CN216690107U - Roof system with integrated aluminum alloy structure - Google Patents

Abstract

The utility model relates to a roof system with an integrated aluminum alloy structure, wherein a plurality of grids are arranged on the aluminum alloy structure, and the roof system comprises: the bearing part is arranged in the grid and connected with the corresponding aluminum alloy structure, the bearing part is annular, and an installation plate is formed on one side of the bearing part close to the aluminum alloy structure; and the glass plate is covered on the grid, is arranged on the bearing part and is fixedly connected with the mounting plate. According to the roof system, the glass plate is installed through the bearing part, the bearing part is connected with the aluminum alloy structure, the installed glass plate is directly arranged on the bearing part, the load of the glass plate is completely transmitted to the aluminum alloy structure through the bearing part, the force transmission path is stable and reliable, the stress requirement of the glass plate can be met, the keel structure of the glass is reduced, the structure is simple, and the construction is convenient. The assembled construction can be realized to the installation of bearing piece and the installation of glass board, avoids the welding, can improve the efficiency of construction, reduces the construction error.

Description

Roof system with integrated aluminum alloy structure

Technical Field

The utility model relates to the technical field of building engineering, in particular to an aluminum alloy structure integrated roof system.

Background

The glass daylighting roof can meet the requirement of modern originality on the aesthetic degree of the building appearance, can improve the indoor light transmittance, and is widely applied to modern architectural decoration.

The major structure of current glass daylighting top is mostly steel, needs to construct complicated fossil fragments transform structure, and its installation is fixed moreover, adopts welded connection usually in the construction, and its assembly prefabrication rate is low, and the efficiency of construction is lower, and construction error is also great, often is difficult to satisfy the requirement of the relevant technological error of curtain.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the defects of the prior art, provides a roof system with an integrated aluminum alloy structure, and solves the problems of low assembly prefabrication rate, complex construction of a keel conversion structure, low construction efficiency and large construction error of the existing steel welding installation glass daylighting roof.

The technical scheme for realizing the purpose is as follows:

the utility model provides an aluminum alloy structure integrated roof system, wherein a plurality of grids are arranged on the aluminum alloy structure, and the roof system comprises:

the bearing part is arranged in the grid and connected with the corresponding aluminum alloy structure, the bearing part is annular, and an installation plate is formed on one side of the bearing part close to the aluminum alloy structure; and

and the glass plate covers the grid, is arranged on the bearing part and is fixedly connected with the mounting plate.

According to the roof system, the glass plate is installed through the bearing part, the bearing part is connected with the aluminum alloy structure, the installed glass plate is directly placed on the bearing part, the load of the glass plate is completely transferred to the aluminum alloy structure through the bearing part, the force transfer path is stable and reliable, and the stress requirement of the glass plate can be met. The assembled construction can be realized to the installation of bearing piece and the installation of glass board, avoids the welding, can improve the efficiency of construction, reduces the construction error, and this bearing piece is direct to be connected with glass and major structure, reduces glass's keel structure, and the structure is succinct, the construction is convenient.

The roof system with the integrated aluminum alloy structure is further improved in that the bearing part comprises a plurality of bearing units which are in butt joint connection, and the bearing units are arc-shaped;

the aluminum alloy structure comprises a plurality of aluminum alloy rods which are connected in a splicing manner, and the plurality of aluminum alloy rods surround to form corresponding grids;

the bearing units positioned on two sides of the aluminum alloy rod piece are fixedly connected with the aluminum alloy rod piece through a carrying pole beam.

The roof system with the integrated aluminum alloy structure is further improved by comprising a bearing rib arranged at the bottom of the glass plate;

and the bearing piece is provided with a mounting groove corresponding to the bearing rib.

The aluminum alloy structure integrated roof system is further improved in that the bearing ribs comprise a first waist plate and a second waist plate which are oppositely arranged, connecting ribs connected to the bottoms of the first waist plate and the second waist plate and a fixing plate connected to the upper parts of the first waist plate and the second waist plate in a supporting manner;

the first waist plate and the second waist plate are arranged in an inclined manner;

the glass plate is mounted on the fixing plate.

The roof system with the integrated aluminum alloy structure is further improved in that the first waist plate and the second waist plate are arc-shaped plates, and the width of the first waist plate and the width of the second waist plate are gradually reduced from the middle part to the two end parts.

