CN218521966U - Energy-conserving assembled cabin of aerogel - Google Patents

Abstract

The utility model discloses an aerogel energy-saving assembled cabin, which comprises four angle steel stand columns 3, wherein a top plate corner fitting 4 is fixedly installed at the top end of each angle steel stand column 3, and a bottom plate corner fitting 5 is installed at the bottom end of each angle steel stand column 3; a section top beam 6 is welded between every two top plate corner pieces 4, and a section bottom beam 7 is welded between every two bottom plate corner pieces 5; to form a frame structure of the cabin. The aerogel composite color steel plates 13 are arranged between the profile top beam 6 and the profile bottom beam 7 after being spliced into a wall body, and the corresponding aerogel composite color steel plates 13 are provided with doors 16 and windows 17. Install photovoltaic support 1 on four roof corner fittings 4 jointly, arranged photovoltaic board 2 on the photovoltaic support 1. The utility model relates to a rationally, fine practical application is worth having.

Description

Energy-conserving assembled cabin of aerogel

Technical Field

The utility model belongs to the technical field of integrated house, a modularization integrated housing construction is related to, specifically is an energy-conserving assembled cabin of aerogel.

Background

At present, the wallboard of the integrated house mainly uses a rock wool board, the energy supply mainly uses commercial power, and various problems exist; the rock wool board has high water absorption rate, water is easy to accumulate in the rock wool board, the weight is increased for a long time, the mould is mildewed and shed, the repair rate is high, and the rock wool board can generate fibrous substances in the production process and after being used for 3 to 5 years, belongs to carcinogenic substances and has great harm to human bodies; the energy adopts the commercial power, has restricted the application range and the scene of integrated house, needs cable external power supply, has the potential safety hazard.

The aerogel zero-carbon cabin can effectively solve the problems, is mainly applied to engineering offices, worker dormitories, restaurants, warehouses and the like for short-term use, can be detached and moved for multiple times, and can also be applied to earthquake relief work, epidemic prevention settling rooms, large-scale public movable rooms, tourist scenic spot villas and the like.

Disclosure of Invention

The utility model aims at providing a novel energy-conserving assembled cabin of aerogel, solve current integrated house assembly complicated, application range is limited, the unsafe technical problem of waiting of power consumption.

The utility model discloses an adopt following technical scheme to realize:

an aerogel energy-saving assembled cabin comprises four angle steel stand columns, wherein a top plate corner piece is fixedly installed at the top end of each angle steel stand column, and a bottom plate corner piece is installed at the bottom end of each angle steel stand column; the top beam of the section is welded between every two top plate corner pieces, and the bottom beam of the section is welded between every two bottom plate corner pieces.

The top plate corner piece comprises two side plates I which are arranged in a right-angled mode, the horizontal folded edges at the bottoms of the two side plates I form a right-angled bottom surface I together, and the upward vertical folded edge of the right-angled bottom surface I forms a lower right-angled folded edge I; the horizontal folded edges at the tops of the two side plates I form a right-angle top surface I together, and the downward vertical folded edges of the right-angle top surface I form an upper right-angle folded edge I; a horizontal supporting plate is arranged between the middle parts of the two side plates I, an inner vertical plate is arranged on the inner side edge of the horizontal supporting plate, baffle plates are arranged between the two side edges of the inner vertical plate and the corresponding side edges of the horizontal supporting plate and the corresponding side edges of the side plates I respectively, and the two baffle plates are vertically arranged; the upper end of the inner vertical plate is inwards provided with a right-angle flanging; and a downpipe socket is formed in the middle of the horizontal supporting plate.

The section shape of the section bar top beam is as follows: including the back timber side, this back timber side lower extreme forms horizontal limit under the back timber and vertical limit under the back timber in proper order, and this back timber side upper end forms horizontal minor face on the back timber, back timber bevel edge on, the long limit of the horizontal on the back timber, vertical limit and back timber turn-ups on the back timber in proper order.

The right angle bottom surface I of roof corner fittings passes through the bolt and installs in angle steel stand top, the roof corner fittings is connected terminal surface welding section bar back timber, promptly: the back timber side welds with curb plate I, and horizontal limit under the back timber, vertical limit under the back timber respectively with right angle bottom surface I, down right angle turn-ups I welding, the horizontal minor face welds with the baffle side on the back timber, the long limit of the back timber upper level welds with the horizontal limit of baffle, vertical limit on the back timber, the back timber on the turn-ups respectively with the side and the right angle turn-ups welding of interior riser.

