied from the heat source moves through the base frame, wall panel and ceiling panel, the interior space of the house from various directions. It is delivered to, and a prefabricated house is disclosed that is provided in a prefabricated manner and does not install piping on the wall.

However, Patent Documents 1 and 2 have a problem in that the prefabricated house is manufactured as a whole and then installed on the site, so the bulk is difficult to transport and the transport cost is increased.

In addition, other conventional prefabricated houses are reinforced by bonding a frame such as a pipe to the inner wall surface of a metal plate material by welding, etc., but since the inner frame must be reinforced, material costs are increased, and the outer wall surface is easily deformed by welding However, since it is manufactured in a monotonous form, it is vulnerable to earthquakes or typhoons, and it is difficult to transport to the site.

The present invention provides a frame structure for a prefabricated house for easy house design.

In the frame structure for a prefabricated house, a connecting member 100 composed of an intersection portion 102a and extension portions 102b protruding in three to six directions from the intersection portion 102a is connected to a beam 200 through the extension portion 102b. ) and fastened with the pillar 300.

The connecting member 100 includes a connecting member housing 102 forming the crossing portion 102a and the extension portion 102b, an internal insulation material 101 filled in the crossing portion 102a, and the crossing portion 102a. It includes an outer insulation cap 103 surrounding, and the extension 102b is inserted into the beam 200 and the pillar 300 as a hollow one.

The beams 200 and the pillars 300 surround the lightweight steel pipe 203 filled with the inner insulation material 201, the core material 202 introduced into the pipe 203, and the outside of the pipe 203. Insulation 204 is included.

On the outer surfaces of the beams 200 and the columns 300, a pattern consisting of ridges 211 and ridges 212 in the longitudinal direction is formed.

In one aspect, the connectors, beams, and columns may be rectangular pipe shapes.

In another aspect, a through hole for penetrating the coupling member may be formed at the end of the extension part of the connecting member and the column or beam.

In another aspect, an adhesive may be applied to an extension of the connection member to fasten the connection member and the column or beam.

In another aspect, the adhesive may be an epoxy resin.

In another aspect, a frame structure for a prefabricated house, characterized in that a two-sided spacer is bonded to some or all of the lateral or straight edges of the extension. can be

In another aspect, the cross section of the groove may be square, rectangular, triangular, semicircular, or semielliptical.

In another aspect, the depth of the furrow may be 0.1 to 20 mm, 1 to 10 mm, or 2 to 5 mm.

In another aspect, the furrows may be formed in 1 to 5, 1 to 4, or 1 to 3 furrows per side in the square pipe-type beams and columns.

In another aspect, the heat-resistant material may be a urethane foam.

In another aspect, the outer insulation material may be neoprene.

In another aspect, the outer insulation cap may be a three-sided cap or a two-sided cap.

In another aspect, the pillar or beam may be manufactured by integrally extruding the core material, the heat insulating material, and the pipe.

In another aspect, the pillar or beam may be manufactured by integrally extruding the core material, the inner insulation material, the pipe, and the outer insulation material.

In another aspect, the outer insulation material surrounding the pillar or beam may be sealed with a zipper after wrapping the pillar or beam.

In another aspect, in the frame structure, the distance between the column or beam and the connecting member extension may be 0.2 to 5 mm, 0.5 to 4 mm, or 1 to 2.6 mm.

In another aspect, the pipe may have a square or rectangular cross-section with a side of 80 to 130 mm, 85 to 120 mm, or 90 to 110 mm.

In another aspect, the cross section of the connecting member extension may be a square or rectangular shape having one side of 70 to 120 mm, 75 to 110 mm, or 80 to 100 mm.

In another aspect, the thickness of the connector housing and the pipe may be 2.5 to 3.8 T, 2.8 to 3.6 T, or 3 to 3.4 T.

In another aspect, the core material may be a material for lightweight steel or plastic.

According to the present invention, it is possible to provide a frame structure for a prefabricated house that makes it easier for non-specialists to design a house and simulates the final confirmed house structure.

