CN115434428B - Annular cross-woven cable net structure, stereoscopic city dome and large-span building dome - Google Patents

Abstract

The invention relates to an annular cross woven cable net structure, a stereoscopic city dome and a large-span building dome, belongs to the technical field of building structure design, and solves the problems that the large-span dome cannot meet internal lighting requirements and the circumferential balance of a super high-rise structure is difficult to adjust. The annular cross-woven cable net structure comprises a giant ring truss, a roof cable net unit and a connector; the inner ring truss, the middle ring truss and the outer ring truss of the giant ring truss are correspondingly arranged at the top ends of the inner ring tower group, the middle ring tower group and the outer ring tower group of the concentric ring building group, and the roof cable net units are connected between the adjacent giant ring trusses through connectors; the roof cable net unit comprises a cable rope and a double-layer cable clamp; connectors with the same number are uniformly distributed on the edges of the adjacent giant ring trusses, the steel ropes are symmetrically interwoven, and rope clamps are arranged at the crossing points. The annular cross-woven rope net structure is light in weight, the inflatable membrane is good in light transmittance, and the roof with the dome structure is strong in adaptability to temperature change, and the whole is light and attractive.

Description

Annular cross-woven cable net structure, stereoscopic city dome and large-span building dome

Technical Field

The invention relates to the technical field of building structures, in particular to an annular cross-woven cable net structure, a stereoscopic city dome and a large-span building dome.

Background

With the advancement of human civilization and the development of construction technology, it is a desire to continually challenge the scale, height and span of buildings. In recent years, the idea of building ultra-high and ultra-large stereoscopic cities is raised. However, there are a series of technical problems to be solved in order to realize the envisaged stereoscopic city.

If the building diameter of the huge stereo city with strong functionality and markedness is set to be more than kilometers, the corresponding building area can reach millions of square meters, and the building height can also exceed kilometers. Under the assumption, the three-dimensional city building has huge volume, huge building height and structure span, and the structural height and the cross section size of members of rigid systems such as trusses, net racks and the like are increased, so that the steel consumption is increased rapidly. In addition, because the number of the rods is dense, the construction decoration measures are required to be additionally adopted, so that the structural weight, the earthquake force and the engineering cost are further increased, and the requirements of natural lighting and green ecology of the three-dimensional city are difficult to meet.

The foundation bearing capacity, lateral rigidity and other heavy technical bottlenecks of the ultra-high building are removed, and the foundation structure further comprises the problems of supporting and balancing adjustment of the ultra-high structure, including the problem of natural light utilization of a three-dimensional city and the like.

When the structural span is more than 120m, the cross section of the common structural system member is rapidly increased, so that the steel consumption is large, and the use requirements of light, transparent, lighting and the like of the dome roof can not be met; at the same time, rigid large span structures are also difficult to accommodate for the effects of relative movement of the support structure.

The technical difficulties of lighting and supporting super high-rise structures limit the construction of large-span buildings and three-dimensional city super high-rise buildings. To construct a stereoscopic city of good quality, a new stereoscopic city dome structure must be created.

Disclosure of Invention

In view of the above analysis, the invention aims to provide an annular cross-woven cable net structure, a large-span building dome and a stereoscopic city dome, which are used for solving the technical problems of insufficient lighting in the large-span building and the stereoscopic city and circumferential balance adjustment of a core super high-rise structure.

The invention is realized by the following technical scheme:

an annular cross-woven cable net structure comprises a giant ring truss, a roof cable net unit and a connector; the huge ring trusses are arranged at the top end of the annular building group, and the roof cable net units are connected between the adjacent huge ring trusses through the connectors; the annular building groups are concentrically arranged and are divided into an inner annular tower group, an intermediate annular tower group and an outer annular tower group; correspondingly, the huge ring truss is divided into an inner ring truss, a middle ring truss and an outer ring truss; the roof cable net unit comprises a cable rope and a cable clamp; the roof cable net unit comprises an outer annular cross-woven cable net and an inner annular cross-woven cable net, and the outer annular cross-woven cable net and the inner annular cross-woven cable net are respectively and radially connected between the adjacent giant ring trusses in an annular way; the outer annular cross braided rope net and the inner annular cross braided rope net form a single-layer annular cross braided rope net structure or a double-layer annular cross braided rope net structure; the steel ropes in the outer annular cross woven rope net are connected between the upper edge of the inner side of the outer annular truss and the upper edge of the outer side of the middle annular truss; the steel cable of the inner annular cross woven cable net is connected between the upper edge of the inner side of the middle ring truss and the upper edge of the outer side of the inner ring truss; the steel cable and the giant ring truss connected with the steel cable form the single-layer annular cross-woven cable net structure; the same number of connectors are arranged on the adjacent giant ring trusses, and the connectors are circumferentially and uniformly distributed on the edges of the giant ring trusses; each connector on the same huge ring truss is connected with the first ends of 2 steel ropes; the second ends of the 2 steel ropes are connected to different connectors of the adjacent giant ring trusses and are symmetrically arranged relative to the first ends; every 2 intersecting said steel cords are connected at an intersection by said cord clamps; the connector is a ball head adjusting support; the cable clamp is a double-layer cable clamp; the diameter of the minimum inscribed circle of the giant ring truss is larger than 200m.

Further, the outer annular cross-woven cable net is arranged between the inner side of the outer ring truss and the outer side of the middle ring truss; the inner annular cross-woven rope net is arranged between the inner side of the middle ring truss and the outer side of the inner ring truss to form a single-layer annular cross-woven rope net structure or a double-layer annular cross-woven rope net structure.