The bottom plate corner piece comprises two side plates II which are arranged in a right-angle mode, the horizontal folded edges at the bottoms of the two side plates II form a right-angle bottom surface II together, and the upward vertical folded edge of the right-angle bottom surface II forms a lower right-angle folded edge II; a downpipe limiting frame is arranged outside the lower right-angle flanging II; the horizontal folded edges at the tops of the two side plates II form a right-angle top surface II together, and the downward vertical folded edges of the right-angle top surface II form an upper right-angle folded edge II.

The section shape of the section bar bottom beam is as follows: the bottom beam side edge structure comprises a bottom beam side edge, wherein the lower end of the bottom beam side edge sequentially forms a bottom beam lower horizontal edge and a bottom beam lower vertical edge, and the upper end of the bottom beam side edge sequentially forms a bottom beam upper horizontal edge and a bottom beam upper vertical edge.

The right-angle top surface II of the bottom plate corner piece is arranged at the bottom end of the angle steel upright post through a bolt; the end face welding section bar bottom beam is connected to the bottom plate corner fittings, namely: the bottom beam side is welded with the side plate II, the upper horizontal edge of the bottom beam and the upper vertical edge of the bottom beam are respectively welded with the right-angle top surface II and the upper right-angle flanging II, and the lower horizontal edge of the bottom beam and the lower vertical edge of the bottom beam are respectively welded with the right-angle bottom surface II and the lower right-angle flanging II.

A wall body formed by splicing aerogel composite color steel plates is assembled between the corresponding profile top beam and the profile bottom beam, the upper ends of the aerogel composite color steel plates are assembled on the lower vertical edge of the top beam of the profile top beam through screws, the lower ends of the aerogel composite color steel plates are inserted into a geosyncline in a matching manner, and the side edges of the geosyncline are assembled on the upper vertical edge of the bottom beam of the profile bottom beam; a bottom plate secondary beam is connected between the two opposite profile bottom beams, and an indoor layered ground is arranged on the bottom plate secondary beam.

And a downpipe is arranged between the corresponding top plate corner piece and the corresponding bottom plate corner piece, the upper end of the downpipe is inserted into the downpipe socket, and the lower end of the downpipe penetrates through the downpipe limiting frame.

The roof secondary beam is connected between the two opposite profile top beams, a roof square tube is arranged on the roof secondary beam, a roof skin covers the roof square tube, and an inner flanging and a right-angle flanging of an inner vertical plate are arranged on the top beam of the profile top beam, wherein the edge of the roof skin covers the profile top beam.

And a door and a window are arranged on the corresponding aerogel composite color steel plate.

The utility model discloses in, four section bar back timber are prepared four roof corner fittings after erect on four angle steel stands, lie in under four angle steel stands after four section bar floorbars are prepared four bottom plate corner fittings, constitute whole frame, adopt the compound various steel sheet of aerogel to enclose wall body all around, the top sets up roof secondary beam and roof side's pipe after, covers the roof covering, then covers photovoltaic system. Rainwater is gathered to the top plate corner fitting through the drainage channels of the section bar top beams on the periphery, flows into the bottom of the bottom plate corner fitting through the downpipe and flows out through a gap between the section bar bottom beam and the bottom surface. The cabin is typically located directly on the concrete floor or the profile sills and floor angle may be located on a concrete foundation. The cabin can be decorated indoors, and a better office environment is provided.

Further preferably, the four top plate corner pieces are jointly provided with a photovoltaic support, and a photovoltaic plate is arranged on the photovoltaic support and is used as a part of a photovoltaic system.

Further preferably, in order to realize sealing and heat preservation, glass wool is filled in the middle of a corner space between the angle steel stand column and the aerogel composite color steel plate, and extruded plates with the thickness of 100mm are respectively arranged on the upper portion and the lower portion of the corner space.

