TWM641960U - Foldable prefabricated house - Google Patents

Abstract

This creation discloses a foldable composite house, which includes two side wall structures, two end wall structures, a first roof component, a second roof component, two floor components, plastic-steel doors and plastic-steel windows. The foldable modular house can be switched between the folded state and the ready house state. The second roof element is rotatable relative to the first roof element. The two end wall structures are rotatable relative to at least one side wall structure. The two floor members can rotate relative to each other. When the foldable composite house is in the folded state, the two floor components are arranged between the two side wall structures after being rotated against each other, and the two end wall structures are respectively rotated and located on the outside of the side wall structures. The roof elements are rotated against the outside of the two end wall structures.

Description

folding house

This creation involves a foldable modular house, especially a foldable modular house used to replace traditional container houses.

The existing common container houses need to be transported in the entire container, which leads to high freight costs, especially for international transport, which requires a large amount of freight costs.

This creation discloses a foldable modular house, which is mainly used to improve the problem of high transportation cost of the conventional container house.

One embodiment of the invention discloses a foldable composite house, which includes: a wall panel, a roof structure, a floor structure, at least one plastic-steel door and at least one plastic-steel window. A wall group contains multiple wall structures, where two wall structures are defined as two side wall structures and the other two wall structures are defined as two end wall structures; each end wall structure is pivoted to one of the side wall structures connected, and each end wall structure can rotate relative to its pivoted side wall structure; the roof structure includes a first roof component and a second roof component, the long sides of the first roof component and the long sides of the second roof component equal length, the short side of the first roof component is smaller than the short side of the second roof component; the first roof component is connected to one of the side wall structures, the first roof component and the second roof component are pivotally connected to each other, and the second roof component can Rotates relative to the first roof element; the floor structure consists of two floor elements pivotally connected to each other; one of the floor elements is pivotally connected to one of the side wall structures and the other floor element is pivotally connected to the other side wall structure connected; the plastic-steel door is arranged on at least one of the side wall structure and the end wall structure; the plastic-steel window is arranged on at least one of the side wall structure and the end wall structure; wherein, the foldable composite house can be operated and converted from a folded state It is a finished house state; when the combined house is in a folded state, the outer wide sides of the two floor members are against each other, and the inner wide side of one of the floor members is against one of the side wall structures the inner wide side of the other floor member against the inner wide side of the other side wall structure, the outer wide side of each end wall structure against the outer wide side of one of the side wall structures, the second roof The inner wide side of the component is against the inner wide side of the two end wall structures; when the foldable prefabricated house is in the finished state, the two side wall structures, the two end wall structures, the first roof member, and the second roof The component and the two floor components together constitute an indoor space. The outer wide sides of each floor component, the outer wide side of each end wall structure and the outer wide side of each side wall structure are located outside the indoor space; the inner wide sides of each floor component , the inner wide sides of each side wall structure, the inner wide side of the end wall structure and the inner wide side of the second roof element are all located in the interior space.

One embodiment of the invention discloses a foldable composite house, which includes: a wall panel, a roof structure, a floor structure, at least one plastic-steel door and at least one plastic-steel window. A wall group contains multiple wall structures, where two wall structures are defined as two side wall structures and the other two wall structures are defined as two end wall structures; each end wall structure is pivoted to one of the side wall structures Each end wall structure can be rotated relative to the side wall structure to which it is pivoted; the roof structure includes two roof components, and the two roof components are pivotally connected to each other; one of the roof components is pivotally connected to one of the side wall structures, Another roof component and another side wall structure are pivotally connected to each other; the floor structure includes a plurality of floor components, and the multiple floor components are pivotally connected to each other, and any one of the floor components can rotate relative to another adjacent floor component. The long sides of the components are equal in length, and one of the floor components is connected to one of the side wall structures; the plastic steel door is set on at least one of the side wall structure and the end wall structure; the plastic steel window is set on at least one of the side wall structure and the end wall structure; Wherein, the foldable combined house can be operated and converted from a folded state to a ready-made state; when the combined house is in the folded state, the outer wide sides of the two roof members are against each other, and the inner wide side of one of the roof members is against each other. against the inner wide side of one of the side wall structures, the inner wide side of the other roof element against the inner wide side of the other side wall structure, and the outer wide side of each end wall structure against the inner wide side of one of the side wall structures On the outside wide side, the floor element connected to one of the side wall structures is located on the side of the two side wall structures, the two roof elements and the two end wall structures, and the inner side of the other floor element faces the two end wall structures The inner side of the setting; among them, the folding When the stacked composite house is in the finished state, two side wall structures, two end wall structures, multiple floor components and two roof components together form an indoor space, and the outer wide sides of each roof component and each end wall structure The outer broadsides and the outer broadsides of the individual side wall structures are located outside the interior space; the inner broadsides of the individual roof elements, the inner broadsides of the individual side wall structures, the inner broadsides of the end wall structures and the inner broadsides of the individual floor elements , are located in the interior space.

To sum up, compared with the traditional container house, the folding modular house of this creation has the technical function of relatively lower transportation costs.

In order to further understand the characteristics and technical content of this creation, please refer to the following detailed description and drawings about this creation, but these descriptions and drawings are only used to illustrate this creation, not to make any statement on the scope of protection of this creation limit.

A: Foldable combined house

1: Main frame body

11: Shelf body

111: Groove

112: Convex structure

113: guide bevel

114: drainage hole

12: lower frame body

121: Protruding structure

122: Lower glue groove

13: column structure

14: Upper frame structure

15: Lower frame structure

3: ceiling body

4: board body

4A: First side

4B: Second side

4C: Modeling section

41:Support structure

411: Assembly groove

412: support part

413: Edge department

4131: Narrow side

414: connection part

415: engaging groove

42:SMC chip body

42A: Snap slot

42B: snap structure

421: Assembly hole

422: Outdoor drainage hole

423: Decoration Department

424: glue tank

425: Ontology

4251: wide side

426: Extended structure

43: Hollow tube body

431: hollow channel

432: perforation

434: sloped end wall

435: drainage perforation

44: foam structure

45:Accommodating space

46: Snap slot

47: Auxiliary support structure

48: Strengthening components

481: Fixed sheet

482: lock

5: Plastic steel door

6: Plastic steel window

7: Solar installation

71: Solar panels

72: circuit device

8: Electric energy storage device

91: The first auxiliary engaging structure

92: Second auxiliary engaging structure

A1: Wall group

A11: Side wall structure

A111: frame

A112: inner wide side

A113: Outer wide side

A12: Side wall structure

A121: frame

A122: inner wide side

A123: Outer wide side

A13: End wall structure

A131: frame

A132: inner wide side

A133: Outer wide side

A14: End wall structure

A141: frame

A142: inner wide side

A143: Outer wide side

A2: Roof structure

A21: First roof component

A211: frame

A212: inner wide side

A213: Outer wide side

A22: Second roof member

A221: frame

A222: inner wide side

A223: Outer wide side

A23: Outdoor

A3: Floor structure

A31: Floor components

A311: frame

A312: inner wide side

A313: Outer wide side

A32: Floor components

A321: frame

A322: inner wide side

A323: Outer Wide Side

B1: waterproof glue structure

B2: Lower waterproof glue structure

B3: waterproof glue

C: waterproof tape

D1: Thickness

D2: Thickness

E: wire

F: socket

G: drain pipe

L1: Spacing

L2: Spacing

SP1: Mezzanine Space

SP2: Interior Space

SP3: Hollow channel

H: Foldable modular house

H1: wall group

H11: Side wall structure

H111: inner wide side

H112: Outer wide side

H12: Side wall structure

H121: inner wide side

H122: Outer wide side

H13: End wall structure

H131: inner wide side

H132: Outer wide side

H14: End wall structure

H141: inner wide side

H142: Outer wide side

H2: Roof structure

H21: Roof elements

H211: inner wide side

H212: Outer wide side

H3: Floor structure

H31: Floor components

H311: inner wide side

H312: Outer wide side

H32: Floor components

H321: inner wide side

H322: Outer wide side

H33: Floor components

H331: inner wide side

H332: Outer wide side

H4: plastic steel door

H5: plastic steel window

H6: Auxiliary components

H61: frame body

H62:Roller

Fig. 1 is a schematic diagram of a foldable combined house according to the first embodiment of the invention.