1 is a view showing a frame structure for a prefabricated house according to an embodiment of the present invention.
2 is a block diagram showing the detailed configuration of a housing structure generating unit according to an embodiment of the present invention.
3 is a block diagram showing a detailed configuration of a virtual reality data providing unit according to an embodiment of the present invention.
4 is a diagram showing the configuration of an image of a 3D block provided by a unit interior space providing unit according to an embodiment of the present invention.
5 is a block diagram and a schematic diagram showing the overall configuration of a Tetris house design system according to an embodiment of the present invention.
6A and 6B are diagrams illustrating 3D blocks selected through a unit indoor space selection unit according to an embodiment of the present invention.
7A and 76B are diagrams illustrating images of housing structure data generated through block combination of a housing structure generating unit according to an embodiment of the present invention.
8 is a diagram illustrating an interface for selecting an interior/exterior structure based on house structure data generated according to an embodiment of the present invention.
9 is a diagram showing a virtual reality screen executed through a virtual reality data provider according to an embodiment of the present invention.

1 is a view showing a frame structure for a prefabricated house according to an embodiment of the present invention.

Referring to FIG. 1, in the frame structure for a prefabricated house, a connecting member 100 composed of an intersection portion 102a and extension portions 102b protruding in three to six directions from the intersection portion 102a is the extension portion 102b. ) It is fastened with the beam 200 and the column 300 through.

The connecting member 100 includes a connecting member housing 102 forming the crossing portion 102a and the extension portion 102b, an internal insulation material 101 filled in the crossing portion 102a, and the crossing portion 102a. It includes an outer insulation cap 103 surrounding, and the extension 102b is inserted into the beam 200 and the pillar 300 as a hollow one.

The beams 200 and the pillars 300 surround the lightweight steel pipe 203 filled with the inner insulation material 201, the core material 202 introduced into the pipe 203, and the outside of the pipe 203. Insulation 204 is included.

On the outer surfaces of the beams 200 and the columns 300, a pattern consisting of ridges 211 and ridges 212 in the longitudinal direction is formed.

In one aspect, the connectors, beams, and columns may be rectangular pipe shapes.

In another aspect, a through hole for penetrating the coupling member may be formed at the end of the extension part of the connecting member and the column or beam.

In another aspect, an adhesive may be applied to an extension of the connection member to fasten the connection member and the column or beam.

In another aspect, the adhesive may be an epoxy resin.

In another aspect, a frame structure for a prefabricated house, characterized in that a two-sided spacer is bonded to some or all of the lateral or straight edges of the extension. can be

In another aspect, the cross section of the groove may be square, rectangular, triangular, semicircular, or semielliptical.

In another aspect, the depth of the furrow may be 0.1 to 20 mm, 1 to 10 mm, or 2 to 5 mm.

In another aspect, the furrows may be formed in 1 to 5, 1 to 4, or 1 to 3 furrows per side in the square pipe-type beams and columns.

In another aspect, the heat-resistant material may be a urethane foam.

In another aspect, the outer insulation material may be neoprene.

In another aspect, the outer insulation cap may be a three-sided cap or a two-sided cap.

In another aspect, the pillar or beam may be manufactured by integrally extruding the core material, the heat insulating material, and the pipe.

In another aspect, the pillar or beam may be manufactured by integrally extruding the core material, the inner insulation material, the pipe, and the outer insulation material.

In another aspect, the outer insulation material surrounding the pillar or beam may be sealed with a zipper after wrapping the pillar or beam.

In another aspect, in the frame structure, the distance between the column or beam and the connecting member extension may be 0.2 to 5 mm, 0.5 to 4 mm, or 1 to 2.6 mm.

In another aspect, the pipe may have a square or rectangular cross-section with a side of 80 to 130 mm, 85 to 120 mm, or 90 to 110 mm.

In another aspect, the cross section of the connecting member extension may be a square or rectangular shape having one side of 70 to 120 mm, 75 to 110 mm, or 80 to 100 mm.

In another aspect, the thickness of the connector housing and the pipe may be 2.5 to 3.8 T, 2.8 to 3.6 T, or 3 to 3.4 T.

In another aspect, the core material may be a material for lightweight steel or plastic.

Meanwhile, referring to FIGS. 2 to 9 , the Tetris house design system 1000 according to an embodiment of the present invention is an architectural design program using a standardized cuboid-shaped 3D block, and includes a unit interior space providing unit 100, It includes a unit interior space selection unit 200, a housing structure generation unit 300, a virtual reality data providing unit 400, and a primary construction estimate cost providing unit 500.