Further preferred, for realizing sealed heat preservation, the piece joint between the compound various steel sheet of adjacent aerogel adopts cartridge formula cooperation, promptly: the splicing side face of one aerogel composite color steel plate is a slot, the splicing side face of the other aerogel composite color steel plate is an inserting projection, an inner opening groove is formed in the inserting projection, and an extruded sheet is bonded in the inner opening groove through marble glue or double faced glue; the inserting convex seal is inserted in the inserting groove.

Further preferably, the indoor layered ground is sequentially provided with a base layer, a heat insulation layer, a moisture-proof layer, a graphene heating film, a breathing film and a decoration layer from bottom to top.

Further preferably, in order to realize sealing, the joint between the aerogel composite color steel plate and the angle steel upright post is sealed by white sealant.

Further preferred, realize the interior furred ceiling and decorate, the various steel sheet upper portion lateral wall of aerogel passes through screw installation furred ceiling buckle strip.

Preferably, in order to realize sealing and heat preservation, the inside of the profile top beam is filled with glass wool.

Further preferably, the floor trough is supported on the floor secondary beam.

The utility model realizes the high-efficiency conversion and utilization of green clean energy through the intelligent micro-grid formed by the energy management system of photovoltaic and energy storage, and provides continuous renewable energy supply for buildings; by additionally arranging the aerogel fireproof heat-preservation wallboard, the temperature transmission between the interior and the outside is effectively isolated, and the excellent performances of A-level fire prevention, heat insulation and heat preservation and environmental protection are realized; through laying graphite alkene heating film floor, utilize photovoltaic power generation and energy storage system energy supply, arouse self far infrared heat radiation, realize the even intensification effect of nature in the space. The whole energy-saving cabin system adopts an active and passive building energy-saving mode, integrates the functional characteristics of various green new materials, and truly realizes the aim of zero carbon emission of green building materials, no cold in winter and no heat in summer.

Compared with the prior art, the utility model has the advantages of as follows:

1. low energy consumption: the advanced energy management system, the electrical equipment with high energy efficiency and the energy conservation of the building body are adopted.

2. Fire resistance: the advanced aerogel fireproof insulation board is used, the fireproof performance of the board reaches A level, and the fireproof performance of the cabin meets the requirements.

3. The cost is low: compared with the traditional integrated house, the production and use cost is similar, but the product use convenience is far higher than that of the traditional integrated house.

4. Energy conservation: the aerogel fireproof insulation board, the solar panel and the graphene geothermal film are assembled by taking the aerogel fireproof insulation board, the solar panel and the graphene geothermal film as raw materials, the assembling process is convenient and fast, the flow process is realized, and the factory yield is high. In addition, through a special process, cold and hot bridges of a house are eliminated, and high energy-saving rate is achieved.

5. The turnover property: the zero energy consumption cabin adopts and to dismantle the component, can be based on user's demand customization production, can dismantle at any time after using up, removes to other places and assembles again, and the turnover number of times is higher.

6. Customizing: the method can meet the use requirements of users to the maximum extent according to different and differentiated designs of the user requirements, each part of components can be produced in a customized manner, and the cost and the price can be controlled to the maximum extent while the user requirements are met.

The utility model relates to a rationally, fine practical application is worth having.

Drawings

Fig. 1 shows an exploded view of an aerogel energy-saving prefabricated house.

Figure 2 shows a schematic view of the profile header construction.

Fig. 3 shows a schematic view (forward direction) of the connection of the profile top beam to the roof angle.

Figure 3a shows a schematic representation of the connection of the profiled top beam to the roof angle (back).

Fig. 4 shows a schematic view of the structure of the top plate corner fitting.

Figure 4a shows a schematic top view of a roof corner fitting.

Fig. 4b showsbase:Sub>A schematicbase:Sub>A-base:Sub>A diagram of fig. 4base:Sub>A.

FIG. 4c shows a schematic B-B diagram of FIG. 4 a.

FIG. 4d shows a schematic C-C diagram of FIG. 4 a.

Fig. 4e shows a schematic view D-D of fig. 4 a.

FIG. 4f shows a schematic E-E diagram of FIG. 4 a.

Figure 4g shows a schematic view of the right angle bottom surface i of the top panel corner fitting.

Figure 4h shows a schematic side view of the top plate corner fitting.

Figure 4i shows a schematic bottom view of the roof corner fitting.

Fig. 5 shows a partial schematic view of an angle steel upright post and an aerogel composite color steel plate.