FIG. 2 and FIG. 3 are schematic views of different viewing angles of the foldable prefabricated house in the folded state according to the first embodiment of the present invention.

FIGS. 4 to 7 are respectively schematic diagrams showing the operation of the foldable prefabricated house in the first embodiment of the present invention, from the folded state to the completed state.

Fig. 8 is a schematic diagram of the assembly of the foldable assembled house of the second embodiment of the present invention.

FIG. 9 is an exploded schematic view of the foldable combined house of the second embodiment of the present invention.

Fig. 10 is a schematic top view of a single panel of the foldable assembled house according to the second embodiment of the present invention.

Fig. 11 is a schematic cross-sectional view of a foldable combined house according to the second embodiment of the invention.

12 to 14 are partial enlarged schematic diagrams of different regions in FIG. 11 .

Fig. 15 is another schematic cross-sectional view of the foldable combined house of the second embodiment of the present invention.

Fig. 16 is a schematic top view of the interconnection of two boards of the foldable composite house according to the second embodiment of the present invention.

FIG. 17 is a partially enlarged schematic view of FIG. 16 .

Fig. 18 is an exploded schematic view of one end of the two boards of one embodiment of the foldable assembled house of the present invention.

FIG. 19 and FIG. 20 are schematic diagrams of disassembly and assembly of two boards of one embodiment of the foldable assembled house of the present invention, respectively.

FIG. 21 and FIG. 22 are schematic diagrams of disassembly and assembly of two boards of one embodiment of the foldable assembled house of the present invention, respectively.

Fig. 23 is a schematic diagram of the combination of two boards of one embodiment of the foldable assembled house of the present invention.

FIG. 24 is a partially enlarged schematic view of FIG. 23 .

Fig. 25 is a schematic view of the completed state of the third embodiment of the foldable combined house of the present invention.

FIG. 26 and FIG. 27 are schematic diagrams of different viewing angles of the third embodiment of the foldable prefabricated house of the present invention in a folded state.

Fig. 28 to Fig. 31 are schematic diagrams of the third embodiment of the foldable combined house of the present invention, which is converted from the folded state to the finished house state.

In the following description, if it is pointed out that please refer to the specific drawing or as shown in the specific drawing, it is only used to emphasize the subsequent description, and most of the relevant content mentioned appears in the specific drawing, It is not intended, however, to limit the ensuing description to only those particular drawings referred to.

Please refer to Figures 1 to 7 together. Figure 1 is a schematic diagram of the foldable composite house created by this author. 7 The action of converting the folding prefabricated house from the folded state to the completed state schematic diagram. The foldable composite house A of this creation includes: a wall group A1, a roof structure A2, a floor structure A3, multiple plastic-steel doors 5 and multiple plastic-steel windows 6. Wall group A1 includes four wall structures, two of which are defined as two side wall structures A11 and A12, and the other two wall structures are defined as two end wall structures A13 and A14. The two side wall structures A11 , A12 are arranged facing each other, and the two end wall structures A13 , A14 are arranged facing each other. Two end wall structures A13, A14 are pivotally connected to two ends of one side wall structure A12, and each end wall structure A13, A14 can be operated to rotate relative to the side wall structure A12.

It should be noted that in this embodiment, the two end wall structures A13 and A14 are pivotally connected to the same side wall structure A12 as an example, but in different embodiments, the two end wall structures A13 and A14 are also It may be pivotally connected to the side wall structures A11 and A12 respectively, that is, the end wall structure A13 is pivotally connected to one end of the side wall structure A11, and the end wall structure A14 is pivotally connected to one end of the side wall structure A12.

In practical application, the periphery of each side wall structure A11, A12 and the periphery of each end wall structure A13, A14 may have a frame body A111, A121, A131, A141 respectively. Frames A111, A121, A131, A141 are mainly used to strengthen the structural strength of each side wall structure A11, A12 and each end wall structure A13, A14, and the frame body can be made of metal material, but it is not taken as a limit. Between the frame body A131 of the end wall structure A13 and the frame body A121 of the adjacent side wall structure A12, a plurality of pivotal components (not shown, such as various hinges) can be arranged, and the end wall structure A13 can Rotate relative to the side wall structure A12 through a plurality of pivoting components, similarly, a plurality of pivoting components ( Not shown in the figure, such as various hinges), and the end wall structure A14 can rotate relative to the side wall structure A12 through a plurality of pivot components.

In practical applications, the end wall structure A13 can be operated to rotate 270 degrees relative to the side wall structure A12, and the outer wide side A133 of the end wall structure A13 can correspond to the outer wide side A123 of the side wall structure A12; The wall structure A14 can be operated to rotate 270 degrees with respect to the side wall structure A12, and the outer wide side A143 of the end wall structure A14 can correspondingly abut against the outer surface of the side wall structure A12. Broadside A123. When the end wall structures A13 and A14 are rotated 270 degrees respectively, the inner wide sides A132 and A142 of the end wall structures A13 and A14 will be exposed on one side of the outer wide side A123 of the side wall structure A12.

The roof structure A2 includes a first roof component A21 and a second roof component A22, and the size of the first roof component A21 is smaller than that of the second roof component A22. In practical application, the length of the long side (the side adjacent to the side wall structure A11) of the first roof member A21 is the same as the length of the long side (the side adjacent to the side wall structure A12) of the second roof member A22, The length of the short side (the side adjacent to the end wall structures A13, A14) of the first roof member A21 is smaller than the length of the short side (the side adjacent to the end wall structures A13, A14) of the second roof member A22.

The first roof component A21 is connected to one of the side wall structures A11; in practical applications, the frame body A211 of the first roof component A21 and the frame body A111 of the side wall structure A11 may be fixed to each other by means of welding or screwing. The first roof member A21 and the second roof member A22 are pivotally connected to each other, and the second roof member A22 is operable to rotate relative to the first roof member A21. In practical applications, the three sides of the first roof component A21 and the three sides of the second roof component A22 can be provided with frames A211 and A221 respectively, and one of the frames A211 of the first roof component A21 is the same as The frames A111 of one side wall structure A11 are fixed to each other. The sides of the first roof member A21 and the second roof member A22 are pivotally connected to each other, and a plurality of pivot assemblies (not shown, such as various hinges) are provided, and the second roof member A22 is formed by a plurality of pivot joints. assembly, rotated relative to the first roof member A21. In practice, the second roof member A22 can be manipulated to rotate downwards by 90 degrees with respect to the first roof member A21, and the inner wide side A222 of the second roof member A22 can be abutted against after being rotated 270 degrees. The inner wide sides A132 and A142 of the two end wall structures A13 and A14 on one side of the side wall structure A12 (as shown in FIG. 2 and FIG. 3 ).