In this embodiment, the unit indoor space providing unit 100, the unit indoor space selection unit 200, the housing structure generating unit 300, and the primary construction estimate cost providing unit 500 are smart devices such as smart phones or tablet PCs. It may be implemented in the form of an application or program installed in (1), and the virtual reality data providing unit 400 may be implemented in the form of a program installed in the VR (virtual reality) device 2, but this is one implementation example. It can be implemented by changing in various forms.

In addition, the application supports the user to design a unique home that suits the individual's taste by using it directly, and can be directly executed by the user with the help of a designer or design-related expert as needed. The VR device 2 can be omitted, and when omitted, the corresponding virtual reality data can be executed through an application.

The unit indoor space providing unit 100 may divide each unit indoor space of the house into three-dimensional blocks 10 in which the actual area of a certain size is reflected, respectively, and provide them. Here, the unit indoor space refers to a space having functions such as a living room, kitchen, dining room, bathroom, stairs, room, and entrance, and may be displayed as a three-dimensional block 10 according to a certain standard. For example, as shown in FIG. 5, the 3D block 10 has a frame 11, an upper surface 12, a lower surface 13, and first to fourth side surfaces 14a, 14b, 14c, and 14d. It can be displayed as a three-dimensional image in the form of an approximate cube. The width, length, and height of this 3D block 10 is preset to have a predetermined standard or size of approximately 3mХ3mХ3m.

On the other hand, in the 3D block 10, basic interiors may be displayed for each function of the unit indoor space. For example, in the case of a bedroom, 3D graphics representing a bed, dressing table, wardrobe, etc. may be displayed by default, , In the case of a kitchen, 3D graphics representing sinks, refrigerators, etc. are displayed, helping to intuitively check which block is the corresponding block in the process of assembling the 3D blocks 10.

The unit indoor space selector 200 may select the type and number of unit indoor spaces. To this end, the unit indoor space selection unit 200 may include a user interface capable of selectively providing an icon or text information indicating the type of unit indoor space and the number of corresponding spaces.

The unit indoor space selector 200 may display 3D blocks selected by a user through a user interface. For example, as shown in FIG. 5A, when a user selects three-dimensional blocks 'A, B, C, D, E, F', they can be displayed, where block A is bedroom 1 and block B is Block C may indicate a kitchen, block D may indicate a bathroom, block E may indicate a living room, and block F may indicate an entrance. Although not shown, information on the number of each block selected by the user may be displayed.

To design a building, you need to draw the plane, section, and elevation by filling in the actual length while imagining the shape of the building to be created in the three-dimensional space of the X, Y, and Z axes. This requires specialized architectural training. . Architects use professional programs such as SketchUp ^® or AutoCAD ^® for design work, but this design process is not easy for the general public. Accordingly, it is possible to easily create a building by selecting and combining shapes according to options provided through the design system 1000 of the present embodiment.

That is, as shown in FIGS. 7B and 7B , if you select and combine modules such as a room, living room, bathroom, kitchen, dining room, entrance, and stairs that you need for a unit indoor space displayed as a three-dimensional block, this program automatically Since the number of combinations is made and the building is shown, the general public can easily design the building, and the size of the space is fixed, so architectural mistakes can be minimized.

The housing structure generator 300 may generate housing structure data by combining the 3D blocks 10 selected through the housing unit interior space selection unit 200 . To this end, the housing structure generator 300 may include a first housing structure generator 310 and a second housing structure generator 320 .

The first house structure creation unit 310 may generate first house structure data by combining the 3D blocks 10 selected through the unit interior space selection unit 200 in a puzzle form. To this end, the first housing structure creation unit 310 may include a combination simulation unit 311 and a combination interface unit 312 .

The combination simulation unit 311 may provide at least one combination simulation between the 3D blocks 10 selected through the unit interior space selection unit 200 . Basically, when all selectable unit interior spaces are selected, various housing structure cases that are combined with all three-dimensional blocks, that is, living room, kitchen, dining room, bathroom, stairs, room, entrance, etc., can be provided as images, and other selected units Depending on the combination of indoor space, various housing structure cases are provided as images so that the user can select the desired case after checking the housing structure case for each combination.

Accordingly, when the user selects specific blocks 10, the combination simulation unit 311 may simulate and display cases that can be combined with the selected blocks 10, and may receive a desired simulation selection from the user.