Fig. 6 is a schematic diagram illustrating the insertion of the aerogel composite color steel plates.

Figure 7 shows a profile sill and a connection scheme.

Figure 8 shows a schematic top view of a floor corner fitting.

Fig. 8base:Sub>A showsbase:Sub>A schematicbase:Sub>A-base:Sub>A diagram of fig. 8.

FIG. 8B shows a schematic B-B diagram of FIG. 8.

Fig. 9 shows a schematic view of an indoor layered floor.

Fig. 10 shows a schematic view of energy management in a room.

In the figure: 1-photovoltaic support, 2-photovoltaic panel, 3-angle steel column, 4-roof corner fitting, 5-floor corner fitting, 6-profile top beam, 7-profile bottom beam, 8-floor secondary beam, 9-trench, 10-roof secondary beam, 11-roof square tube, 12-roof skin, 13-aerogel composite color steel plate, 14-indoor layered floor, 15-downpipe, 16-door, 17-window, 18-bolt, 19-screw, 20-ceiling buckle strip, 21-glass wool, 22-extruded sheet, 23-marble glue or double faced glue, 24-white sealant; 401-side plate I, 402-right-angle bottom surface I, 403-lower right-angle flanging I, 404-right-angle top surface I, 405-upper right-angle flanging I, 406-horizontal supporting plate, 407-inner vertical plate, 408-baffle, 409-right-angle flanging, 410-downpipe interface and 411-lightening hole; 501-side plates II, 502-right-angle bottom surfaces II, 503-lower right-angle flanging II, 504-downpipe limiting frames 505-right-angle top surfaces II, 506-upper right-angle flanging II; 601-top beam side edge, 602-top beam lower horizontal edge, 603-top beam lower vertical edge, 604-top beam upper horizontal short edge, 605-top beam upper oblique edge, 606-top beam upper horizontal long edge, 607-top beam upper vertical edge, 608-top beam upper inward flanging; 701-bottom beam side edge, 702-bottom beam lower horizontal edge, 703-bottom beam lower vertical edge, 704-bottom beam upper horizontal edge, 705-bottom beam upper vertical edge; 1301-slot, 1302-insert convex; 1401-a base layer, 1402-a heat insulation layer, 1403-a moisture-proof layer, 1404-a graphene heating layer, 1405-a breathing film and 1406-a decoration layer; 100-an intelligent control system, 200-a solar photovoltaic system, 300-an energy storage system, 400-an air conditioning system, 500-a power utilization terminal, 600-a lighting system and 700-a graphene geothermal system.

Detailed Description

The following describes in detail specific embodiments of the present invention with reference to the accompanying drawings.

An energy-conserving assembled cabin of aerogel, erects back timber and floorbar through the angle steel stand, constitutes behind the assembly wall body.

As shown in fig. 1, the angle iron stand column comprises four angle iron stand columns 3, wherein a top plate corner piece 4 is fixedly arranged at the top end of each angle iron stand column 3, and a bottom plate corner piece 5 is arranged at the bottom end of each angle iron stand column 3; a section top beam 6 is welded between every two top plate corner pieces 4, and a section bottom beam 7 is welded between every two bottom plate corner pieces 5; to form a frame structure of the cabin. The aerogel composite color steel plates 13 are arranged between the profile top beam 6 and the profile bottom beam 7 after being spliced to form a wall body, and the corresponding aerogel composite color steel plates 13 are provided with doors 16 and windows 17. Install photovoltaic support 1 on four roof corner fittings 4 jointly, arranged photovoltaic board 2 on the photovoltaic support 1.