The floor structure A3 comprises two floor elements A31, A32 which are pivotally connected to each other. One of the floor components A31 is pivotally connected to one of the side wall structures A11, and the other floor component A32 is pivotally connected to the other side wall structure A12. In practical applications, the three sides of each floor member A31, A32 can be provided with frames A131, A321 (such as gold frame). The frame body A311 of the floor member A31 and the frame body A111 of the side wall structure A11 may be provided with a plurality of pivotal components, and the floor component A31 can rotate relative to the side wall structure A11 through these pivotal components; Reasonably, the frame body A321 of the floor member A32 and the frame body A121 of the side wall structure A12 may be provided with a plurality of pivotal components, and the floor component A32 can rotate relative to the side wall structure A12 through these pivotal components. . The sides of the two floor components A31 and A32 that are pivotally connected to each other may be provided with multiple pivot components (such as various hinges), while the two floor components A31 and A32 are pivotally connected to each other through multiple pivot components. .

The plastic-steel door 5 is arranged on at least one side wall structure A11, A12. The plastic-steel window 6 is arranged on at least one side wall structure A11, A12. The quantity and setting positions of the plastic-steel doors 5 and the plastic-steel windows 6 are not limited to those shown in the figure, and can be changed according to actual needs. The plastic-steel door 5 and the plastic-steel window 6 referred to here refer to doors and windows made of fiber reinforced plastics (Fiber Reinforced Plastics, FRP).

When the foldable prefabricated house A is in the finished state (as shown in Figure 1), the two side wall structures A11, A12, the two end wall structures A13, A14, the first roof component A21, the second roof component A22 and the floor structure A3, together constitute an indoor space, the inner wide side A112 of the side wall structure A11, the inner wide side A122 of the side wall structure A12, the inner wide side A132 of the end wall structure A13, the inner wide side A142 of the end wall structure A14, The inner wide side A212 of a roof member A21, the inner wide side A222 of the second roof member A22, the inner wide side A312 of the floor member A31 and the inner wide side A322 of the floor member A32 are all located in the indoor space. Conversely, the outer wide sides A113, A123 of the two side wall structures A11, A12, the outer wide sides A133, A143 of the two end wall structures A13, A14, the outer wide sides A213 of the first roof member A21, the second roof member A22 The outer wide side A223 of the floor member A31, the outer wide side A313 of the floor member A31 and the outer wide side A323 of the floor member A32 are located outdoors.

As shown in Figures 1 to 3, the foldable combined house A can be operated and converted from a folded state (as shown in Figure 2 and Figure 3) to a finished house state (as shown in Figure 1), the foldable combined house The overall volume of A in the folded state is smaller than the overall volume of the foldable combined house A in the completed state, and the foldable combined house When the house A is in the folded state, it can be easily transported, and the transportation cost of the foldable combined house A can be greatly saved.

More specifically, as shown in FIG. 2 and FIG. 3, when the foldable prefabricated house A is in the folded state, the outer wide sides A313, A323 of the two floor members A31, A32 will abut against each other, and the inner width of the floor member A31 The side A312 will abut the inner broadside A112 of the side wall structure A11, the inner broadside A322 of the floor member A32 will abut the inner broadside A122 of the side wall structure A12, the outer broadsides of the two end wall structures A13, A14 A133, A143 will abut against the outer broadside A123 of the side wall structure A12, the inner broadside A222 of the second roof element A22 is the side that abuts the inner broadside A132, A142 of the two end wall structures A13, A14.

As shown in Fig. 2, Fig. 4 and Fig. 5, when the foldable prefabricated house A is in a folded state, relevant personnel may first use related equipment (such as a crane) to rotate the second roof member A22 upward until the second The outer wide side A223 of the roof member A22 is flush with the outer wide side A213 of the first roof member A21. In practical applications, when the relevant personnel make the outer wide side A223 of the second roof component A22 flush with the outer wide side A213 of the first roof component A21, the relevant personnel may first use relevant fixing members (such as screws, etc.) to make the The first roof member A21 and the second roof member A22 are fixed to each other.

Next, as shown in FIG. 5 and FIG. 6, the relevant personnel may pull out the side wall structure A12 located under the second roof member A22 in a direction away from the side wall structure A11, so that one side of the side wall structure A12 , move to the side of the second roof member A22 opposite to the side connected to the first roof member A21, and at the same time, the inner wide sides A312, A322 of the two floor members A31, A32 will be converted into a flush state. In practice, during the process of pulling the side wall structure A12 under the second roof component A22 away from the side wall structure A11, the second roof component A22 may be continuously pulled by equipment such as a crane. Support, by which, the safety of the relevant personnel can be ensured.

Then, relevant personnel can use relevant fixing components (such as screws, etc.) to fix the frame body A221 of the second roof component A22 and the frame body A121 of the adjacent side wall structure A12 to each other, and make the two floor components A31, A32 The frames A311 and A321 are fixed to each other. In a preferred embodiment, a plurality of slide rails and other components may be arranged on the inner wide side A222 of the second roof component A22, and one side of the side wall structure A12 is connected with the slide rails. When carrying out the operations shown in FIG. 5 and FIG. 6 , relevant personnel will be able to relatively easily pull out the side wall structure A12.

As shown in Figure 6, when one side of the second roof component A22 has been fixed to one side of the first roof component A21, the other side of the second roof component A22 has been fixed to the side wall structure A12, and When the two floor elements A31, A32 have been fixed to each other, the first roof element A21, the second roof element A22, the two side wall structures A11, A12 and the two floor elements A31, A32 will jointly form a hollow channel SP3. Then, as shown in Figure 6 and Figure 7, the relevant personnel can rotate each end wall structure A13, A14 respectively, so that the two end wall structures A13, A14 cover the openings at both ends of the hollow passage SP3, and finally, each end wall The structures A13 and A14 are opposite to the sides pivotally connected with the adjacent side wall structure A12, and are mutually fixed with the side wall structure A11, so that the foldable composite house A can be in a completed state.

It should be noted that after the foldable composite house A is converted into the finished house state, the relevant personnel can also carry out relevant waterproofing and structural reinforcement on the foldable composite house A according to actual needs, so that the foldable composite house in the ready-made state Housing A can achieve good weather resistance (such as wind resistance, rain resistance, etc.). In the interior space of the foldable composite house A, a plurality of reinforced steel beams are additionally provided, and relevant personnel may also use relevant waterproof glue to fill the pivot joints and seams of the foldable composite house A.

According to the above, the overall volume of the folding prefabricated house A in this creation will be significantly smaller than that of the existing house in the folded state, and the collapsible prefabricated house A can be easily transported in the folded state. reduce transportation costs. Dangben's Foldable Modular House A After being transported to the predetermined location, the relevant personnel can convert the folded modular house A in the folded state into the ready house state through simple operations.

Please refer to FIG. 8 and FIG. 9 together, which are schematic diagrams of assembly and partial component decomposition of the second embodiment of the foldable assembled house of the present invention, respectively. The foldable composite house A of this creation includes a main frame body 1, a ceiling body 3, a plurality of panels 4, a plastic steel door 5, a plurality of plastic steel windows 6, a solar device 7 and an electric energy storage device 8. In different embodiments, the foldable combined house A may also not include a plurality of ceiling bodies 3 .

The main frame body 1 is mainly used as the main supporting structure of the foldable prefabricated house A, and the main frame body 1 may be fixedly arranged on a plurality of foundations, for example. The main frame 1 can be divided into a plurality of upper frames 11 , a plurality of lower frames 12 and a plurality of column structures 13 . A plurality of upper frames 11 are connected to each other to jointly form an upper frame structure 14 , and a plurality of lower frames 12 are connected to each other to jointly form a lower frame structure 15 . A plurality of column structures 13 are arranged upright, and two ends of each column structure 13 are respectively connected to the upper frame structure 14 and the lower frame structure 15 . In one specific embodiment, each upper frame body 11 , each lower frame body 12 and each column structure 13 may be made of steel, and they may be fixed to each other by means of welding or rivets.