Further, the double-layer cable clamp comprises a double-layer cable clamp base plate, a double-layer cable clamp upper cover plate and a double-layer cable clamp lower cover plate which are sequentially connected.

Further, a first steel rope hole is formed between the double-layer rope clamp base plate and the double-layer rope clamp upper cover plate, and a second steel rope hole is formed between the double-layer rope clamp base plate and the double-layer rope clamp lower cover plate; the first and second wire rope holes are used for connecting 2 crossed wire ropes.

Further, the roof cable net unit further comprises a large-span roof unit. The large-span roof unit adopts a single-layer shell structure and comprises a core spoke cable and a single-layer shell; the single-layer shell is arranged concentrically with the inner ring truss, the same number of connectors are arranged on the upper edge of the outer side of the single-layer shell and the upper edge of the inner side of the inner ring truss, and two ends of the core spoke rope are respectively connected with the single-layer shell and the corresponding connectors on the inner ring truss.

A large-span building dome is used as a large-span building roof and comprises an annular cross-woven rope net structure and an inflatable membrane unit, wherein the inflatable membrane unit is attached to the roof rope net unit of the annular cross-woven rope net structure.

The stereoscopic city dome is used as a stereoscopic city super high-rise building roof, a central high tower is constructed on an inner ring truss of the stereoscopic city super high-rise building, and a roof cable network unit is connected with the outer elevation of the central high tower in a smooth manner; the stereoscopic city dome comprises a roof cable net unit and an inflatable membrane unit; the ring-shaped cross-woven rope net structure is used for the roof rope net unit, and the inflatable membrane unit is attached to the roof rope net unit.

A stereoscopic city super high-rise building comprises a stereoscopic city dome.

Compared with the prior art, the invention has at least one of the following beneficial effects:

1. the annular cross-woven rope net structure and the dome structure of the large-span building formed by the same can be used as an oversized inner ring roof, such as a roof of a large-span stadium; the middle of the roof adopts a single-layer reticulated shell structure, and the periphery of the roof adopts a spoke type cable structure, so that the rigidity of the building dome is ensured on the premise of fully ensuring lighting.

2. The annular cross braided rope net structure and the stereoscopic city dome structure formed on the basis thereof can be used as a roof at the periphery of a central high tower of a stereoscopic city, and can enable a central high tower foundation ring truss to be connected with the top of a huge annular structure at the outer side through the cross braided rope net; the lighting device can ensure good lighting in the three-dimensional city, can play a symmetrical and stable role in the central high tower of the three-dimensional city, and can weaken or resist the influence of wind resistance, earthquake and other destructive forces.

3. According to the annular cross-woven cable net structure and the dome structure formed on the basis of the annular cross-woven cable net structure, the space density of the cable nets is adjustable, and the density can be set according to specific environments, so that the lateral rigidity of the super high-rise building structure is remarkably improved.

4. The annular cross-woven rope net structure uses the steel rope material with the strength far higher than that of common steel, and the single-layer cross-woven rope net is arranged between the adjacent annular trusses to form the dome of the large-span roof structure, so that the steel consumption is greatly reduced, the weight is light, and the adaptability of the dome roof to air temperature change can be remarkably improved.

5. The three-dimensional urban dome structure formed on the basis of the annular cross-woven rope net structure adopts the ETFE inflatable film as the enclosure structure, and has good light transmittance and good energy-saving effect.

6. In the annular cross-woven cable net structure, diamond grids formed by the cross weaving of the steel cables can be used as peripheral supporting conditions of the ETFE film structure, and the adjacent annular trusses are high in inside and low in outside, so that roof drainage is facilitated.

7. In the annular cross-woven cable net structure, the cross points of the steel cable cross-woven are connected into the cable net structure through the double-layer cable clamps, and compared with each independent single radial cable, the structural integrity is greatly improved. Although the steel ropes of the annular cross braiding structure are all straight lines, diamond grids with rhythm sense can be formed by properly deflecting the angle of the steel ropes between adjacent annular trusses, and the upper surface of the roof is changed from straight lines to slightly concave curved surfaces, so that the structure is light and attractive.

8. The annular cross-woven cable net structure of the invention uses the connector with the position adjusted, and can resist the influence of wind resistance and earthquake force on the whole core building through the spherical position adjusting unit, thereby avoiding the generation of acting force on the core building.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. The objectives and other advantages of the invention may be realized and attained by the structure particularly pointed out in the written description and drawings.

Drawings

The drawings are only for purposes of illustrating particular embodiments and are not to be construed as limiting the invention, like reference numerals being used to refer to like parts throughout the several views.

FIG. 1 is a schematic view of the structure of an annular cross-woven rope net with a large-span roof unit of the present invention;

FIG. 2 is a bottom view of FIG. 1;

FIG. 3 is a schematic view of the planar layout of the giant ring truss of the present invention;

FIG. 4 is a schematic diagram of a roof cable net unit structure according to the present invention;

FIG. 5 is a schematic view of the connection structure of the middle ring truss and the roof cable net unit according to the present invention;

FIG. 6 is a schematic diagram of the connection relationship between the same-ring building group and the huge ring truss thereon according to the present invention;

FIG. 7 is a top view of FIG. 6;

FIG. 8 is a partially expanded view of an inner ring tower group according to the present invention;

FIG. 9 is a schematic view of a median plane of a roof cable network element arrangement with an inner loop platform horizontal reinforcement layer of the present invention;