The structure of the top plate corner fitting 4 is shown in fig. 4, 4h and 4i, and comprises two side plates i 401 arranged at right angles, and as shown in fig. 4e and 4f, the side plates i 401 are provided with lightening holes 411. The horizontal folded edges at the bottoms of the two side plates I401 form a right-angle bottom surface I402 together, and the upward vertical folded edge of the right-angle bottom surface I402 forms a lower right-angle folded edge I403; the horizontal hem at the top of two blocks of curb plates I401 constitutes I404 of right angle top surface jointly, and the vertical hem in the downward of I404 of right angle top surface constitutes last right angle turn-ups I405. A horizontal supporting plate 406 is arranged between the middle parts of the two side plates I401, an inner vertical plate 407 is arranged on the inner side edge of the horizontal supporting plate 406, baffle plates 408 are arranged between the two side edges of the inner vertical plate 407 and the corresponding side edges of the horizontal supporting plate 406 and the corresponding side edges of the side plates I401 respectively, and the two baffle plates 408 are arranged vertically. The upper end of the inner vertical plate 407 is inwards provided with a right-angle flange 409; the horizontal strut 406 is formed with a downspout receptacle 410 at a central portion thereof. Roof rainwater is gathered to the middle space (enclosed by two side plates I, two baffles, a horizontal supporting plate and an inner vertical plate) of the top plate corner piece through the section bar top beam and is introduced into the downpipe.

As shown in fig. 2, the sectional shape of the profile header 6 is: including back timber side 601, horizontal limit 602 under this back timber side 601 lower extreme forms back timber in proper order and vertical limit 603 under the back timber, and this back timber side 601 upper end forms back timber upper horizontal short edge 604, back timber upper sloping edge 605, the long limit 606 of the back timber upper horizontal, vertical limit 607 and back timber upper internal flanging 607 in proper order, forms this water drainage tank space and is used for water conservancy diversion rainwater.

As shown in fig. 4g, 5 bolt holes are preset in the right-angle bottom surface i 402, and the right-angle bottom surface i 402 of the top plate corner fitting 4 is mounted on the top end of the angle iron upright 3 through the bolts 18.

As shown in fig. 3 and 4, the top plate corner fitting 4 is connected with the end face welding profile top beam 6, namely: the side edge 601 of the top beam is welded with the side plate I401, the lower horizontal edge 602 of the top beam and the lower vertical edge 603 of the top beam are respectively welded with the right-angle bottom surface I402 and the lower right-angle flanging I403, the upper horizontal short edge 604 of the top beam is welded with the side surface of the baffle 408, the upper horizontal long edge 606 of the top beam is welded with the horizontal edge of the baffle 408, and the upper vertical edge 607 of the top beam and the upper internal flanging 608 of the top beam are respectively welded with the side edge of the internal vertical plate 407 and the right-angle flanging 409.

The structure of the bottom plate corner fitting 5 is shown in fig. 8, 8a and 8b, and comprises two side plates II 501 arranged at right angles, the horizontal folded edges at the bottoms of the two side plates II 501 form a right-angle bottom surface II 502 together, and the upward vertical folded edge of the right-angle bottom surface II 502 forms a lower right-angle folded edge II 503; a downpipe limiting frame 504 is arranged outside the lower right-angle flanging II 503; the horizontal folded edges at the tops of the two side plates II 501 form a right-angle top surface II 505 together, and the downward vertical folded edges of the right-angle top surface II 505 form an upper right-angle folded edge II 506.

As shown in fig. 7, the sectional shape of the bottom beam 7 of the profile is: the structure comprises a bottom beam side 701, wherein a bottom beam lower horizontal edge 702 and a bottom beam lower vertical edge 703 are sequentially formed at the lower end of the bottom beam side 701, and a bottom beam upper horizontal edge 704 and a bottom beam upper vertical edge 705 are sequentially formed at the upper end of the bottom beam side 701.

Five bolt holes are reserved in the right-angle top surface II 505 of the bottom plate corner fitting 5 and are installed at the bottom end of the angle steel upright post 3 through bolts 18. The end face welding profile bottom beam 7 is connected to the bottom plate corner fitting 5, namely: the side edge 701 of the bottom beam is welded with the side plate II 501, the upper horizontal edge 704 of the bottom beam and the upper vertical edge 705 of the bottom beam are respectively welded with the right-angle top surface II 505 and the upper right-angle flanging II 506, and the lower horizontal edge 702 of the bottom beam and the lower vertical edge 703 of the bottom beam are respectively welded with the right-angle bottom surface II 502 and the lower right-angle flanging II 503.

A downpipe 15 is arranged between the corresponding top plate corner piece 4 and the corresponding bottom plate corner piece 5, the upper end of the downpipe 15 is inserted into the downpipe inserting opening 410, and the lower end of the downpipe 15 penetrates through the downpipe limiting frame 504.