It should be noted that the main frame body 1 referred to in this embodiment is composed of the frame bodies A111 and A121 of the side wall structures A11 and A12 described in the foregoing embodiments, the frame bodies A131 of the end wall structures A13 and A14, A141, the frame body A211 of the 1st roof member A21, the frame body A221 of the 2nd roof member A22, the frame body A311 of the floor member A31, and the frame body A321 of the floor member A32 are comprised. The exploded schematic diagram shown in Figure 9 is only to better explain the connection relationship between the main frame body 1, the ceiling body 3 and a plurality of board bodies 4, and the exploded schematic diagram is consistent with the actual structure of the foldable composite house. The method of assembly is irrelevant. In addition, for the convenience of description, in the drawings of this embodiment, only the main frame body 1, the upper frame body 11, a plurality of lower frame bodies 12 and a plurality of column structures 13 are used for marking, but not frame bodies A111, A121, A131, A141, A211, A221, A311, A321 are marked.

The ceiling body 3 can be fixed with the main frame body 1 through components such as light steel frames, and the main frame body 1 and a plurality of ceiling bodies 3 jointly form a mezzanine space SP1 (as shown in Figure 11) and an indoor space. Space SP2 (as shown in Figure 11). The mezzanine space SP1 is used to provide a part of lamps, a part of air-conditioning equipment, various pipelines (such as water pipes, power pipes, etc.), and various lines (such as various electric wires, routings, etc.). The indoor space SP2 provides user activities. The fixing method between the main frame body 1 and the plurality of ceiling bodies 3 belongs to the known technology, and will not be repeated here.

A plurality of panels 4 are fixed to the main frame body 1, and a part of the plurality of panels 4 are connected to each other to jointly serve as one of the wall structures of the foldable modular house A, and a part of the plurality of panels 4 are connected to each other to jointly serve as In a roof structure A2 of the foldable combined house A, a part of a plurality of boards 4 are connected to each other to serve as a floor structure A3 of the foldable combined house A. Regarding the quantity of the boards 4 forming the wall structure, the number of the boards 4 forming the roof structure A2 and the number of the boards 4 forming the floor structure A3, they can all be designed according to the actual size of the foldable composite house A. This is not limited.

The plastic-steel door 5 is arranged on the main frame body 1 or at least one plate body 4 . The plastic-steel window 6 is arranged on at least one plate body 4 . The quantity of the plastic-steel door 5 and the plastic-steel window 6 can be changed according to requirements, and is not limited to what is shown in the figure. In practical application, the gap between the plastic-steel door 5 and the board body 4 and the gap between the plastic-steel window 6 and the board body 4 may be filled with waterproof glue. The plastic-steel door 5 and the plastic-steel window 6 referred to here refer to doors and windows made of composite plastic as the main material. For example, the main materials of the plastic-steel door 5 and the plastic-steel window 6 can be glass fiber reinforced thermosetting plastic sheet molding compound (Sheet Molding Compound, SMC), and the plastic-steel window 6 can also be added iron parts according to requirements to strengthen them. Structural strength.

The solar device 7 includes at least one solar panel 71 and a circuit device 72, and the solar panel 71 and the circuit device 72 are arranged on the roof structure A2. The solar panel 71 is electrically connected to the circuit device 72, and the circuit device 72 includes necessary electronic components such as a battery and a frequency converter. The electric energy storage device 8 is used to store the electric energy generated by the solar device 7 , and the electric energy storage device 8 is electrically connected to the solar device 7 through a plurality of wires. Both the solar energy device 7 and the electric energy storage device 8 belong to the prior art, and will not be repeated here.

Please refer to Fig. 10 to Fig. 15 together. Fig. 10 is a schematic top view of a single panel of the foldable combined house of the second embodiment of the present invention, and Fig. 11 is a schematic view of the foldable combined house of the second embodiment of the present invention. 12 to 14 are partial enlarged schematic diagrams of different areas in FIG. 11 , and FIG. 15 is another schematic cross-sectional view of the foldable composite house of the second embodiment of the present invention.

As shown in FIG. 10 , each board 4 includes two supporting structures 41 , two SMC sheets 42 , two hollow tubes 43 and a foam structure 44 . The two supporting structures 41 are the main supporting structures of the board body 4 , and in practical applications, each supporting structure 41 may be, for example, wood, steel and other structures. Two support structures 41 are such as rectangular column structures, wherein one SMC sheet body 42 is fixed on one side of two support structures 41, and another SMC sheet body 42 is fixed on the other side of two support structures 41, and two The SMC sheet 42 and the two supporting structures 41 jointly form an accommodating space 45 . Wherein, the SMC sheet 42 refers to a sheet structure made of glass fiber reinforced thermosetting plastic sheet molding material (Sheet Molding Compound, SMC).

The hollow tube body 43 is fixedly disposed on one side of the supporting structure 41 , and the hollow tube body 43 is located in the accommodating space 45 . In practical applications, the hollow tube body 43 is, for example, a square column or cylindrical plastic tube, steel tube, etc., which is not limited here. The hollow tube body 43 can be fixed to the supporting structure 41 by glue, for example, but it is not limited thereto. The foam structure 44 is disposed in the accommodation space 45 . The foam structure 44 is, for example, formed by pouring PU foam material into the accommodating space 45 and then solidified, and the two support structures 41 and the two SMC sheets 42 can be fixed to each other by the foam structure 44 .

The hollow tube body 43 includes a hollow channel 431 and at least one through hole 432 , and the through hole 432 is disposed through the hollow tube body 43 . One of the SMC sheets 42 includes at least one assembly hole 421, the assembly hole 421 is arranged through the SMC sheet 42, and each assembly hole 421 is arranged facing the perforation 432, and the hollow channel 431 can communicate with the outside through the assembly hole 421.

As shown in Figures 11 to 12, one of the perforations 432 and the corresponding assembly hole 421 of the hollow pipe body 43 of one of the boards 4 of the wall structure can communicate with the interlayer space SP1 and be located on the interlayer Relevant lines (such as various wires, network lines, etc.) or pipelines in space SP1 (such as various power pipes, water pipes, etc.), can enter the corresponding hollow channel 431 through the perforation 432 of one of the boards 4 of the wall structure and the corresponding assembly hole 421 .

Similarly, as the perforation 432 of the hollow pipe body 43 of one of the panels 4 of the roof structure A2 and the corresponding assembly hole 421, it can communicate with the interlayer space SP1 and be located in one of the panels 4 of the roof structure A2. The relevant lines (such as various electric wires, network lines, etc.) or pipelines (such as various power pipes, water pipes, etc.) in the hollow channel 431 of the hollow channel can enter one of the boards 4 as the wall structure through the interlayer space SP1 In the hollow channel 431 of.

As shown in Figure 11 and Figure 13, another perforation 432 and the corresponding assembly hole 421 of the hollow pipe body 43 of one of the boards 4 as the wall structure can communicate with the outside and be located on the board 4 The relevant lines in the hollow channel 431 can pass through the outside of the house, thereby electrically connecting with the electric energy storage device 8 located outside the house.

As shown in Figure 11 and Figure 14, one of the perforations 432 and the corresponding assembly hole 421 of the hollow pipe 43 of one of the panels 4 of the roof structure A2 can communicate with the outside, and the solar device 7 The relevant electric wires E included in the circuit device 72 can enter the corresponding hollow channel 431 through the assembly hole 421 and the through hole 432 of one of the boards 4 of the roof structure A2.

As shown in Fig. 11 and Fig. 14, the mounting hole 421 and the through hole 432 included in one of the boards 4 as the wall structure can also be used to install a socket F, and the electric wire E connected with the socket F, then The interlayer space SP1 can be entered through the hollow channel 431 as the wall structure, another through hole 432 and the assembly hole 421 of the board body 4 .