FIG. 10 is a schematic illustration of a split face of a roof cable network element arrangement with a large span roof element of the present invention;

FIG. 11 is a schematic view of a connector according to the present invention;

FIG. 12 is a schematic view of a double-layered cable clamp according to the present invention;

FIG. 13 is a second schematic view of a double-layered cable clamp according to the present invention;

FIG. 14 is a schematic view of a double layer endless woven cable net structure according to the present invention;

FIG. 15 is a schematic view of a three-dimensional city split surface structure to which the dome of the present invention is applied;

FIG. 16 is a schematic perspective view of FIG. 15;

FIG. 17 is a bottom view of FIG. 16;

FIG. 18 is a schematic view of the split-plane structure of a large span building to which the dome of the present invention is applied;

FIG. 19 is a schematic view of the positional relationship between the inner ring pile foundation and the annular raft in the present invention;

fig. 20 is a bottom view of fig. 19.

Reference numerals:

1. building a foundation; 11. pile-raft foundation; 111. an outer ring pile foundation; 112. middle ring pile foundation; 113. an inner ring pile foundation; 12. an annular raft;

21. an outer ring tower group; 211. an outer ring tower body; 212. an outer ring truss; 213. an outer ring tower core barrel; 22. middle ring tower group; 221. middle ring tower body; 222. middle ring truss; 223. an outer ring tower core barrel; 23. an inner loop turret group; 231. an inner ring tower body; 232. an inner ring truss; 233. an inner ring tower core tube; 234. an inner ring platform horizontal reinforcement layer;

3. a central high tower; 31. a high tower low zone; 32. a high tower middle region; 33. a high tower elevation; 34. a mast region;

4. a dome structure; 41. a roof cable net unit; 411. an outer annular cross-woven cable net; 412. an inner annular cross-woven cable net; 413. a large span roof unit; 4131. a core spoke cable; 4132. a single layer housing; 42. an inflatable membrane unit; 43. a double layer cable clamp; 431. a double-layer cable clamp base plate; 432. double-layer cable clamp upper cover plate; 43. a double-layer cable clamp lower cover plate; 44. a wire rope; 45. a connector; 451. a positioning fixing body; 452. a positioning connector; 453. a positioning vibration reduction unit; 454. a positioning sealing unit; 455. and (5) positioning the spherical body.

Detailed Description

The following detailed description of preferred embodiments of the invention is made in connection with the accompanying drawings, which form a part hereof, and together with the description of the embodiments of the invention, are used to explain the principles of the invention and are not intended to limit the scope of the invention.

The following describes the technical scheme of the present invention in more detail with reference to fig. 1 to 20:

example 1

An annular cross-woven rope net structure.

As shown in fig. 4, an annular cross-woven cable net structure comprises a giant ring truss, a roof cable net unit 41 and a connector 45; the huge ring trusses are arranged at the top end of the annular building group, and the roof cable net units 41 are connected between the adjacent huge ring trusses through connectors 45.

The roof cable net unit 41 is constituted by a cable 44 and a cable clamp. Preferably, the cord clip is a double layer cord clip 43.

The same number of connectors 45 are arranged on the adjacent giant ring trusses, and the connectors 45 are circumferentially and uniformly distributed on the edges of the giant ring trusses; each connector 45 on the same huge ring truss is connected with the first ends of 2 steel ropes 44; the second ends of the 2 steel ropes 44 are connected to different connectors 45 of the adjacent huge ring trusses and are symmetrically arranged relative to the first ends; every 2 crossed wires 44 are connected at the crossing point by a double layer wire clip 43; the connector 45 is an adjustable mount, preferably the connector 45 is a ball adjustment mount.

As shown in fig. 11, specifically, the connector 45 of the ball head adjustment holder includes a positioning fixing body 451, a positioning connecting body 452, a positioning vibration reduction unit 453, a positioning sealing unit 454, and a positioning spherical body 455.

The positioning connector 452 is used for connecting the edge of the huge ring truss, and the positioning fixing body 451 is used for connecting 2 steel ropes 44 with angles. A positioning spherical body 455 with a ball head structure is provided between the positioning fixing body 451 and the positioning connecting body 452, wherein the positioning connecting body 452 has a matching spherical groove at a portion contacting with the spherical surface in the positioning spherical body 455. When the giant ring truss is stressed to generate micro displacement, the steel ropes 44 on each annular cross woven rope net structure can pass through the fine adjustment positions of the spherical surfaces, and damping is formed through different displacements of all the steel ropes 44 on the annular cross woven rope net structure, so that the influence of external factors on super high-rise buildings, especially the central high tower 3, is reduced or even eliminated.

An elastomer positioning vibration reduction unit 453 is arranged between the positioning fixing body 451 and the positioning spherical body 455 and between the positioning spherical body 455 and the positioning connecting body 452, and is used for absorbing vibration, further increasing damping and blocking the transmission of destructive force to the main body structure.

A gap is provided between the positioning fixing body 451 and the positioning connecting body 452, and the positioning sealing unit 454 seals the positioning fixing body 451 and the positioning connecting body 452, so that the rotatable and positioning spherical body 455 is positioned in the closed cavity, and lubricant is conveniently added in the closed cavity in the installation process, so that the positioning spherical body 455 can freely rotate.

As shown in fig. 1 and 3, in particular, the annular building groups are concentrically arranged and divided into an inner annular tower group 23, an intermediate annular tower group 22 and an outer annular tower group 21; correspondingly, the huge ring truss is divided into an inner ring truss 232, a middle ring truss 222 and an outer ring truss 212.