The roof system with the integrated aluminum alloy structure is further improved in that the roof system further comprises a ring beam arranged on the mounting plate, and the ring beam is fixedly connected with the corresponding part of the glass plate;

the glass plate is fixedly connected with the mounting plate through the annular beam;

the ends of the corresponding load-bearing ribs below the glass sheet abut against the ring beam and are fixedly connected with the ring beam.

The utility model further improves the roof system with the integrated aluminum alloy structure, wherein the bearing ribs comprise transversely arranged bearing ribs and longitudinally arranged bearing ribs, the transversely arranged bearing ribs are supported on the inner side of the annular beam, and both ends of the transversely arranged bearing ribs are connected with the annular beam;

the bearing ribs which are arranged longitudinally are supported and connected between two adjacent bearing ribs which are arranged transversely and between the bearing ribs which are arranged transversely and the annular beam.

The roof system with the integrated aluminum alloy structure is further improved in that an adapter piece connected with the annular beam is arranged at the end part of the glass plate, and a sealing strip is arranged between the end part of the glass plate and the adapter piece.

The roof system integrated with the aluminum alloy structure is further improved in that the roof system integrated with the aluminum alloy structure further comprises a roof panel arranged on the aluminum alloy structure, a drainage groove is formed in the roof panel, and the end part of the roof panel is connected with a corresponding glass plate in a sealing mode.

Drawings

FIG. 1 is a top view of the aluminum alloy structural integrated roofing system of the present invention.

Fig. 2 is a schematic structural view of a load-bearing member at a grid in the aluminum alloy structure integrated roof system of the present invention.

FIG. 3 is a top view of a grid in the aluminum alloy structural integration roofing system of the present invention.

FIG. 4 is a cross-sectional view of a first mounting arrangement for a glass sheet in an aluminum alloy structural integrated roofing system of the present invention.

FIG. 5 is an enlarged partial view of the junction of the ring beam and the glass sheet of FIG. 4.

Fig. 6 is a side view of a first embodiment of a load bearing member of the aluminum alloy structural integration roofing system of the present invention.

FIG. 7 is a cross-sectional view of a second mounting arrangement for a glass sheet in an aluminum alloy structural integrated roofing system of the present invention.

FIG. 8 is a side view of a second embodiment of a load bearing member of the aluminum alloy structural integration roofing system of the present invention.

FIG. 9 is a cross-sectional view of a third mounting arrangement for glass sheets in the aluminum alloy structural integrated roofing system of the present invention.

FIG. 10 is a schematic view of the connection of the ring beam to the load bearing ribs of FIG. 9.

FIG. 11 is a schematic structural view of a load-bearing rib in the aluminum alloy structure integrated roof system of the present invention.

Figure 12 is a schematic view of an exploded view of the load bearing rib of figure 11.

Fig. 13 is a schematic structural view of a preferred arrangement of load-bearing ribs in the aluminum alloy structural integrated roof system of the present invention.

FIG. 14 is a cross-sectional view of a connecting structure of a load-bearing rib and a glass plate in the aluminum alloy structure integrated roof system of the present invention.

FIG. 15 is a cross-sectional view of a preferred embodiment of the connection of the load-bearing ribs to the glass sheets in the aluminum alloy structural integrated roofing system of the present invention.

Fig. 16 is a cross-sectional view of a drainage ditch in the aluminum alloy structure-integrated roof system.

Detailed Description

The utility model is further described with reference to the following figures and specific examples.

Referring to fig. 1, the utility model provides an aluminum alloy structure integrated roof system, which is particularly suitable for the construction of a lighting roof of a glass plate with an ultra-large area. The roof system disclosed by the utility model adopts an aluminum alloy structure, has the characteristics of light weight, high strength and strong corrosion resistance, can realize on-site fully-assembled construction, does not need a welding process, and can improve the construction efficiency and reduce the construction error compared with the traditional steel construction. The aluminum alloy structure integrated roof system of the utility model is explained in the following with the attached drawings.

Referring to fig. 1, a top view of the aluminum alloy structural integrated roofing system of the present invention is shown. Referring to fig. 2, a schematic structural diagram of a load-bearing member at a grid in the aluminum alloy structure integrated roof system of the present invention is shown. Referring to fig. 3, a top view of a grid in the aluminum alloy structural integrated roofing system of the present invention is shown. The aluminum alloy structure integrated roofing system of the present invention will be described with reference to fig. 1 to 3.