And a wall body formed by splicing aerogel composite color steel plates 13 is assembled between the corresponding profile top beam 6 and the profile bottom beam 7. As shown in fig. 6, the abutted seams between the adjacent aerogel composite color steel plates 13 are matched in a plug-in manner, that is: the splicing side face of one aerogel composite color steel plate 13 is a slot 1301, the splicing side face of the other aerogel composite color steel plate 13 is an inserting protrusion 1302, an inner opening groove is formed in the inserting protrusion 1302, and the extruded sheet 22 is bonded in the inner opening groove through marble glue or double-faced glue 23; the insertion protrusion 1302 is hermetically inserted into the insertion groove 1301.

As shown in fig. 2, the upper end of the aerogel composite color steel plate 13 is assembled on the top beam lower vertical edge 603 of the profile top beam 6 through a screw 19. A roof secondary beam 10 is connected between the two opposite profile top beams 6, a roof square tube 11 is arranged on the roof secondary beam 10, a roof skin 12 covers the roof square tube 11, and the edge of the roof skin 12 covers a top beam upper inward flanging 608 of the profile top beam 6 and a right-angle flanging 409 of an inner vertical plate 407. The side wall of the upper part of the aerogel composite color steel plate 13 is provided with a suspended ceiling buckle strip 20 through a screw 19. The inside of the profile top beam 6 is filled with glass wool 21.

As shown in fig. 5, the middle part of the corner space between the angle steel upright 3 and the aerogel composite color steel plate 13 is filled with glass wool 21, and the upper and lower parts of the corner space are respectively provided with extruded plates with the thickness of 100 mm. The joint of the aerogel composite color steel plate 13 and the angle steel upright post 3 is sealed by white sealant 24.

As shown in fig. 7, the lower end of the aerogel composite color steel plate 13 is inserted into the ground groove 9, the side edge of the ground groove 9 is assembled on the vertical edge 705 of the bottom beam 7, and the ground groove 9 is supported on the bottom plate secondary beam 8. A bottom plate secondary beam 8 is connected between the two opposite profile bottom beams 7.

The floor secondary beam 8 is provided with an indoor layered floor 14, and as shown in fig. 9, the indoor layered floor 14 sequentially comprises a base layer 1401, a heat insulation layer 1402, a moisture-proof layer 1403, a graphene heating film 1404, a breathing film 1405 and a decoration layer 1406 from bottom to top. Wherein, the basal layer can select for use calcium silicate board, cement fiberboard, steel sheet etc. and EPS (polystyrene foam), XPS (extrusion molding polystyrene foam) etc. can be selected for use to the insulating layer, and plastic film, special reflectance coating, PE membrane etc. can be selected for use to the dampproof course, and polyethylene waterproof ventilated membrane etc. can be selected for use to the breathing membrane, and timber apron, ceramic tile, earth's glue etc. can be selected for use to the decorative layer. And a door 16 and a window 17 are arranged on the corresponding aerogel composite color steel plate 13. Install photovoltaic support 1 on four roof corner fittings 4 jointly, arranged photovoltaic board 2 on the photovoltaic support 1.

As shown in fig. 10, the cabin is powered by solar energy, the solar panel generates electricity by using the heat energy generated by solar radiation in a light-heat-electricity conversion mode, and stores the electric energy by a special battery pack to supply energy for the aerogel zero-carbon cabin. After the solar photovoltaic system 200 is used for generating electric energy, the intelligent control system 100 controls the electric energy to be transmitted to the air conditioning system 400, the lighting system 600, the graphene geothermal system 700 and each electric terminal 500, and the redundant electric energy enters the energy storage system 300 for storage. The graphene heating film has ultrahigh heat conversion, ultralow energy consumption and ultrahigh damage resistance, and adopts far infrared heat dissipation, so that the drying and heat brought by traditional heat conduction are reduced, and the graphene heating film is healthier. In addition, graphene can be intelligently managed and can be kept at a constant temperature. Has no formaldehyde, and is healthy and environment-friendly. In addition, the aerogel fireproof insulation board has the performances of fire prevention, heat preservation, falling prevention and the like, and a reasonable composite process is obtained by combining the performances of aerogel materials, so that various index requirements are met, and the combustion grade of the product can reach A level.