The giant ring truss of the ring-shaped cross-woven cable network structure of embodiment 1 includes an inner ring truss 232, a middle ring truss 222, and an outer ring truss 212 of the ring-shaped building group.

Further, the roof cable net unit 41 includes an outer annular cross-woven cable net 411 and an inner annular cross-woven cable net 412, and the outer annular cross-woven cable net 411 and the inner annular cross-woven cable net 412 are respectively connected between adjacent giant ring trusses in an annular radial manner.

Further, an outer annular cross-woven cable net 411 is disposed between the inner side of the outer ring truss 212 and the outer side of the middle ring truss 222; an inner endless cross-woven cable net 412 is between the inner side of middle ring truss 222 and the outer side of inner ring truss 232.

Alternatively, the outer annular cross-woven wire mesh 411 and the inner annular cross-woven wire mesh 412 may each be provided in a single-layer annular cross-woven wire mesh structure or a double-layer annular cross-woven wire mesh structure. The double-layer annular cross-woven cable net structure is shown in fig. 14, a plurality of connectors are uniformly distributed on the inner side of the outer ring truss 212, each uniformly distributed point location can be connected with 2 connectors 45 (or the positioning connector 452 of one connector 45 is provided with 4 direction connectors), 2 other ends of the steel cables 44,4 in 4 different directions can be connected with 2 connectors on the outer side of the middle ring truss 222, the other ends of the other 2 of the 4 steel cables are respectively connected with 2 connectors on the lower side of the outer side of the middle ring truss 222, and the connectors on other points on the inner side of the outer ring truss 212 are sequentially connected in this way to form the double-layer annular cross-woven cable net structure with radial annular arrangement. The advantage of this structure is that the connection is more stable, but because of the extra large amount of raw materials, the load effect needs to be considered compared with the cable net structure used by the dome of the super-large building.

Therefore, as shown in fig. 4, the single-layer annular cross-woven cable net structure is preferably adopted in the invention. Specifically, the steel cables 44 in the outer annular cross-woven cable net 411 are connected between the upper edge of the inner side of the outer ring truss 212 and the upper edge of the outer side of the middle ring truss 222; the steel cables 44 of the inner endless cross-woven cable net 412 are connected between the inner upper edge of the middle ring truss 222 and the outer upper edge of the inner ring truss 232. The steel cables 44 and the connected huge ring trusses all form a single-layer annular cross-woven cable net structure.

The steel cables 44 in the cross-woven cable net structure are not vertical and are all arranged in a cross manner, and 2 steel cables use double-layer cable clamps 43 at the crossing positions.

As shown in fig. 12 and 13, the double-layered rope clip 43 includes a double-layered rope clip base plate 431, a double-layered rope clip upper cover plate 432, and a double-layered rope clip lower cover plate 433, which are sequentially connected; a first wire rope hole is formed between the double-layer rope clamp base plate 431 and the double-layer rope clamp upper cover plate 432, and a second wire rope hole is formed between the double-layer rope clamp base plate 431 and the double-layer rope clamp lower cover plate 433; the first and second wire holes are disposed at an angle for connecting 2 intersecting wires 44.

The double-layer cable clamp 43 with different angles can be suitable for the intersecting condition of steel cables with any angle, and the double-layer cable clamp 43 has the advantages of small volume, simple structure, low manufacturing cost and good effect of fastening 2 steel cables with angles.

In the endless, cross-woven wire mesh structure of the present invention, the cross-woven intersections of the wire ropes 44 are connected by double layer clamps to form a wire mesh structure, which greatly improves the structural integrity as compared to each individual radial rope. Although the steel ropes 44 of the endless cross-weave structure are all straight ropes, diamond-shaped grids with rhythm sense can be formed by properly deflecting the angle of the steel ropes between adjacent ring trusses, and the upper surface of the formed roof is changed from straight lines to slightly concave curved surfaces, so that the structure is light and attractive.

The annular cross-woven rope net structure uses a steel rope material with the strength far higher than that of common steel, and a single-layer cross-woven rope net is arranged between adjacent annular trusses to form a dome of the large-span roof structure, so that the steel consumption is greatly reduced, the weight is light, and meanwhile, the adaptability of the dome roof to temperature change can be remarkably improved.

The cable network spacing density of the annular cross-woven cable network structure is adjustable, and the density can be set according to specific environments, so that the lateral rigidity of the super high-rise building structure is obviously improved.

Example 2:

a stereoscopic city dome.

The stereoscopic city dome of example 2, which is used as a stereoscopic city super high rise building roof, comprises a roof cable net unit 41 and an inflatable membrane unit 42. The roof cable net unit 41 includes the endless cross-woven cable net structure of embodiment 1, among others.

The inflatable membrane unit 42 is attached to the roof cable network unit 41 of the cross-woven annular cable network structure to form a roof of the three-dimensional city super high-rise building, namely a three-dimensional city dome, in particular a dome structure 4.

Preferably, the inflatable membrane unit 42 employs ETFE inflatable membrane ethylene-tetrafluoroethylene copolymer. On one hand, the ETFE inflatable film has light weight, good light transmittance, high strength, strong impact resistance and good heat preservation and insulation performance, can meet the requirements of natural light irradiation in a three-dimensional city, has good energy saving effect in the three-dimensional city, and can play a role in enclosing the internal environment of the three-dimensional city; on the other hand, the ETFE inflatable film can not drip and can self-extinguish when being burnt, thereby being beneficial to the fire safety of the three-dimensional city. Also, the roof cable net units 41 of adjacent annular trusses are high in inside and low in outside, which is beneficial to roof drainage.