As shown in fig. 1 to fig. 3, a plurality of grids 11 are disposed on an aluminum alloy structure 10 in an aluminum alloy structure-integrated roof system of the present invention, the roof system includes a bearing member 21 and a glass plate 22, wherein the bearing member 21 is disposed in the grid 11 and connected to the corresponding aluminum alloy structure 10, the bearing member 21 is ring-shaped, a mounting plate 211 is formed on one side of the bearing member 22 close to the aluminum alloy structure 10, the glass plate 22 covers the grid 11, and the glass plate 22 is disposed on the bearing member 21 and fixedly connected to the mounting plate 211.

Preferably, the size of the glass plate 22 is larger than that of the bearing member 21, so that the glass plate 22 is completely placed on the bearing member 21, the weight and the load of the glass plate 22 are completely and uniformly transmitted to the bearing member 21, the bearing member 21 is annular, has good integrity and higher stress stability, the bearing member 21 serves as a main bearing member of the glass plate 22, can completely transmit the load of the glass plate to the aluminum alloy structure 10, and further, the stability of the glass plate is ensured by the aluminum alloy structure 10. The load applied to the aluminum alloy structure by the glass plate and the bearing part is vertical load, no other lateral component force exists, and the overall stability of the aluminum alloy structure can be improved. By covering the grid with a glass plate, the structure can be made highly light transmissive.

In one embodiment of the present invention, as shown in fig. 2 to 4, the bearing member 21 includes a plurality of bearing units connected in a butt joint manner, and the bearing units are arc-shaped; the aluminum alloy structure 10 comprises a plurality of aluminum alloy rods 12 connected in a splicing manner, and the plurality of aluminum alloy rods 12 are enclosed to form corresponding grids 11; the bearing units on both sides of the aluminum alloy rod 12 are fixedly connected with the aluminum alloy rod 12 through a carrying pole beam 13.

The grids 11 are formed by surrounding aluminum alloy bars 12, so that two adjacent grids 11 share one aluminum alloy bar 12. A bearing part 21 is arranged in the grid 11, the bearing part 21 is positioned at the side part of the corresponding aluminum alloy rod piece, when the bearing part 21 is connected with the aluminum alloy rod piece 12, the carrying pole beam 13 is arranged on the aluminum alloy rod piece 12 and the bearing part 21 at the two sides, and then the carrying pole beam 13 and the aluminum alloy rod piece 12, and the carrying pole beam 13 and the bearing part 21 are fastened and connected by bolts. Specifically, the mounting plate 211 of the bearing member 21 is flush with the top surface of the aluminum alloy rod member 12, and the carrying pole beam 13 is placed on the top of the mounting plate 211 and the aluminum alloy rod member 12, so that fastening connection is realized through bolts.

Further, as shown in fig. 4 and 6, a connecting plate 213 is further formed on one side of the bearing member 21 close to the aluminum alloy rod 12, the connecting plate 213 is located below the mounting plate 211, the connecting plate 213 is flush with the bottom of the aluminum alloy rod 12, and another shoulder pole beam 13 is attached to the bottom of the aluminum alloy rod 12 and the connecting plate 213, so that fastening connection is realized through bolts. Therefore, the bearing parts 21 on the two sides of the aluminum alloy rod 12 are clamped on the aluminum alloy rod 12 through the upper and lower carrying pole beams 13, so that the connection between the bearing parts 21 and the aluminum alloy rod 12 is firm, the force transmission is stable, and the bearing parts 21 on the two sides can be supported through the aluminum alloy rod 12.

Preferably, the bearing unit is an arc-shaped plate, a preferred embodiment of the arc-shaped plate is pi-shaped, and the bearing unit comprises a vertical plate, and a mounting plate and a connecting plate which are formed on one side of the vertical plate and are vertically connected with the vertical plate. Further, the top of vertical board is close to glass board 22 to this vertical board can shelter from glass board 22's mounting structure, has played the effect of enclosing the fender, so from indoor seeing, does not have any mounting structure expose, can improve the outward appearance effect.

Still further, as shown in fig. 4 and 6, the wing plate 214 is formed at the bottom of the bearing member 21 near the aluminum alloy rod 12, and the wing plate 214 is used as a mounting base for mounting the lamp source 14. Referring to fig. 16, in order to prevent the aluminum alloy bar 12 from being exposed to the indoor side, a decorative plate 28 is provided under the aluminum alloy bar 12, and the end of the decorative plate 28 is fastened to the flange 214.