This combination simulation unit 311 can be usefully used by general users who lack a professional understanding of building structures, and can present convenience store and interior recommendation information for each case.

The combination interface unit 312 is activated according to user settings and may provide a user interface so that the user can directly combine the 3D blocks 10 selected through the unit indoor space selection unit 200 .

For example, as shown in FIG. 6, when a user selects 'A, B, C, D, E, F' blocks, the selected 'A, B, C, D, E, F' blocks are shown in FIG. As shown, one house structure data can be created by arranging 'A, B, C, D' blocks in a row, and arranging 'E, F' blocks on the side of 'C' block, which is a 3D graphic can be displayed and displayed. In this embodiment, not only can the selected blocks be combined in a T-shaped structure, but the user can directly move graphics or icons representing the corresponding blocks using the combination interface unit 312 in a drag-and-drop manner to create various combinations. can be made directly.

In the combination interface unit 312, design information that cannot be combined between 3D blocks is stored in advance. For example, a combination in which the first floor is composed of only one block and multiple blocks on the second floor or more, a combination in which the entrance is placed on the second floor, and a space between rooms such as 'room-toilet-room' It is not an open communal living space, but various information on associations, such as associations that are expected to be uncomfortable in housing use, can be stored.

The combination interface unit 312 may drop the combined 3D block from the simulation being combined when the user makes a block combination corresponding to the above case.

For example, if the user makes a combination of one block on the first floor and multiple blocks on the second floor or higher, move some blocks on the second floor to the first floor, but it is appropriate to place them on the first floor. It moves from the block of the indoor unit space, and in this process, improperly placed blocks can be separated or eliminated from the corresponding combination.

In addition, if the entrance is made of a combination that is placed on the second floor, the block is removed from the combination and placed on the first floor, and it is not a common living space where the space between rooms is open like 'room-toilet-room', but a house In the case of a combination that is expected to be inconvenient in use, a block corresponding to 'toilet' may be separated or eliminated from the corresponding combination and placed in a predetermined appropriate location. Accordingly, it is possible to guide a user who lacks architectural design or common sense to design an appropriate block combination. On the other hand, when the 3D blocks are connected, the frames 11 included in the block are also overlapped. In this case, when two or more frames 11 overlap or overlap, they are automatically changed to one column on the design program. Design data can be created.

The second housing structure generator 320 may generate second housing structure data by setting the location, type, and number of visits, doors and windows based on the first housing structure data generated as described above. To this end, the second housing structure creation unit 320 may include a block contact surface display unit 321, a block outer surface display unit 322, an internal structure selection unit 323 and an external structure selection unit 324, The contact surface display unit 321 and the internal structure selection unit 323 can be executed through one user interface (hereinafter referred to as a first user interface), and the block outer surface display unit 322 and the external structure selection unit 324 can also be implemented. It can be executed through another user interface (referred to as a second user interface).

The block contact surface display unit 321 may display the contact surfaces of the 3D blocks among the first housing structure data in a selectable manner using the first user interface. For example, as shown in FIG. 8 , when an 'A' block and a 'B' block are in contact, a contact surface between the A' block and the 'B' block may be selected. In the case of this contact surface, it can be between a room and a living room, between a room and a bathroom, between a room and a kitchen, between a room and a dining room, etc. Whether to apply or open can be displayed so that the user can select. However, depending on the setting, if blocks adjacent to each other are of the same type of indoor unit space, the contact surface between the corresponding blocks may not be displayed separately. For example, when a living room and a living room, a room and a room, and a bathroom and a bathroom are combined so that they are directly connected, the contact surface between the blocks is recognized as expanding the size of the living room, room size, or bathroom. It may not be marked separately so that it can be selected. This is according to user settings, and even if blocks of the same type are adjacent to each other, all corresponding contact surfaces may be displayed selectably.

The block outer surface display unit 322 may display the outer surfaces excluding the contact surfaces of the 3D blocks among the first housing structure data in a selectable manner, respectively, using the second user interface. For example, as shown in FIG. 7 , in the case of a 'C' block, an outer surface without inter-block contact may be displayed to be selectable. Of course, not only the 'C' block is displayed, and all outer walls may be displayed to be selectable.