As shown in fig. 16 and 17, by attaching the inflatable membrane units 42 to the outer annular cross-woven wire mesh 411 and the inner annular cross-woven wire mesh 412, a stereoscopic city dome, i.e., a dome structure 4 of a stereoscopic city with the center high tower 3 can be formed. The stereoscopic city dome is connected with the peripheral annular conjoined structure through the roof cable net unit 41, and the function of the stereoscopic city dome is equivalent to a cable rope (the roof cable net unit 41) of a tower mast structure (the central tower 3), and the multiple huge annular structures are connected into a whole, so that the lateral rigidity of the central high tower base can be effectively improved. The annular cross-woven rope net structure and the stereoscopic city dome structure formed on the basis thereof can be used as a roof at the periphery of a central high tower of a stereoscopic city, and can enable a central high tower foundation ring truss to be connected with the top of a huge annular structure at the outer side through the cross-woven rope net; the high tower in the stereoscopic city can play a role in symmetrically pulling and balancing damping while ensuring good lighting in the stereoscopic city, and can weaken or resist the influence of wind resistance, earthquake and other destructive forces.

The stereoscopic city dome of embodiment 2, namely dome structure 4, is integrally formed by a large-down and small-up body, which is beneficial to reducing the wind resistance area of stereoscopic cities and large-span buildings, reducing the influence of wind load and increasing the lateral rigidity of stereoscopic cities and large-span building structures.

Example 3

A kind of large-span building dome.

The large span building dome of example 3 is used as a roof for a large span building, comprising the stereoscopic city dome of example 2, and further comprising a large span roof unit 413 and an inflatable membrane unit (42) applied on the large span roof unit 413. Wherein, the roof cable wire net unit 41 included in the stereoscopic city dome of embodiment 2 includes the annular cross-woven cable net structure of embodiment 1.

Specifically, as shown in fig. 2 and 10, the large-span roof unit 413 of embodiment 3 adopts a single-layer housing structure, including a core spoke cable 4131 and a single-layer housing 4132; the single-layer housing 4132 is concentric with the inner ring truss 232, the same number of connectors 45 are provided on the outer side upper edge of the single-layer housing 4132 and the inner side upper edge of the inner ring truss 232, and two ends of the core spoke cable 4131 are respectively connected to the connectors 45 on the single-layer housing 4132 and the inner ring truss 232.

The inflatable membrane unit 42 is attached to the outer annular cross-woven wire mesh 411, the inner annular cross-woven wire mesh 412 and the core large-span roof unit 413.

As shown in fig. 1 and 10, the outer annular cross-woven wire mesh 411, the inner annular cross-woven wire mesh 412 and the large-span roof unit 413 together constitute a roof of a large-span building center square, forming a large-span building dome of example 3.

In connection with fig. 15, the large span building applied to the large span building dome of embodiment 3 further includes a building foundation 1, a giant ring structure.

The large-span super high-rise building forms a huge central square at the center of the inner ring tower body 231, and the large-span roof unit 413 is a roof thereon. The large span super high rise building forms an environmentally controlled space under the structure of the large span building dome of example 3.

The large-span building dome with the annular cross woven rope net structure can greatly break through the limitation of the span of the conventional rope structure by continuously arranging the multiple annular cross woven rope net structure, is suitable for large-span buildings covering millions of square meters and over super-large spaces, has a coverage area equivalent to tens of large-scale stadiums, and provides technical possibility for building urban-level super-large indoor space environments.

Example 4

Three-dimensional city super high-rise building.

The stereoscopic urban super high-rise building of example 4 includes a building foundation 1, a huge ring structure, a central high tower 3, and the stereoscopic urban dome of example 2. Wherein, the stereoscopic city dome is specifically a dome structure 4; the dome structure 4 includes the endless cross-woven wire mesh structure of embodiment 1.

The minimum inscribed circle diameter of the giant ring structure of embodiment 4 is not less than 200m. The huge annular structure has three layers in total and is arranged on three concentric rings respectively.

As shown in fig. 15, the huge ring structure of the three-dimensional city super high-rise building of embodiment 2 includes an outer ring tower group 21, a middle ring tower group 22 and an inner ring tower group 23. Each ring comprises a tower body and a ring truss. Each ring truss is arranged on the corresponding tower body.

Preferably, the bisecting plane of each ring truss is coplanar with the bisecting plane of the ring tower body.

As shown in fig. 2, 3 and 15, the outer ring tower group 21 includes an outer ring tower body 211 and an outer ring truss 212; the middle tower group 22 comprises a middle tower body 221 and a middle truss 222; the inner ring tower group 23 includes an inner ring tower body 231 and an inner ring truss 232.

Specifically, in embodiment 2, the outer ring tower body 211, the middle ring tower body 221 and the inner ring tower body 231 respectively include a plurality of tower bodies. Alternatively, the tower body may be one or more of a circle, a trapezoid, a fan, and other shapes.

Preferably, the plurality of tower bodies on the outer ring tower body 211, the middle ring tower body 221 and the inner ring tower body 231 are circumferentially and uniformly distributed, and the heights are the same. The heights of the tower bodies on the inner ring tower body 231, the middle ring tower body 221 and the outer ring tower body 211 are gradually reduced from inside to outside, and the radius difference between the middle ring tower group 22 and the inner ring tower group 23 is larger than the height difference between the inner ring tower body 231 and the middle ring tower body 221, and the radius difference between the outer ring tower group 21 and the middle ring tower group 22 is larger than the height difference between the middle ring tower body 221 and the outer ring tower body 211.