In one embodiment of the present invention, as shown in fig. 4, which shows a first mounting structure of a glass plate 22, a ring beam 24 is provided on a mounting plate 211, the ring beam 24 is fixedly connected to a corresponding portion of the glass plate 22, and the glass plate 22 is mounted on the mounting plate 211 via the ring beam 24.

The ring beam 24 bearing is in the bottom of glass board 22, and this ring beam 24 is close to the border setting of glass board 22, through the setting of ring beam 24, improves glass board 22's installation intensity, further improves glass board 22's structural stability, and glass board 22's vertical load accessible ring beam 24 is even transmits for mounting panel 211, and then mounting panel 211 transmits for the aluminum alloy member through carrying pole roof beam 13 for the whole atress of structure is stable.

Specifically, as shown in fig. 5, a mounting frame 221 corresponding to the ring beam 24 is provided at the bottom of the glass plate 22 near the edge, the mounting frame 221 is adhered and fixed to the glass plate 22, and the mounting frame 221 is fastened and connected to the top of the ring beam 24 by a pressing plate 222. The mounting frame 221 is preferably disposed adjacent the inner side of the ring beam 24. As shown in fig. 10 and 4, the bottom of the ring beam 24 is provided with a base 241, and the base 241 is placed on the mounting plate 211 and is connected and fixed to the mounting plate 211 by bolts.

An adapter 25 is connected between the outer side of the annular beam 24 and the edge of the glass plate 22, the adapter 25 is also annular and comprises a straight plate, the straight plate is adhered and fixed at the bottom of the glass plate 22, the end part of the straight plate corresponding to the edge of the glass plate 22 is bent upwards to form a binding plate, and a sealing strip 261 is arranged between the binding plate and the end part of the glass plate 22. The other end of the flat plate is bent with a vertical plate corresponding to the outer side of the ring beam 24, and the vertical plate is fixedly connected with the ring beam 24 through a screw. The vertical plate is also connected with an L-shaped plate 251, a foam rod 263 and a first sealing layer 262 are filled between the L-shaped plate 251 and the straight plate, and the first sealing layer 262 is formed by filling sealing glue. Sealing of the end of the glass plate 22 is achieved by the sealing strip 261 and the first sealing layer 262.

In one embodiment of the present invention, as shown in fig. 7, a second mounting structure for a glass plate 22 is shown, which is suitable for mounting a glass plate 22 with a smaller size, a mounting plate 211 on a bearing member 21 is disposed near the top of the bearing member 21, and a mounting frame of the glass plate 22 is disposed on the mounting plate 211 and is further fixedly connected to the mounting plate 211 through a pressing plate. Referring to fig. 8, in the present embodiment, the bearing member 21 includes a vertical plate, a mounting plate 211 formed on one side of the vertical plate and disposed perpendicular to the vertical plate, a mounting plate 215, a connecting plate 213, and a wing plate 214, and the mounting plate 215 and the connecting plate 213 are fastened to the aluminum alloy rod 12 through the pole beam 13.

The glass plate 22 with a small size can be directly and conveniently hoisted during installation, and then the installation frame on the glass plate 22 is tightly connected to the installation plate 211.

In an embodiment of the present invention, as shown in fig. 2, 3 and 9, the glass plate further includes a bearing rib 23 disposed at the bottom of the glass plate 22, and the bearing member 21 has a mounting groove 212 corresponding to the bearing rib 23. The mounting structure is suitable for mounting a large-sized glass plate 22, and the bearing ribs 23 are arranged at the bottom of the glass plate 22, so that the overall structural strength of the glass plate 22 can be improved. The bearing rib 23 is clamped into the mounting groove 211 on the bearing part 21, the mounting groove 211 plays a role in mounting and positioning the bearing rib 23, and the bearing rib 23 is directly seated on the bearing part 21, so that the structure is integrally stable.

Further, as shown in fig. 11 and 12, the load-bearing rib 23 includes a first waist plate 231 and a second waist plate 232 which are oppositely arranged, a connecting rib 233 connected at the bottom of the first waist plate 231 and the second waist plate 232, and a fixing plate 234 supported and connected at the upper portion of the first waist plate 231 and the second waist plate 232, wherein the first waist plate 231 and the second waist plate 233 are arranged in an inclined manner, and as shown in fig. 14, the glass plate 22 is mounted on the fixing plate 234.