The utility model discloses use new material, new technology in integrated room, aerogel fire prevention heat preservation wallboard, photovoltaic power generation and energy storage system, graphite alkene heating film have realized A level fire prevention, thermal-insulated heat preservation, have realized renewable resource utilization, green, have realized the even intensification effect of nature in the space.

Finally, it should be noted that the above embodiments are only used for illustrating the technical solutions of the present invention and not for limiting, and although the detailed description is made with reference to the embodiments of the present invention, those skilled in the art should understand that the technical solutions of the present invention are modified or replaced with equivalents without departing from the spirit and scope of the technical solutions of the present invention, which should be covered by the protection scope of the claims of the present invention.

Claims (9)

1. An aerogel energy-saving assembled cabin comprises four angle steel upright posts (3), wherein a top plate corner piece (4) is fixedly installed at the top end of each angle steel upright post (3), and a bottom plate corner piece (5) is installed at the bottom end of each angle steel upright post; a section top beam (6) is welded between every two top plate corner pieces (4), and a section bottom beam (7) is welded between every two bottom plate corner pieces (5);

the method is characterized in that: the top plate corner fitting (4) comprises two side plates I (401) which are arranged in a right angle mode, the horizontal folded edges of the bottoms of the two side plates I (401) form a right angle bottom surface I (402), and the upward vertical folded edge of the right angle bottom surface I (402) forms a lower right angle folded edge I (403); the horizontal folded edges at the tops of the two side plates I (401) form a right-angle top surface I (404), and the downward vertical folded edges of the right-angle top surface I (404) form an upper right-angle folded edge I (405); a horizontal supporting plate (406) is arranged between the middle parts of the two side plates I (401), inner side edges of the horizontal supporting plate (406) are provided with inner vertical plates (407), two side edges of each inner vertical plate (407) are respectively provided with a baffle (408) between the corresponding side edge of the horizontal supporting plate (406) and the corresponding side edge of the corresponding side plate I (401), and the two baffles (408) are vertically arranged; the upper end of the inner vertical plate (407) is inwards provided with a right-angle flanging (409); a downpipe socket (410) is formed in the middle of the horizontal supporting plate (406);

the section shape of the section bar top beam (6) is as follows: the device comprises a top beam side edge (601), wherein a top beam lower horizontal edge (602) and a top beam lower vertical edge (603) are sequentially formed at the lower end of the top beam side edge (601), and a top beam upper horizontal short edge (604), a top beam upper inclined edge (605), a top beam upper horizontal long edge (606), a top beam upper vertical edge (607) and a top beam upper inward flanging (608) are sequentially formed at the upper end of the top beam side edge (601);

the right angle bottom surface I (402) of roof corner fittings (4) is installed in angle steel stand (3) top through bolt (18), end face welding section bar back timber (6) is connected in roof corner fittings (4), promptly: the side edge (601) of the top beam is welded with the side plate I (401), the lower horizontal edge (602) and the lower vertical edge (603) of the top beam are respectively welded with the right-angle bottom surface I (402) and the lower right-angle flanging I (403), the upper horizontal short edge (604) of the top beam is welded with the side surface of the baffle (408), the upper horizontal long edge (606) of the top beam is welded with the horizontal edge of the baffle (408), and the upper vertical edge (607) and the upper internal flanging (608) of the top beam are respectively welded with the side edge of the internal vertical plate (407) and the right-angle flanging (409);

the bottom plate corner fitting (5) comprises two side plates II (501) which are arranged in a right-angle mode, the horizontal folded edges of the bottoms of the two side plates II (501) form a right-angle bottom surface II (502), and the upward vertical folded edges of the right-angle bottom surface II (502) form a lower right-angle folded edge II (503); a downpipe limiting frame (504) is arranged outside the lower right-angle flanging II (503); the horizontal folded edges at the tops of the two side plates II (501) form a right-angle top surface II (505), and the downward vertical folded edges of the right-angle top surface II (505) form an upper right-angle folded edge II (506);

the section shape of the section bottom beam (7) is as follows: the structure comprises a bottom beam side edge (701), wherein a bottom beam lower horizontal edge (702) and a bottom beam lower vertical edge (703) are sequentially formed at the lower end of the bottom beam side edge (701), and a bottom beam upper horizontal edge (704) and a bottom beam upper vertical edge (705) are sequentially formed at the upper end of the bottom beam side edge (701);