The number of tower bodies included on the inner ring tower body 231, the middle ring tower body 221, and the outer ring tower body 211 gradually increases from inside to outside.

Preferably, the number of tower bodies is increased from inside to outside in equal proportion.

Further preferably, the number of tower bodies is 1 from inside to outside: 2 equal ratio increases.

Further preferably, on one diameter line, 2 tower units are symmetrically arranged in each of the outer tower group 21, the middle tower group 22 and the inner tower group 23. The inner ring tower group 23 is circumferentially and uniformly provided with tower 6 seats, the middle ring tower group 22 is circumferentially and uniformly provided with tower 12 seats, and the outer ring tower group 21 is circumferentially and uniformly provided with tower 24 seats.

Specifically, as shown in fig. 15 and 16, the heights of the towers on the outer ring tower group 21, the middle ring tower group 22, and the inner ring tower group 23 are increased from the outside to the inside layer by layer. Preferably, the ratio of the difference in radius of adjacent rings to the difference in tower height is greater than 1.

As shown in fig. 5, 6 and 7, each tower body includes a tower and a core tube. The annular truss is built at the upper end of the core tube with the same ring. This allows the ring truss and its load to be transferred through the core barrel to the building foundation 1 without damaging the tower.

Specifically, fig. 8 shows a schematic illustration of a partial bisecting plane structure of the flattened inner ring building group 23, including an inner ring tower 231 and an inner ring truss 232; the inner ring tower body 231 comprises an inner ring tower and an inner ring tower core tube 233; the inner ring tower core tube 233 is disposed at the center of the inner ring tower. The inner ring tower core tube 233 and the inner ring tower are connected to the ring raft 12.

The top of the inner ring tower core tube 233 is higher than the inner ring tower body 231; the inner ring truss 232 is connected to the top of all of the inner ring turret core barrels 233 on the same ring through a ring truss structure. The inner ring tower core tube 233 forms a whole with the inner ring truss 232 on the inner ring tower body 231, and forms the tower foundation of the upper central high tower 3 together with the annular raft 12 and the inner ring pile foundation under the annular raft 12.

Similarly, the middle building group 22 includes a middle truss 222 and a middle tower body 221, and the middle tower body 221 includes a middle tower core tube 223 and a middle tower. The middle tower core barrel 223 is arranged in the middle tower; the middle ring truss 222 connects the tops of all middle ring tower core barrels 223 on the same ring on top of the middle ring tower body 221, thereby forming a whole, and the foundation of the part is the middle ring pile foundation 112 under each middle ring tower body 221.

Similarly, the outer ring building group 21 includes an outer ring truss 212 and an outer ring tower body 211, and the outer ring tower body 211 includes an outer ring tower core tube 213 and an outer ring tower. The outer ring tower core tube 213 is arranged in the outer ring tower, and the outer ring truss 212 connects the tops of all the outer ring tower core tubes 213 on the same ring on the top of the outer ring tower body 211, so as to form a whole, and the foundation of the part is the outer ring pile foundation 111 under each outer ring tower 231.

Preferably, outer ring truss 212, middle ring truss 222, and inner ring truss 232 of embodiment 2 are all annular cross-woven roof support structures.

Alternatively, as shown in fig. 9 and 15, an inner ring platform horizontal reinforcement layer 234 is built attached to the inner ring truss 232. The inner ring platform horizontal reinforcement layer 234 may act as a central shared lobby and also as a conversion platform during construction of the central high tower 3.

Optionally, multiple layers of towers may be further constructed above the middle ring truss 222 and the outer ring truss 212, such that the middle ring tower 221 and the outer ring tower 211 penetrate out of the dome structure 4 to the outside of the internal environment of the stereoscopic city.

The central tall tower 3 is built on top of the inner ring platform horizontal reinforcement layer 234 as in example 1.

On the basis of example 1, the building foundation 1 of example 2 includes a piled raft foundation 11 and a ring raft 12; the piled raft foundation 11 comprises an outer ring pile foundation 111, a middle ring pile foundation 112 and an inner ring pile foundation 113; the annular raft 12 is arranged on the inner annular pile foundation 113 in a surrounding manner.

As shown in fig. 15, the building foundation 1 includes a piled raft foundation 11 and a ring raft 12; the piled raft foundation 11 comprises an outer ring pile foundation 111, a middle ring pile foundation 112 and an inner ring pile foundation 113; the annular raft 12 is arranged on the inner annular pile foundation 113 in a surrounding manner.

As shown in fig. 19 and 20, the radial dimension of the annular raft 12 of embodiment 2 is preferably much larger than the maximum planar dimension of the inner ring tower 231 supported thereon, and the 6 inner ring towers 231 disposed at a remote distance are connected to a pile foundation. The inner ring pile foundation 113 is not only disposed under the inner ring tower body 231 but also under the entire ring raft 12, so that the effective pile distribution area is enlarged, thereby carrying a larger load. At the same time, the overall strength of the inner ring tower group 23 is effectively enhanced.

The annular raft 12 is adopted at the bottom of the inner ring tower group 23, which is equivalent to the construction of a continuous foundation beam, and the annular foundation of the annular raft 12 breaks through the conventional method that adjacent building structures with longer distances are provided with independent pile raft foundations. The continuous foundation beams of the annular raft 12 can disperse concentrated loads to the whole annular bearing platform, allow pile distribution area to be enlarged, and improve bearing capacity of the foundation. The pile distribution area is far larger than the projection area of the inner ring tower body 231, so that the problem that the area of a single raft is difficult to meet the pile distribution requirement in a high-tower low-area can be solved, the problem of insufficient bearing capacity of a foundation can be overcome, and a brand new thought is provided for greatly improving the building height.