The cross-section of bearing rib 23 is the style of calligraphy of falling A, the bottom of first waist board 231 and second waist board 232 is close to the setting, and be connected with splice bar 233, the top of first waist board 231 and second waist board 232 is kept away from the setting mutually and is connected with fixed plate 234, wherein fixed plate 234 bearing glass board 22, this fixed plate 234 exerts pressure to first waist board 231 and second waist board 232, first waist board and second waist board receive this splice bar 233 of transmission behind the pressure, make this splice bar 233 to be drawn, splice bar 233 receives the pulling force of both sides and can form certain balanced action, thereby make the atress stable, this bearing rib self accords with the atress principle, can have higher stability.

Specifically, as shown in fig. 14, the mounting frames 221 are provided at the ends of the glass plates 22, the mounting frames 221 are placed on the fixing plate 234, the ends of the two glass plates 22 are butted, and the two mounting frames 221 are fastened to the fixing plate 234 by the pressing plate 222. The top elevations of the first waist plate 231 and the second waist plate 232 are higher than the top elevation of the fixing plate 234, so that the mounting frame 221 and the pressing plate 222 are shielded by the raised parts of the tops of the first waist plate 231 and the second waist plate 232. For the waterproof performance who improves the glass board, laid the drainage rubber layer at the top surface of fixed plate 234, the part that first waist board 231 and second waist board 232 top are higher can also play limiting displacement to the drainage rubber layer, prevents that this drainage rubber layer from taking place lateral displacement. A second sealant layer 264 is provided at the butt seam of the two glass sheets 22. In the case of larger grid sizes, multiple glass sheets 22 are spliced together to form a glass sheet that covers the grid.

Further, as shown in fig. 12, the first waist panel 231 and the second waist panel 232 of the load-bearing rib 23 are arc-shaped panels, and the width of the first waist panel 231 and the second waist panel 232 gradually decreases from the middle portion to both end portions. The first waist plate and the second waist plate are arranged to be variable in cross section, and the bending moment force borne by the first waist plate and the second waist plate is borne by the wider middle part, so that the bending resistance of the first waist plate and the second waist plate can be improved.

The bearing rib 23 is in an inverted A shape and has high bending resistance, on one hand, the connecting ribs at the bottoms of the first waist plate and the second waist plate are integrally pulled, the fixing plates at the tops of the first waist plate and the second waist plate are pressed, the bending resistance of the bearing rib can be improved by pulling the connecting ribs, the force of downward bending of the middle part of the bearing rib can be resisted, and therefore the bearing rib can be in a stable state. On the other hand, first waist board and second waist board are the arc, and the width at middle part is greater than the width of tip, are variable cross section state, and the middle part of first waist board and second waist board has higher structural strength so as to resist decurrent bending force, has improved bending resistance. Moreover, the connecting ribs are arranged at the bottom, the tapered parts at the bottoms of the bearing ribs can be seen firstly when the connecting ribs are seen indoors, the width of the rod piece is reduced in visual effect, and the aesthetic pursuit of lightness, fineness and permeability of modern building shapes can be reflected in visual effect. The bearing rib of the type of falling A compares and to have material saving in current square fossil fragments, saves the labour to can shorten construction cycle.

Still further, as shown in fig. 13, the bearing ribs 23 include a transverse bearing rib and a longitudinal bearing rib, and the transverse bearing rib and the longitudinal bearing rib are connected in a butt joint manner and are supported at the bottom of the glass plate 22, so that the overall structural strength of the glass plate 22 can be improved. Preferably, when the ring beam 24 is used for installing the glass plate, the transversely arranged bearing ribs are supported on the inner side of the ring beam 24, and two ends of the bearing ribs are connected with the ring beam 24; the longitudinally arranged bearing ribs are supported and connected between two adjacent transversely arranged bearing ribs and between the transversely arranged bearing ribs and the ring beam 24. So, the bearing rib that transversely sets up and vertically set up is connected with the ring beam and is formed a stable whole, is the ring form at ring beam 24, and bearing rib is connected to inside shore, and bearing rib both had played the supporting role to ring beam 24, and an overall structure is connected into with ring beam 24 again, bearing glass board together, can satisfy the bearing requirement of glass board. As shown in fig. 9 and 10, the ends of the load-bearing ribs 23 abut against the inner side of the ring beam 24 and are welded and fixed. As shown in fig. 15, the transverse load-bearing ribs and the longitudinal load-bearing ribs can be fixed by welding, and can be fixedly connected with the screws by corner connectors.