According to the above, as shown in Figure 11 to Figure 14, by making each plate body 4 have the design of hollow pipe body 43, hollow channel 431, perforation 432, assembly hole 421, and cooperate with the design of interlayer space SP1, it is arranged in The relevant electric wires that the solar device 7 of the roof structure A2 comprises and the electric wires that are arranged on each socket F connected indoors can pass through the assembly holes 421, the perforations 432 and the hollow passages 431 of a plurality of panels 4, and be arranged outside the house. The electrical energy storage device 8 is connected.

In the existing common container houses, the relevant lines (such as various electric wires, network lines, etc.) and pipelines (such as various water pipes, power pipes, etc.) contained in the interior are all exposed. Such a design is unsightly. And the problem that lines and pipelines are easily damaged. On the other hand, the foldable modular house A of this creation, through the design of each board body 4 including the hollow pipe body 43, and the design of the mezzanine space SP1, can prevent the relevant lines and pipelines from being exposed in the indoor space SP2, thereby solving the problem. The existing problems of the above-mentioned conventional container houses.

The existing common container houses use metal corrugated boards as the roof and walls, so there are problems of cold in winter and hot in summer and poor sound insulation, and the overall structure is heavy and difficult to carry. On the other hand, in the foldable modular house A of this creation, each panel body 4 is mainly composed of SMC sheet body 42 and foam structure 44, and cooperates with the design of the plastic steel door 5 and plastic steel window 6, so that the foldable modular house A can The whole has relatively light weight, and compared with conventional container houses, especially conventional container houses, it has better sound insulation effect and better heat insulation.

Please refer to Fig. 12 and Fig. 13 again. It is worth mentioning that in practical applications, each upper frame body 11 may include a groove 111, and the two side walls forming the groove 111 have a convex structure 112 respectively. The frame body 12 includes a protruding structure 121 , and a top wall of the protruding structure 121 has a lower glue groove 122 . One upper end of each panel 4 as a wall structure is fixedly arranged in the groove 111, and the upper end of the panel 4 has two glue grooves 424, and the two convex structures 112 are correspondingly engaged with the two glue grooves 424 Among them, there is an upper waterproof glue structure B1 between each glue groove 424 and the corresponding convex structure 112. The lower end of the board body 4 has an engaging groove 46, and the engaging groove 46 and the protruding structure 121 are mutually engaged. Close, and between the lower glue groove 122 and the board body 4, a waterproof glue structure B2 is provided.

Through the design of the groove 111 of the upper frame body 11, the protruding structure 121 of the lower frame body 12, and the engaging groove 46 of the board body 4, relevant personnel can easily install the board body 4, and through the raised structure 112, the upper The designs of the glue groove 424, the upper waterproof glue structure B1, the lower glue groove 122 and the lower waterproof glue structure B2 can effectively prevent external liquid from entering the indoor space.

In practical applications, the size of the groove 111 can be slightly smaller than the size of the upper end of the board body 4, and the size of the engaging groove 46 can be slightly smaller than the size of the protruding structure 121, while the upper end and the lower end of the board body 4 can be tightly It is mutually fixed with the upper frame body 11 and the lower frame body 12 .

Please refer to FIG. 8 and FIG. 15 together. FIG. 15 is another schematic cross-sectional view of the foldable combined house created by the present invention. One end of one of the hollow pipes 43 as a wall structure may also include an inclined end wall 434, and the hollow pipe 43 has a drainage perforation 435 adjacent to the inclined end wall 434, and the drainage perforation 435 runs through the hollow pipe. 43. One of the SMC sheets 42 of one of the boards 4 of the wall structure may have an outdoor drainage hole 422 , and the outdoor drainage hole 422 is arranged facing the drainage perforation 435 . The roof structure A2 is obliquely fixed to the main frame body 1 , and part of the upper frame body 11 of the main frame body 1 further includes a guiding slope 113 and a drainage hole 114 , and the drainage hole 114 runs through the main frame body 1 . An outer surface A23 of the roof structure A2 and the guide slope 113 are used to guide the liquid (such as rainwater) falling on the roof structure A2 into the drainage hole 114 . The inclined end wall 434 , the drainage perforation 435 and the outdoor drainage hole 422 are used to guide the liquid in the hollow tube body 43 to drain out of the plate body 4 . In practical applications, the board body 4 with the outdoor drain hole 422 may also be provided with a drain pipe G. As shown in FIG. Through the above design, the foldable composite house A does not need to design additional drainage components, and the overall appearance of the foldable composite house A can be simpler.

It should be noted that the hollow pipe body 43 used to lead the liquid falling on the roof structure A2 to the outside is two different hollow pipe bodies 43 from the aforementioned hollow pipe body 43 used to accommodate electric wires. , in practical applications, the two hollow tube bodies 43 may belong to different plate bodies 4 .

Please refer to Figure 10, Figure 16 to Figure 18 together, Figure 16 is a top view schematic diagram of the interconnection of the two boards of the foldable composite house created by this creation, Figure 17 is a partially enlarged schematic diagram of Figure 16, and Figure 18 is a schematic diagram of this creation An exploded schematic diagram of one end of the two boards of one embodiment of the foldable modular house.

As shown in Fig. 10, Fig. 16 and Fig. 17, in practical application, the two opposite wide sides of each supporting structure 41 of each plate body 4 can be concavely formed with an assembly groove 411 respectively, and each SMC sheet body 42 may include a main body 425 and two extension structures 426, the main body 425 The two opposite sides extend outward to form two extension structures 426 , and the two extension structures 426 of each SMC sheet 42 are fixed to one assembly groove 411 respectively included in the two support structures 41 . Wherein, each extension structure 426 may also be connected to the assembly groove 411 by glue. With such a design, in the process of manufacturing the plate body 4, the two SMC sheets 42 and the two support structures 41 can be fixed to each other to form the accommodation space 45, and then the hollow pipe body 43 is arranged in the accommodation space. After entering the space 45 , the foam material can be poured into the accommodating space 45 .

It is worth mentioning that, in practical applications, one of the supporting structures 41 of part of the board body 4 may include a support portion 412, a side strip portion 413 and a connecting portion 414, the support portion 412 is located in the board body 4, and the support portion 412 is connected to the edge part 413 , a part of the edge part 413 is exposed on one side of the plate body 4 , and the support part 412 and the edge part 413 are connected by the connection part 414 . Wherein, the thickness of the supporting part 412 is greater than the thickness of the connecting part 414, the thickness of the edge part 413 is greater than the thickness of the connecting part 414, and the supporting part 412, the connecting part 414 and the edge part 413 jointly form two assembly grooves 411, And a narrow side 4131 of the edge part 413 is flush with a wide side 4251 of each SMC sheet 42 .

As shown in Figure 10, Figure 16 and Figure 17, in practical applications, the opposite sides of each plate body 4 are respectively defined as a first side 4A and a second side 4B, and the plate body 4 is on the first side 4A The thickness D1 of the board body 4 is greater than the thickness D2 of the second side 4B of the board body 4, and the supporting structure 41 of the board body 4 on the first side 4A may have an engaging groove 415, and the engaging groove 415 can accommodate the second side of another board body 4. The two sides 4B are designed in such a way that the two boards 4 can engage with each other. A plurality of plates 4 engaged with each other can be used as a wall structure, a roof structure A2 or a floor structure A3.