The outer ring pile foundation 111 and the middle ring pile foundation 112 are respectively arranged below the outer ring tower body 211 and the middle ring tower body 221, and are all arranged discretely to form a common building foundation.

Example 5:

a three-dimensional city.

The stereoscopic city has a main body structure of the stereoscopic city super high-rise building of the embodiment 4. Wherein the stereoscopic city super high-rise building comprises a stereoscopic city dome, namely a dome structure 4, using the annular cross-woven cable net structure of example 1. Stereoscopic cities also include neighborhood and environmentally controllable spaces, and the like.

As shown in fig. 15 and 16, the stereoscopic city super high-rise building is a skeleton of a stereoscopic city.

Super high-rise buildings refer to high-rise buildings with a height exceeding 1000 m; the diameter of the minimum inscribed circle of the giant annular structure is not smaller than 200m.

Under the frame of super high-rise building, the stereoscopic city block is covered under the huge stereoscopic city dome (dome structure 4), and the environment-controllable space can be built. The environment-controllable space integrates the functions of living, working, business, hotel, travelling and the like, and an artificial climate environment is formed inside the environment-controllable space, so that a large amount of public spaces such as roads, greenbelts, rivers and the like can be built.

The huge annular structures of the super high-rise building can be round or a plurality of closed structures which are in any shape and are not intersected.

Preferably, the plurality of giant ring structures of the super high-rise building are respectively arranged on different rings of a group of concentric rings.

Further preferably, the plurality of huge annular structures of the super high-rise building are respectively arranged on different circles of a group of concentric rings.

Each ring comprises a plurality of tower bodies and 1 ring truss which are circumferentially arranged; the ring truss is annularly arranged at the top of a plurality of tower bodies arranged on the ring. Preferably, a plurality of tower bodies on each ring are uniformly distributed on the circumference.

Each ring truss can be built into an annular common space. The environment-controllable space can be provided with horizontal, vertical and inclined channels or even spiral channels as public spaces according to the main structures of the tower body and the ring truss so as to realize the traffic and evacuation channel network of the three-dimensional city cross intercommunication. Preferably, the channels are symmetrically arranged.

Preferably, the heights of the towers on the same ring are the same, and the ratio of the difference between the radii of adjacent rings to the height difference of the towers arranged on the two rings is more than 1. The connecting line of the tower heights on the same radius is a streamline curve from inside to outside.

The stereoscopic city dome (dome structure 4) of example 5 is disposed on a plurality of huge ring structures in smooth engagement with the bus bar of the central high tower 3.

As shown in fig. 15, specifically, the central high tower 3 is entirely constructed of steel to reduce the structural dead weight, and is divided into a high tower low zone 31, a high tower middle zone 32, a high tower high zone 33, and a mast zone 34.

Wherein, the high tower height area and the mast area are unmanned areas.

Wherein, the high tower is low, and 31 evenly arranges low district vertical support unit along the periphery, arranges a plurality of low district horizontal support units along the direction of height, and low district horizontal support unit constitutes high tower low district grid structure with low district vertical support unit jointly, has arranged low district cross bracing in succession on the facade of high tower low district grid structure to improve the side direction rigidity of central high tower 3 structure. The basic framework in the low area of the high tower is utilized to arrange a plurality of layers of floor beams, so that a floor structure with a using function is formed.

Wherein, the middle region 32 of the high tower is uniformly provided with a middle region vertical supporting unit and a middle region horizontal supporting unit along the peripheral direction, the middle region vertical supporting unit comprises a middle region core tube, and the middle region horizontal supporting unit and the middle region vertical supporting unit jointly form a grid structure of the middle region of the high tower; middle area cross support that is arranged in succession on the middle area grid structure facade in the high tower. The middle-zone horizontal support units, the middle-zone vertical support units and the middle-zone cross support together improve the lateral rigidity of the central high tower 3 structure. The middle-area horizontal support unit comprises a plurality of layers of middle-area floor beams, and the middle-area floor beams can form a floor structure with a using function.

The high tower high area 33 comprises a high area horizontal supporting unit, a high area truss column outer cylinder and a high area cross support, so that an integral frame structure of the high tower high area is formed. The high-area horizontal support unit comprises a plurality of layers of high-area floor beams, and forms a floor structure with the function of using equipment.

The mast area 34 adopts a truss column or lattice column structure for implementing telecommunication emission and monitoring of air temperature, sunlight and atmospheric quality. The highest point can be provided with a high point mark, and a lightning arrester is installed.

The central high tower 3 adopts a building shape with a large lower part and a small upper part, the height-width ratio of a using floor is strictly controlled, the height-width ratio H/B at the position of the high tower low region 31 is not more than 5, and the wind load and the earthquake effect can be obviously reduced. The high tower height area 33 and the mast area 34 at the upper part of the central high tower 3 adopt a high-efficiency giant truss-support system steel structure system, so that the structural dead weight can be remarkably reduced. The self-weight of the main body de steel structure of the central high tower 3 can be reduced, the self-vibration period is shortened, and the wind vibration response is effectively controlled.