The internal structure selector 323 enables selection of openness between unit indoor spaces and types and locations of visits for each contact surface displayed through the block contact surface display unit 312 using the first user interface. For example, as shown in FIG. 7, if the contact surface between the 'A' block and the 'B' block is selected, the architectural symbols related to the door such as a single door, a double door, a single door, a double sliding window, etc. Or, the name and description are displayed, and the user can select the desired type of door, and the location can also be selected. Of course, although not shown, it is possible to select an open form between the 'A' block and the 'B' block without a separate entrance door.

Meanwhile, when blocks are combined, the internal structure selector 323 may provide a first user interface to select adjacent blocks, that is, overlapping pillar shapes or types between adjacent indoor unit spaces, and internal finishing materials.

The exterior structure selector 324 enables the selection of types and locations of windows and doors for the outer surface displayed through the block outer surface display unit 322 using the second user interface. For example, as shown in FIG. 8, architectural symbols or names and descriptions related to windows and doors such as single casement windows, double casement windows, mesh windows, single casement doors, and double casements are displayed, and the types of windows and doors desired by the user are displayed. can be selected, and the location can also be selected.

Meanwhile, the external structure selection unit 324 may provide a second user interface to select an external finishing material and a roof shape when blocks are finally combined.

The above-described first and second user interfaces may be sequentially activated after generation of the first housing structure data is completed through the first housing structure generating unit 310, and the type of visit, door, and window through the corresponding interface When the setting and selection of the number of locations are completed, second housing structure data may be generated. On the other hand, the housing structure creation unit 300 provides a third user interface so that the user can set or select internal facilities or system design between blocks, such as electrical wiring and drainage lines between blocks combined. .

The virtual reality data providing unit 400 may generate and provide virtual reality data based on the housing structure data generated by the housing structure generating unit 300, that is, the second housing structure data. To this end, the virtual reality data providing unit 400 may include a virtual reality data generating unit 410 and a virtual reality data executing unit 420 .

The virtual reality data generating unit 410 may generate virtual reality data by rendering house structure data into 3D model data. The housing structure data generated through the housing structure generating unit 300 is also 3D graphic data, but serves to convert it so that it can be executed in the VR device 2. The virtual reality data generation unit 410 may be implemented as a dedicated application installed in the smart device 1, and the generated virtual reality data is transmitted to the VR device 2 so that the corresponding data is executed.

The virtual reality data execution unit 420 may be implemented in the form of a program installed in the VR device 2, but may also be implemented as the VR device 2 itself. The virtual reality data executor 420 executes virtual reality data so that the user can experience the internal structure, shape, size and lighting of the virtual house based on the house structure data generated by the virtual reality data generator 410. can

For example, as shown in FIG. 8 , the virtual reality data execution unit 420 executes the virtual reality data generated through the virtual reality data generation unit 410 when the user wears the VR device 2, so that the user While moving inside the virtual house, you can feel or experience the structure, shape, size, etc. of the inside of the house. Through this process, users can check the house they have designed as directly as possible, so they can understand the design structure of the house more effectively than the existing design drawing, etc. We can help with corrections or changes to

When the housing structure is finally determined with the housing structure data generated through the housing structure creation unit 300, the primary construction estimate cost providing unit 500 determines the unit indoor space selected through the unit indoor space selection unit 200. Based on the type, number, and actual area information of the 3D block, the first construction estimate cost can be calculated and provided.

As described above, since the 3D block displayed as a unit indoor space has certain standard information, based on the total number of unit indoor spaces selected by the user and the type information of each unit indoor space in the final confirmed house structure, an approximate Estimated cost of construction materials can be calculated.

When the housing design is finalized through the above process, the design system 1000 of this embodiment requests construction to a designated construction company. Amount excluding costs may be presented.

When an ordinary person makes architectural drawings using an existing computer design program, he or she must draw the drawings while imagining a three-dimensional building with his or her head using a program that requires separate professional training, such as SketchUp ^® or AutoCAD ^® . At this time, it is quite difficult for those who have not received architectural training to conceive or design a building. In addition, since the general public cannot estimate the appropriate size of space (for example, drawing a bathroom or kitchen very narrow or very wide), in most cases, the produced design drawings cannot be realized.