As shown in Figure 18, in a preferred embodiment, in the process of assembling the two boards 4, the waterproof adhesive tape C may be pasted on the second side 4B of one of the boards 4, and on the other The two corners of the engagement groove 415 of the board body 4 are injected with waterproof glue B3, and then, one end of the board body 4 pasted with the waterproof adhesive tape C is snapped into the engagement groove 415 of the other board body 4, and the waterproof glue B3 is applied. After the B3 is solidified into a waterproof glue structure, the assembly of the two boards 4 can be completed. Through the design of the waterproof adhesive tape C and the waterproof adhesive structure, etc., the external rainwater can be effectively prevented from entering the indoor space through the position where the two boards 4 are connected.

As shown in Figures 10 and 16, in a preferred embodiment, each plate body 4 has a molding section 4C on the first side 4A, and each SMC sheet body 42 of the plate body 4 also includes a plurality of decorative parts 423 , the SMC sheet 42 has at least one decorative portion 423 between the first side 4A and the second side 4B. The appearance of the plate body 4 in the shape section 4C is the same as the shape of the plate body 4 in each decorative part 423, and the distance L1 between the shape section 4C and the adjacent decorative part 423 is the same as that between any two decorative parts 423. The distance L2 between them is the same. With this design, each wall structure of the foldable prefabricated house A will present an appearance similar to a corrugated board.

Please refer to FIG. 19 and FIG. 20 , which are schematic diagrams of disassembly and assembly of two boards of one embodiment of the foldable combined house of the present invention, respectively. The difference between this embodiment and the previous embodiments lies in that: a first auxiliary engaging structure 91 and a second auxiliary engaging structure 92 may be respectively provided on opposite sides of a part of the plate body 4 . The first auxiliary engaging structure 91 and the second auxiliary engaging structure 92, for example, can be mutually fixed with the adjacent support structure 41, and a part of the two SMC sheets 42 can be a part of the first auxiliary engaging structure 91 and the shielding. A part of the second auxiliary engaging structure 92 .

The two adjacent plates 4 can be fixed to each other through the first auxiliary engaging structure 91 and the second auxiliary engaging structure 92, and the first auxiliary engaging structure 91 and the second auxiliary engaging structure 92 are not locked together. exposed outside the two boards 4 . The appearance of the first auxiliary engaging structure 91 and the second auxiliary engaging structure 92 is not limited to those shown in the figure, as long as the first auxiliary engaging structure 91 and the second auxiliary engaging structure 92 can engage with each other, the other The appearance can be changed according to the needs. By making the two plates 4 use the design of the first auxiliary engaging structure 91 and the second auxiliary engaging structure 92 to engage with each other, relevant personnel can use different materials to manufacture the supporting structure 41 and the first auxiliary engaging structure according to actual needs. Engagement structure 91 .

Please refer to FIG. 21 and FIG. 22 , which are schematic diagrams of disassembly and assembly of two boards of one embodiment of the foldable composite house created by the present invention, respectively. The biggest difference between this embodiment and the previous embodiment is that the two SMC sheets 42 of part of the board body 4 jointly form an engaging groove 42A on one side of the board body 4, and the two SMC sheet bodies 42 are placed on the board body. On the other side of 4, an engaging structure 42B is formed. The engaging structure 42B of any board 4 can be engaged in the engaging groove 42A of the other board 4 . Since the SMC sheet body 42 is made by a mould, the plate body 4 mentioned in this embodiment can form related structures together during the process of manufacturing the SMC sheet body 42 , and the SMC sheet body 42 does not require additional processing.

Please refer to FIG. 23 and FIG. 24 together. FIG. 23 is a schematic diagram of the combination of two panels of one embodiment of the foldable combined house created by the present invention, and FIG. 24 is a partially enlarged schematic diagram of FIG. 23 . The biggest difference between this embodiment and the aforementioned embodiments shown in FIG. 16 and FIG. 17 is that: the board body 4 of this embodiment further includes an auxiliary supporting structure 47 and a reinforcing component 48 . The auxiliary support structure 47 is disposed on one side of the hollow tube body 43 , and the auxiliary support structure 47 is located between the two SMC sheets 42 , and the hollow tube body 43 is located between the support structure 41 and the auxiliary support structure 47 . The auxiliary supporting structure 47 is located between the foam structure 44 and the hollow tube 43 .

The reinforcing component 48 may include a fixing piece 481 and a plurality of locking pieces 482 , the fixing piece 481 is fixed on the side of the auxiliary support structure 47 opposite to the hollow tube 43 through the fixing pieces 482 . In practical applications, the auxiliary supporting structure 47 is wood, the fixing piece 481 is metal, the locking member 482 is a screw, and the reinforcement component 48 is mainly used to strengthen the structural strength of the auxiliary supporting structure 47 . Through the design of the auxiliary support structure 47 and the reinforcement component 48, the overall structural strength of the board body 4 can be enhanced.

Please refer to Fig. 25 to Fig. 31 together. Fig. 24 and Fig. 25 are schematic diagrams of the third embodiment of the foldable combined house in the folded state in different perspectives, and Fig. 26 to Fig. 30 are respectively the foldable combination of the present creation The action schematic diagram of the third embodiment of the house transforming from the folded state to the ready house state.

The biggest difference between this embodiment and the aforementioned first embodiment lies in the different folding methods of the foldable prefabricated house. In the following description, the pivotal connection between the various components may be achieved by, for example, components such as hinges, but it is not limited thereto.

The foldable composite house H of this embodiment includes: a wall group H1, a roof structure H2, a floor structure H3, multiple plastic-steel doors H4, multiple plastic-steel windows H5 and two auxiliary components H6. The wall group H1, roof structure H2, and floor structure H3 referred to in this embodiment may be the same as the previous embodiments, including a frame and a plurality of boards, and the internal components of each board may be the same as the previous embodiments. The plastic-steel door H4 and the plastic-steel window H5 referred to in this embodiment are the same as those in the foregoing embodiments, and will not be repeated here.

The wall group H1 includes multiple wall structures, wherein two wall structures are defined as two side wall structures H11 and H12, and the other two wall structures are defined as two end wall structures H13 and H14. Two ends of the end wall structures H13, H14 and one of the side wall structures H12 are pivotally connected to each other, and each end wall structure H13, H14 can rotate relative to the side wall structure H12 to which it is pivotally connected.

The roof structure H2 comprises two roof elements H21 which are pivotally connected to each other. One of the roof components H21 is pivotally connected to one of the side wall structures H11, and the other roof component H21 is pivotally connected to the other side wall structure H12.

The floor structure H3 includes three floor components H31, H32, H33, the three floor components H31, H32, H33 are pivotally connected to each other, and any one of the floor components can rotate relative to another adjacent floor component. The long sides of the respective floor members H31, H32, H33 are equal in length. The short sides of the respective floor members H31, H32, H33 are unequal in length. One of the floor components H31 is connected to one of the side wall structures H11. In practical applications, the floor component H31 and the side wall structure H11 may be non-rotatably connected. In this embodiment, the floor structure H3 has three floor components H31, H32, and H33 as an example, but the number of floor components included in the floor structure H3 is not limited to three. In different embodiments, The floor structure H3 may consist of only two floor elements, or more than four floor elements.

As shown in FIGS. 26 to 28 , two auxiliary components H6 may be fixed at both ends of one of the side wall structures H12 . Each auxiliary component H6 includes a frame H61 and a plurality of rollers H62. The two frame bodies H61 included in the two auxiliary components H6 are detachably (for example, using screws) arranged at both ends of one of the side wall structures H12, each frame body H61 is connected with a plurality of rollers H62, and each frame body H61 It can slide on the ground through multiple rollers H62. Two auxiliary components H6 It is mainly used to push and pull the relevant assembly personnel, and the relevant assembly personnel can relatively easily drive one of the side wall structures H12 to move away from the other side wall structure H11 by pushing and pulling the two auxiliary components H6. The size and appearance of the frame body H61 of each auxiliary component H6 can be designed according to requirements, and the figure shown is only one example.