The building foundation 1 of the super high-rise building comprises a piled raft foundation 11 and annular rafts 12; the annular raft 12 is arranged at the bottom of a tower body on the central ring in a surrounding manner, under a tower without the annular raft 12, a pile raft foundation 11 is arranged under each tower body, under a tower with the annular raft 12, the pile raft foundation 11 is arranged at the lower part of the whole annular raft 12; or the building foundation 1 is provided with a plurality of annular raft plates 12, and the plurality of annular raft plates 12 are respectively and continuously arranged at the bottoms of a plurality of giant annular structure tower bodies at the inner side.

Preferably, a plurality of structure conversion layers are also arranged in the vertical direction in the giant annular structure on the center ring of the super high-rise building. The structural conversion layer comprises an annular conversion truss and a conversion platform. The conversion platforms are built on corresponding annular conversion trusses. The structure conversion layer can be used as a working platform during construction, and building materials and components are lifted from the ground to the conversion platform and then are installed through the tower crane. Meanwhile, the structure conversion layer can disperse the vertical load of the giant annular structure on the center ring to the bottoms of the tower bodies on the plurality of center rings at the lower part, so that the balance control of the vertical load born by each super high-rise building is facilitated; the structure conversion layer can also be used as a relay transfer platform of a huge annular structure on the center ring, and is a huge space for multi-functional use such as business, catering, personnel gathering and distributing.

The present invention is not limited to the above-mentioned embodiments, and any changes or substitutions that are easily contemplated by those skilled in the art within the scope of the present invention are intended to be included in the scope of the present invention. Meanwhile, all equipment with the device for expanding the application field and producing the composite technical effect belong to the protection scope of the method.

Claims (7)

1. The annular cross-woven cable net structure is characterized by comprising a giant ring truss, a roof cable net unit (41) and a connector (45); the huge ring trusses are arranged at the top end of the annular building group, and the roof cable net units (41) are connected between the adjacent huge ring trusses through the connectors (45);

the annular building groups are concentrically arranged and are divided into an inner annular tower group (23), an intermediate annular tower group (22) and an outer annular tower group (21); correspondingly, the huge ring truss is divided into an inner ring truss (232), a middle ring truss (222) and an outer ring truss (212);

the roof cable net unit (41) comprises a cable rope (44) and a cable clip;

the roof cable net unit (41) comprises an outer annular cross braided cable net (411) and an inner annular cross braided cable net (412), and the outer annular cross braided cable net (411) and the inner annular cross braided cable net (412) are respectively connected between the adjacent huge ring trusses in an annular radial manner;

the outer annular cross-woven rope net (411) and the inner annular cross-woven rope net (412) form a single-layer annular cross-woven rope net structure or a double-layer annular cross-woven rope net structure;

the steel ropes (44) in the outer annular cross woven rope net (411) are connected between the upper edge of the inner side of the outer ring truss (212) and the upper edge of the outer side of the middle ring truss (222); the steel ropes (44) of the inner annular cross-woven rope net (412) are connected between the upper edge of the inner side of the middle ring truss (222) and the upper edge of the outer side of the inner ring truss (232); the steel ropes (44) and the connected huge ring trusses form the single-layer annular cross-woven rope net structure;

the same number of connectors (45) are arranged on the adjacent huge ring trusses, and the connectors (45) are circumferentially and uniformly distributed on the edges of the huge ring trusses; -each of said connectors (45) on the same said huge ring truss being connected to a first end of 2 said cables (44); the second ends of 2 steel ropes (44) are connected to different connectors (45) of the adjacent huge ring trusses and are symmetrically arranged relative to the first ends; -every 2 intersecting said wires (44) are connected at an intersection by said clamps;

the cable clamp is a double-layer cable clamp (43);

the diameter of the minimum inscribed circle of the giant ring truss is larger than 200m.

2. The annular cross-woven wire mesh structure of claim 1, wherein the outer annular cross-woven wire mesh (411) is disposed between an inner side of the outer ring truss (212) and an outer side of the middle ring truss (222); the inner annular cross-woven wire mesh (412) is disposed between the inner side of the middle ring truss (222) and the outer side of the inner ring truss (232).

3. The endless cross-woven cable net structure according to claim 2, characterized in that the double-layered cable clamp (43) includes a double-layered cable clamp base plate (431), a double-layered cable clamp upper cover plate (432), and a double-layered cable clamp lower cover plate (433) connected in this order; a first steel rope hole is formed between the double-layer rope clamp base plate (431) and the double-layer rope clamp upper cover plate (432), and a second steel rope hole is formed between the double-layer rope clamp base plate (431) and the double-layer rope clamp lower cover plate (433); the first and second wire rope holes are used for connecting 2 crossed wire ropes (44).

4. An endless, cross-woven wire-mesh structure according to claim 3, characterized in that the roof wire-mesh unit (41) further comprises a large span roof unit (413).

5. A long span construction dome for use as a long span construction roof, comprising an endless cross-woven wire mesh structure as claimed in any one of claims 1-4 and an inflatable membrane unit (42), said inflatable membrane unit (42) being attached to a roof wire mesh unit (41) of said endless cross-woven wire mesh structure.

6. A stereoscopic urban dome for use as a roof for a stereoscopic urban high-rise building, characterized in that the stereoscopic urban dome comprises a roof cable network unit (41) and an inflatable membrane unit (42); the roof cable net unit (41) uses the annular cross-woven cable net structure as claimed in any one of claims 1 to 4, and the inflatable membrane unit (42) is attached to the roof cable net unit (41).

7. A stereoscopic urban super high-rise building comprising the stereoscopic urban dome of claim 6.

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