In the Tetris House design system according to this embodiment, the general public can plan and view a reasonable space using a standardized rectangular parallelepiped, easily create the shape of a building, check the shape and the interior and exterior space with virtual reality (VR) goggles, It can be modified, and it outputs construction drawings such as the estimated construction cost of the finalized building, architectural floor plan, elevation, section, and detailed drawing so that it can be easily constructed, and by implementing these programs in the smartphone app, user accessibility and convenience can be raised

Claims (20)

The connecting member 100 composed of the intersection portion 102a and the extension portions 102b protruding in three to six directions from the intersection portion 102a passes through the extension portion 102b to the beam 200 and the column 300. ) As a frame structure for prefabricated houses fastened with,
The connecting member 100 includes a connecting member housing 102 forming the crossing portion 102a and the extension portion 102b, an internal insulation material 101 filled in the crossing portion 102a, and the crossing portion 102a. It includes an outer insulation cap 103 surrounding, and the extension 102b is inserted into the beam 200 and the column 300 as a hollow one,
The beams 200 and the pillars 300 surround the lightweight steel pipe 203 filled with the inner insulation material 201, the core material 202 introduced into the pipe 203, and the outside of the pipe 203. Including insulation 204,
The outer surfaces of the beams 200 and the pillars 300 are characterized in that a pattern consisting of ridges 211 and ridges 212 in the longitudinal direction is formed, the prefabricated house frame structure. The method of claim 1,
The prefabricated house frame structure, characterized in that the connecting material, beams, and columns are in the shape of a square pipe. The method of claim 1,
A prefabricated house frame structure, characterized in that through holes for penetrating coupling members are formed at the ends of the extensions of the connecting members and the pillars or beams. The method of claim 1,
A frame structure for a prefabricated house, characterized in that by applying an adhesive to the extension of the connecting member to fasten the connecting member and the pillar or beam. The method of claim 1,
The prefabricated house frame structure, characterized in that the adhesive is an epoxy resin. The method of claim 1,
A frame structure for a prefabricated house, characterized in that a two-sided spacer is attached to some or all of the lateral or straight edges of the extension. The method of claim 1,
The cross-section of the furrow is a square, rectangular, triangular, semi-circular, or semi-elliptical frame structure for a prefabricated house, characterized in that. The method of claim 5,
Characterized in that the depth of the groove is 0.1 to 20 mm, 1 to 10 mm, or 2 to 5 mm, the prefabricated house frame structure. The method of claim 5,
The furrows are characterized in that 1 to 5, 1 to 4, or 1 to 3 are formed per side in the square pipe-type beams and columns. The method of claim 1,
The frame structure for a prefabricated house, characterized in that the heat insulation material is a urethane foam. The method of claim 1,
The outer insulation material is a frame structure for a prefabricated house, characterized in that neoprene. The method of claim 1,
The outer insulation cap is a three-sided cap or a two-sided cap, characterized in that, the prefabricated house frame structure. The method of claim 1,
The frame structure for a prefabricated house, characterized in that the core material, the heat insulation material, and the pipe are manufactured by integrally extruding the pillar or beam. The method of claim 1,
The frame structure for a prefabricated house, characterized in that the core material, the inner insulation material, the pipe, and the outer insulation material are manufactured by integrally extruding the pillar or beam. The method of claim 1,
Characterized in that the outer insulation surrounding the pillar or beam is sealed with a zipper after wrapping the pillar or beam, the prefabricated house frame structure. The method of claim 1,
In the frame structure, the distance between the pillar or beam and the connecting member extension is 0.2 to 5 mm, 0.5 to 4 mm, or 1 to 2.6 mm, characterized in that, the prefabricated house frame structure. The method of claim 1,
The pipe is a frame structure for a prefabricated house, characterized in that the cross section is a square or rectangular shape with a side of 80 to 130 mm, 85 to 120 mm, or 90 to 110 mm. The method of claim 1,
A frame structure for a prefabricated house, characterized in that the cross section of the connecting member extension is a square or rectangular shape with one side of 70 to 120 mm, 75 to 110 mm, or 80 to 100 mm. The method of claim 1,
The prefabricated house frame structure, characterized in that the thickness of the connector housing and the pipe is 2.5 to 3.8 T, 2.8 to 3.6 T, or 3 to 3.4 T. The method of claim 1,
The core material is a frame structure for a prefabricated house, characterized in that it is a material for lightweight steel frame or plastic.

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