The foldable modular house H can be operated to convert from a folded state (as shown in Figure 26 and Figure 27 ) to a finished house state (as shown in Figure 25 ). The foldable modular house H is transported in a folded state, and when the foldable modular house H is in the folded state, two auxiliary components H6 are fixedly arranged at both ends of one of the side wall structures H12. During the process of assembling the foldable prefabricated house H by relevant assemblers, the two auxiliary components H6 will be disassembled, and the foldable prefabricated house H does not include the two auxiliary components H6 when it is in the completed state.

As shown in Figures 27 to 29, when the foldable modular house H is in the folded state, the outer wide sides H212 of the two roof members H21 abut against each other, and the inner wide side H211 of one roof member H21 abuts against one of the sides The inner broadside H111 of the wall structure H11, the inner broadside H211 of the other roof member H21 abuts against the inner broadside H121 of the other side wall structure H12, the outer broadsides H132, H142 of the two end wall structures H13, H14 ( 31) abuts against the outer wide side H122 of one of the side wall structures H12. When the foldable modular house H is in the folded state, the floor component H31 connected to the side wall structure H11 is located on one side of the two side wall structures H11, H12, the two roof components H21 and the two end wall structures H13, H14 . The inner broadside H321 of the floor element H32 is arranged facing the inner broadsides H131 , H141 of the two end wall structures H13 , H14 . The outer wide side H332 of the floor member H33 is disposed facing the outer wide side H322 of the floor member H32.

As shown in Fig. 27 and Fig. 28, when the foldable prefabricated house H is in the folded state, the relevant assembly personnel may first use relevant equipment (such as a crane) to fold the three floor components H31, H32, H33 It is unfolded so that the inner wide sides H311, H321, H331 of the three floor members H31, H32, H33 are flush with each other.

Next, as shown in Fig. 28 to Fig. 30, two relevant assemblers can push and pull the two auxiliary components H6 respectively, so that each frame body H61 drives one of the side wall structures H12 through the plurality of rollers H62 connected thereto, Move away from the other side wall structure H11 until the two roof members H21 are transformed from the folded state (as shown in FIG. 28 ) to the unfolded state (as shown in FIG. 30 ). When the two roof components H21 are unfolded, the inner wide sides H211 of the two roof components H21 are flush, and the outer wide sides H212 of the two roof components H21 are also flush.

As shown in Figure 30, when two assemblers use two auxiliary components H6 to move one of the side wall structures H12 to one side of the floor component H33 and convert the two roof components H21 to the unfolded state, the relevant assemblers It may be to use relevant fixing components (such as screws, nuts, etc.) to fix the floor component H33 and the side wall structure H12 to each other, and the relevant assemblers may use relevant fixing components (such as screws, nuts, etc.) to make the two roofs The members H21 are fixed to each other.

As shown in Figure 30 and Figure 31, after the relevant assembling personnel fix the floor component H33 and the side wall structure H12 to each other, and fix the two roof components H21 to each other, the relevant assembling personnel can remove the two auxiliary components H6, and then, Relevant assemblers can continuously rotate the two end wall structures H13, H14 relative to the side wall structure H12, so that the inner wide sides H131, H141 of the two end wall structures H13, H14 face each other. Finally, after the relevant assemblers fix each end wall structure H13, H14 and adjacent floor components H31, H32, H33, roof component H21 and side wall structures H11, H12 to each other, the foldable modular house H can be assembled into a finished product. house status.

When the foldable modular house H is in the completed state, two side wall structures H11, H12, two end wall structures H13, H14, multiple floor components H31, H32, H33 and two roof components H21 together form an indoor space, The outer wide side H212 of each roof member H21, the outer wide side H132, H142 of each end wall structure H13, H14, and the outer wide side H112, H122 of each side wall structure H11, H12 are all located outside the interior space; each roof member H21 Inner wide side H211, inner wide side H111, H121 of each side wall structure H11, H12, inner wide side of end wall structure H13, H14 The surfaces H131, H141 and the inner wide sides H311, H321, H331 of the respective floor members H31, H32, H33 are located in the indoor space.

To sum up, compared with the traditional container house, the foldable modular house of this creation has the technical effect of better heat insulation and sound insulation, and the overall weight of the foldable modular house of this creation is lower than that of the traditional container house Lightweight, and the folding modular house of this creation is easy to carry.

The above is only the preferred feasible embodiment of this creation, and does not limit the patent scope of this creation. Therefore, all equivalent technical changes made by using the instructions and drawings of this creation are included in the protection scope of this creation. .

A: Foldable combined house

A11: Side wall structure

A112: inner wide side

A13: End wall structure

A2: Roof structure

A21: First roof component

A22: Second roof member

A213: Outer wide side

A223: Outer wide side

A3: Floor structure

A31: Floor components

A32: Floor components

Claims (13)