the right-angle top surface II (505) of the bottom plate corner fitting (5) is mounted at the bottom end of the angle steel upright post (3) through a bolt (18); the bottom plate corner fitting (5) is connected with an end face welding profile bottom beam (7), namely: the side edge (701) of the bottom beam is welded with the side plate II (501), the upper horizontal edge (704) of the bottom beam and the upper vertical edge (705) of the bottom beam are respectively welded with the right-angle top surface II (505) and the upper right-angle flanging II (506), and the lower horizontal edge (702) of the bottom beam and the lower vertical edge (703) of the bottom beam are respectively welded with the right-angle bottom surface II (502) and the lower right-angle flanging II (503);

a wall body formed by splicing aerogel composite color steel plates (13) is assembled between the corresponding profile top beam (6) and the profile bottom beam (7), the upper ends of the aerogel composite color steel plates (13) are assembled on the top beam lower vertical edge (603) of the profile top beam (6) through screws (19), the lower ends of the aerogel composite color steel plates (13) are inserted into the ground grooves (9) in an adaptive manner, and the side edges of the ground grooves (9) are assembled on the bottom beam upper vertical edge (705) of the profile bottom beam (7); a bottom plate secondary beam (8) is connected between the two opposite profile bottom beams (7), and an indoor layered ground (14) is arranged on the bottom plate secondary beam (8);

a downpipe (15) is arranged between the corresponding top plate corner piece (4) and the corresponding bottom plate corner piece (5), the upper end of the downpipe (15) is inserted into the downpipe inserting opening (410), and the lower end of the downpipe (15) penetrates through the downpipe limiting frame (504);

a roof secondary beam (10) is connected between two opposite profile top beams (6), a roof square tube (11) is arranged on the roof secondary beam (10), a roof skin (12) covers the roof square tube (11), and the edge of the roof skin (12) is coated with a top beam upper inner flanging (608) of the profile top beam (6) and a right-angle flanging (409) of an inner vertical plate (407);

and a door (16) and a window (17) are arranged on the corresponding aerogel composite color steel plate (13).

2. An energy-conserving prefabricated cabin of aerogel of claim 1, characterized by: install photovoltaic support (1) jointly on four roof corner fittings (4), photovoltaic board (2) have been arranged on photovoltaic support (1).

3. An aerogel energy saving fabricated cabin as claimed in claim 1 or 2, wherein: the corner space middle part between angle steel stand (3) and the compound various steel sheet of aerogel (13) is filled with glass silk floss (21), and this corner space upper and lower part is equipped with 100mm thick extruded sheet respectively.

4. An aerogel energy saving fabricated cabin as claimed in claim 3, wherein: the piece joint between the compound various steel sheet of adjacent aerogel (13) adopts cartridge formula cooperation, promptly: the splicing side surface of one aerogel composite color steel plate (13) is a slot (1301), the splicing side surface of the other aerogel composite color steel plate (13) is an inserting protrusion (1302), an inner opening groove is formed in the inserting protrusion (1302), and an extruded sheet (22) is bonded in the inner opening groove through marble adhesive or double-sided adhesive (23); the inserting protrusion (1302) is inserted into the inserting groove (1301) in a sealing mode.

5. An aerogel energy saving fabricated cabin according to claim 4, wherein: the indoor layered ground (14) sequentially comprises a base layer (1401), a heat insulation layer (1402), a moisture-proof layer (1403), a graphene heating film (1404), a breathing film (1405) and a decoration layer (1406) from bottom to top.

6. An energy-conserving prefabricated cabin of aerogel of claim 5, characterized by: the joint of the aerogel composite color steel plate (13) and the angle steel upright post (3) is sealed by white sealant (24).

7. An energy-conserving prefabricated cabin of aerogel of claim 6, characterized by: the side wall of the upper part of the aerogel composite color steel plate (13) is provided with a suspended ceiling buckle strip (20) through a screw (19).

8. An energy-conserving prefabricated cabin of aerogel of claim 7, characterized by: the inside of the section bar top beam (6) is filled with glass wool (21).

9. An energy-conserving prefabricated cabin of aerogel of claim 8, characterized by: the geosyncline (9) is supported on the bottom plate secondary beam (8).

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