Under the condition that the bearing ribs are arranged at the bottom of the glass plate, the bearing ribs and the annular beam can be assembled and then hoisted and installed together according to the area size of the glass plate, the bearing ribs and the annular beam can be assembled together firstly and then hoisted and installed integrally, and then the glass plate is hoisted and installed block by block.

In an embodiment of the present invention, as shown in fig. 16, the present invention further includes a roof panel 27 disposed on the aluminum alloy structure 12, the roof panel 27 is formed with drainage grooves 271, and the end of the roof panel 27 is hermetically connected to the corresponding glass plate 22. The aluminum alloy rod member 12 is covered with the roof panel 27, and the roof panel 27 has a U-shaped cross section and has a drainage groove 271 formed therein, so that rainwater on the roof can be drained by the drainage groove 271. The bottom surface of the roof panel 27 is lower than the glass panel 22 and the end of the roof panel 27 is fixedly connected to the adapter at the end of the glass panel 22 and sealed at the seam. The seam of the roof panel 27 is welded and fixed, and the sealing performance and the sealing time are better compared with those of sealing glue welding.

Further, a heat insulation layer is covered at the bottom of the roof panel 27.

While the present invention has been described in detail and with reference to the embodiments thereof as illustrated in the accompanying drawings, it will be apparent to one skilled in the art that various changes and modifications can be made therein. Therefore, certain details of the embodiments are not to be interpreted as limiting, and the scope of the utility model is to be determined by the appended claims.

Claims (9)

1. The utility model provides a roofing system of aluminum alloy structure integration, the structural a plurality of grids that are equipped with of aluminum alloy, its characterized in that, roofing system includes:

the bearing part is arranged in the grid and connected with the corresponding aluminum alloy structure, the bearing part is annular, and an installation plate is formed on one side of the bearing part close to the aluminum alloy structure; and

and the glass plate covers the grid, is arranged on the bearing part and is fixedly connected with the mounting plate.

2. An aluminium alloy structural integral roofing system as defined in claim 1 wherein the bearing member includes a plurality of bearing units in butt joint, the bearing units being arcuate;

the aluminum alloy structure comprises a plurality of aluminum alloy rods which are connected in a splicing manner, and the plurality of aluminum alloy rods surround to form corresponding grids;

the bearing units positioned on two sides of the aluminum alloy rod piece are fixedly connected with the aluminum alloy rod piece through a carrying pole beam.

3. An aluminum alloy structural integral roofing system as defined in claim 1 further comprising load bearing ribs disposed on the bottom of said glass sheets;

and the bearing piece is provided with a mounting groove corresponding to the bearing rib.

4. The aluminum alloy structural integration roofing system of claim 3, wherein the load-bearing rib comprises a first waist panel and a second waist panel arranged oppositely, a connecting rib connected at the bottom of the first waist panel and the second waist panel, and a fixing plate connected at the upper part of the first waist panel and the second waist panel in a supporting manner;

the first waist plate and the second waist plate are arranged in an inclined manner;

the glass plate is mounted on the fixing plate.

5. The aluminum alloy structural integration roofing system of claim 4, wherein the first and second waist panels are arc-shaped panels, and the width of the first and second waist panels gradually decreases from the middle portion to both end portions.

6. An aluminium alloy structural integral roofing system as defined in claim 3, further comprising a ring beam disposed on said mounting plate, said ring beam being fixedly attached to a corresponding portion of said glass sheet;

the glass plate is fixedly connected with the mounting plate through the annular beam;

the ends of the corresponding load-bearing ribs below the glass sheet abut against the ring beam and are fixedly connected with the ring beam.

7. An aluminium alloy structural integral roofing system as defined in claim 6, wherein the load-bearing ribs include transversely disposed load-bearing ribs and longitudinally disposed load-bearing ribs, the transversely disposed load-bearing ribs being supported against the inside of the ring beam and having both ends connected to the ring beam;

the bearing ribs which are arranged longitudinally are supported and connected between two adjacent bearing ribs which are arranged transversely and between the bearing ribs which are arranged transversely and the annular beam.

8. An aluminium alloy structural integral roofing system as defined in claim 6 wherein the ends of said glass panels are provided with adapters to which said ring beams are connected and sealing strips are provided between the ends of said glass panels and said adapters.

9. An aluminum alloy structural integrated roofing system as defined in claim 1 further comprising a roof panel disposed on said aluminum alloy structure, said roof panel having drainage channels formed therein, the ends of said roof panel being sealingly connected to corresponding glass sheets.

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