A foldable composite house, which includes: a wall group, which includes a plurality of wall structures, wherein two of the wall structures are defined as two side wall structures, and the other two of the wall structures are defined as two end wall structures; each of said end wall structures is pivotally connected to one of said side wall structures, and each of said end wall structures can rotate relative to said side wall structure to which it is pivotally connected; a roof structure comprising A first roof component and a second roof component, the long side of the first roof component is equal to the long side of the second roof component, and the short side of the first roof component is smaller than the second roof component The short side of the first roof component is connected to one of the side wall structures, the first roof component and the second roof component are pivotally connected to each other, and the second roof component can be relative to the first roof component a roof member rotates; a floor structure comprises two floor members pivotally connected to each other; one of the floor members is pivotally connected to one of the side wall structures, and the other of the floor members It is pivotally connected with another side wall structure; at least one plastic steel door is arranged on at least one of the side wall structure and the end wall structure; at least one plastic steel window is arranged on the side wall structure and the end wall structure At least one of the end wall structures; wherein, the foldable combined house can be operated and converted from a folded state to a ready-made state; when the foldable combined house is in the folded state, the two The outer wide sides of the floor members abut against each other, the inner wide side of one of the floor members abuts against the inner wide side of one of the side wall structures, and the inner wide side of the other floor member abuts against the other the inner broadside of one of said side wall structures, the outer broadside of each of said end wall structures The surface is against the outer wide side of one of the side wall structures, and the inner wide side of the second roof member is against the inner wide side of the two end wall structures; wherein, the foldable composite house is In the house state, the two side wall structures, the two end wall structures, the first roof component, the second roof component and the two floor components together form an indoor space, each The outer wide sides of the floor components, the outer wide sides of each of the end wall structures, and the outer wide sides of each of the side wall structures are located outside the indoor space; the inner wide sides of each of the floor components, each of the side wall structures The inner wide sides of the side wall structure, the inner wide side of the end wall structure and the inner wide side of the second roof element are all located in the interior space. The foldable combined house according to claim 1, wherein the foldable combined house further comprises: a solar device installed on the roof structure; an electric energy storage device used to store the energy generated by the solar device the electric energy, the electric energy storage device is electrically connected to the solar device through a plurality of wires; a plurality of boards, each of the wall structure, the first roof component, the second roof component and each of the The floor component comprises at least one said plate respectively; each said plate comprises: at least two support structures; a foam structure; two SMC sheet bodies, which are mutually fixed with the two support structures, two The SMC sheet and the two supporting structures jointly form an accommodating space, and the foam structure is arranged in the accommodating space; at least one hollow pipe body is fixedly arranged on one of the supporting structures. One side of the structure, the hollow pipe body is located in the accommodating space, and the hollow The pipe body includes a hollow passage; wherein, a fitting hole, a perforation, and the hollow passage as one of the panels of the roof structure, and a fitting hole as one of the panels of the wall structure Assembling holes, a perforation and the hollow channel are perforated with a plurality of the electric wires; each of the assembling holes is provided through one of the SMC sheets, and each of the perforations is disposed through one of the hollow tubes set up. The foldable combined house as described in claim 2, wherein, each of the supporting structures has an assembly groove on opposite sides of each other, and each of the SMC sheets includes a main body and two extension structures. The opposite sides of the body extend outward to form two extension structures, and the two extension structures of each of the SMC sheets are fixed to one of the assembly grooves respectively contained in the two support structures. . The foldable composite house according to claim 3, wherein, one of the supporting structures of part of the board body includes a support part, a side strip part and a connecting part, and the support part is located in the board body, The support part is connected to the edge part through the connection part, a part of the edge part is exposed on one side of the board body, and the support part, the connection part and the The thicknesses of the edge strips are different from each other, and the supporting portion, the connecting portion and the edge strips together form two assembly grooves; wherein, a narrow side of each edge strip is adjacent to each other. A broad side of each of the SMC sheets is flush. The foldable combined house according to claim 2, wherein the opposite sides of each of the boards are respectively defined as a first side and a second side, and the thickness of the boards on the first side is greater than the thickness of the board on the second side, the supporting structure of the board on the first side has an engaging groove, and the engaging groove can accommodate another of the board said second side; wherein, said The board body is also provided with a waterproof adhesive tape on the second side, and there is a waterproof adhesive structure between the two board bodies engaged with each other. The foldable combined house according to claim 5, wherein each of the boards has a molding section on the first side, and each of the SMC sheets of the boards also includes a plurality of decorative parts, Each of the SMC sheets has at least one decorative part between the first side and the second side; wherein, the shape of the board in the molding section is the same as that of the board in Each of the decorative parts has the same appearance, and the distance between the shape section and the adjacent decorative part is the same as the distance between any two decorative parts. The foldable combined house according to claim 2, wherein a first auxiliary snapping structure and a second auxiliary snapping structure are respectively provided on opposite sides of each of the boards, and the first auxiliary snapping The structure is fixed to one of the supporting structures, and the second auxiliary engaging structure is fixed to the other supporting structure; the first auxiliary engaging structure of each of the boards can be connected to the other supporting structure. The second auxiliary engaging structures of the boards are engaged with each other; the two SMC sheets of each of the boards cover a part of the first auxiliary engaging structure and a part of the second auxiliary engaging structure , and the first auxiliary engaging structure and the second auxiliary engaging structure engaged with each other are not exposed outside the two boards. The foldable combined house as described in claim 2, wherein the opposite sides of each of the boards are respectively defined as a first side and a second side, and the two SMC sheets of each of the boards body, an engaging groove is jointly formed on the first side, the thickness of each of the plate bodies on the second side is smaller than the width of the engaging groove, and the second side of each of the plate bodies can is engaged in the engaging groove of the other plate body. The foldable combined house as described in claim 2, wherein each of the side wall junctions The periphery of the structure, the periphery of each of the end wall structures, the periphery of the first roof member, the periphery of the second roof member and the periphery of each of the floor members all have a plurality of frames, and all the frames The bodies together form a main frame body, and the main frame body is divided into a plurality of upper frame bodies and a plurality of lower frame bodies. Each of the upper frame bodies includes a groove, and the two side walls forming the groove respectively have a convex Strip structure, each of the lower frames includes a protruding structure, a top wall of the protruding structure has a lower glue groove; an upper end of each of the boards as the wall structure is fixedly arranged in the concave groove, and the board has two gluing grooves at the upper end, and the two convex strip structures are correspondingly engaged in the two gluing grooves, and each of the gluing grooves and the corresponding An upper waterproof glue structure is arranged between the convex strip structures, and the lower end of the board body has an engaging groove, and the engaging groove and the protruding structure are engaged with each other, and the lower glue groove and the A waterproof glue structure is arranged between the boards. The foldable combined house according to claim 9, wherein the foldable combined house further comprises a plurality of ceiling bodies, and the plurality of ceiling bodies are fixedly arranged on the main frame body, and the main frame body and multiple The two ceiling bodies together form a mezzanine space and an indoor space, and the indoor space is used to provide user activities; one of the assembly holes and the corresponding one of the boards included in one of the wall structures The corresponding perforation is communicated with the interlayer space; one of the assembly holes and the corresponding perforation included in the panel as one of the roof structures are communicated with the interlayer space , and the interlayer space can accommodate multiple wires. The foldable combined house according to claim 9, wherein one end of the hollow pipe body of the board body as one of the wall structures includes an inclined end wall, and the hollow pipe body has A drainage perforation, the drainage perforation runs through the hollow pipe body, the SMC sheet has an outdoor drainage hole, and the outdoor drainage hole is arranged facing the drainage perforation; the roof structure is inclined fixed on the main frame body, and the main frame body includes a guide slope and a drain hole, the drain hole runs through the main frame body; the roof structure and the guide slope can guide the falling The liquid in the roof structure enters the drainage hole; the inclined end wall, the drainage perforation and the outdoor drainage hole are used to guide the liquid in the hollow pipe body to drain out of the plate body. A foldable composite house, which includes: a wall group, which includes a plurality of wall structures, wherein two of the wall structures are defined as two side wall structures, and the other two of the wall structures are defined as two end wall structures; each of said end wall structures is pivotally connected to one of said side wall structures, and each of said end wall structures can rotate relative to said side wall structure to which it is pivotally connected; a roof structure comprising Two roof members, the two roof members are pivotally connected to each other; one of the roof members is pivotally connected to one of the side wall structures, and the other of the roof members is pivotally connected to the other side wall structure a floor structure, which includes a plurality of floor components, a plurality of said floor components are pivotally connected to each other, and any one of said floor components can rotate relative to another adjacent floor component, and each of said floor components The long sides are equal in length, wherein one of the floor components is connected to one of the side wall structures; at least one plastic steel door is arranged on at least one of the side wall structure and the end wall structure; at least one plastic steel window is It is arranged on at least one of the side wall structure and the end wall structure; wherein, the foldable combined house can be operated and converted from a folded state to a finished house state; the foldable combined house is the In the folded state, the outer wide sides of the two roof members abut against each other, and the inner wide side of one of the roof members abuts against the inner side of one of the side wall structures. wide side, the inner wide side of another said roof member abuts against the inner wide side of the other said side wall structure, and the outer wide side of each said end wall structure abuts against the outer wide side of one of said side wall structures. On the wide side, the floor member connected to one of the side wall structures is located on one side of two of the side wall structures, two of the roof members and two of the end wall structures, and the other of the floor The inner surfaces of the components are set facing the inner surfaces of the two end wall structures; wherein, when the foldable composite house is in the completed state, the two side wall structures, the two end wall structures, A plurality of said floor components and two said roof components jointly constitute an indoor space, the outer wide sides of each of said roof components, the outer wide sides of each of said end wall structures and the outer wide sides of each of said side wall structures are located outside the interior space; the inner wide sides of each of the roof elements, the inner wide sides of each of the side wall structures, the inner wide sides of the end wall structures, and the inner wide sides of each of the floor elements, located in the interior space. The foldable composite house according to claim 12, wherein the foldable composite house further comprises two auxiliary components, each of which comprises a frame body and a plurality of rollers, and the two auxiliary components comprise The two frames are detachably arranged at both ends of one of the side wall structures, and each frame is connected to a plurality of rollers, and each frame can pass through a plurality of rollers on the ground. Sliding upward; the side wall structure connected with the two auxiliary components can move away from the other auxiliary component along with the two auxiliary components, so that the two roof components can be folded from each other The state transitions to the expanded state.

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