CN111270755A - Vertical greening intelligent assembling structure based on active energy dissipation technology - Google Patents

Abstract

The invention relates to a brand new intelligent vertical greening structure, in particular to an ultra-light intelligent assembling structure for vertical greening based on an active energy dissipation technology, which solves the problems of heavy bearing keels, complex installation, low safety, inconvenient maintenance, single function and the like in the existing VGT technology. An ultra-light vertical greening intelligent assembling structure based on an active energy dissipation technology comprises two triangular energy dissipation support frames, wherein the two triangular energy dissipation support frames are connected through an upper chord and a lower chord; the triangular energy dissipation support frame comprises two square energy dissipation pipes, a rectangular energy dissipation pipe, a vertical rod and two inclined rods, wherein the two square energy dissipation pipes and the rectangular energy dissipation pipe form three vertexes of the triangular energy dissipation support frame, and the vertical rod and the two inclined rods form three sides of the triangular energy dissipation support frame; and a lower bearing plate is arranged between the inclined rods of the two triangular energy dissipation support frames positioned at the lower part.

Description

Vertical greening intelligent assembling structure based on active energy dissipation technology

Technical Field

The invention relates to a brand new intelligent vertical greening structure, in particular to an ultra-light vertical greening intelligent assembling structure based on an active energy dissipation technology.

Background

The vertical greening structure vgt (vertical Green technology) is used for shading the sun of an outer wall and reducing the temperature of the surface of the wall at first, and then the pressure of the vertical greening structure is increased with the increasing of urban heat island effect, global warming, air pollution, high-rise fire prevention, high-altitude parabolic and falling, comprehensive disaster reduction and relief and the like, while the vertical greening structure plays more and more obvious roles in the comprehensive protection functions of relieving the urban heat island effect, adjusting urban microclimate, improving the environmental comfort, optimizing urban energy utilization, reducing urban disease propagation, resisting falling of the high-altitude outer wall and foreign object impact and the like, and the vertical greening technology obtains general attention of developed countries, develops the outer wall vertical greening structure and system with convenient loading and unloading and outstanding intelligent characteristics, and becomes an important content for research and competition of healthy intelligent cities.

With the development of vertical greening structure from low-rise to high-rise space application, the existing vertical greening structure has the problems of heavy bearing keel, complex installation, low safety, inconvenient maintenance, single function and the like, and is difficult to reach the key technology and the corresponding standard required by the demand.

Therefore, the VGT structure and the core control technology which are suitable for the high-rise unconventional space curved surface and have intelligent characteristics are researched and developed, are key neckerchief technologies for mastering and leading international competition of VGT market, are also very important cross comprehensive innovation technologies for realizing green and healthy development and improving the energy consumption quality of building structures in China, are comprehensive innovations carried out for solving the key technologies, and have extremely important effects on the country and the society due to application and popularization.

Disclosure of Invention

The invention provides an ultra-light vertical greening intelligent assembling structure based on an active energy dissipation technology, which solves the problems of heavy bearing keel, complex installation, low safety, inconvenient maintenance, single function and the like in the conventional VGT technology.

The technical scheme for solving the problems is as follows:

an ultralight vertical greening intelligent assembling structure based on an active energy dissipation technology is characterized in that:

the energy-saving support comprises two triangular energy-consuming support frames, wherein the two triangular energy-consuming support frames are connected through an upper chord and a lower chord;

the triangular energy dissipation support frame comprises two square energy dissipation pipes, a rectangular energy dissipation pipe, a vertical rod and two inclined rods, wherein the two square energy dissipation pipes and the rectangular energy dissipation pipe form three vertexes of the triangular energy dissipation support frame, and the vertical rod and the two inclined rods form three edges of the triangular energy dissipation support frame, wherein two ends of the vertical rod are respectively connected with the two square energy dissipation pipes; the two square energy dissipation pipes are respectively fixed on the wall body through wall plates;

an upper chord is connected between the square energy consumption pipes positioned at the upper parts of the two triangular energy consumption support frames, and a lower chord is connected between the rectangular energy consumption pipes of the two triangular energy consumption support frames; an upper bearing plate is arranged between the inclined rods of the two triangular energy dissipation support frames positioned on the upper portion, and a lower bearing plate is arranged between the inclined rods of the two triangular energy dissipation support frames positioned on the lower portion.

Further, the initial included angle of two adjacent edges of the triangular energy-consumption support frame is 60 degrees, and the angle is independently adjustable.

Furthermore, the end parts of the vertical rod and the diagonal rod are fixed on the square energy dissipation pipe or the rectangular energy dissipation pipe through two vertical rod connecting pieces or diagonal rod connecting pieces, the vertical rod connecting pieces and the diagonal rod connecting pieces are special bending plates designed for fatigue resistance, the bending plates are connected on the square energy dissipation pipe or the rectangular energy dissipation pipe through bolts, the end parts of the vertical rod and the diagonal rod are positioned between the two bending plates and connected through high-strength anti-loosening bolts, the high-strength anti-loosening bolts are arranged on stiffening rib components of the high-strength anti-loosening bolts and positioned among the vertical rod, the diagonal rod and the bending plates, and the high-strength anti-loosening bolts are simultaneously provided with anti-loosening reverse clamping vulnerable gaskets; the anti-loosening reverse-clamping easy-to-wear gasket comprises two gaskets, and the contact part of the two gaskets is provided with specially-designed variable-curve oblique sawteeth.

Furthermore, the upper bearing plate is provided with a round hole for placing a green plant container, and a special wearing part for the cambered surface is arranged on the upper bearing plate close to the round hole.

Furthermore, the triangular energy dissipation support frame is made of magnesium-aluminum alloy.

The invention has the advantages that:

1) through a special active energy dissipation node technology, external load acting can be actively converted through the internal curved surface energy consumption of the node with short delay and deformation amplitude according to the structural stress and deformation, so that the unfavorable deformation of the structure is controlled, and the VGT has a good intelligent characteristic of actively resisting the load;

2) the modified magnesium-aluminum alloy with high specific strength and specific rigidity is adopted, so that the VGT structure has excellent strength-to-mass ratio, is light and convenient to assemble, disassemble and maintain;

3) the VGT structure is designed by adopting a temporary structure theory, is combined with pneumatic shape finding, implements full-section optimization, can quickly adapt to various wind environments, has an optimal topological form of node area stress self-regulation, and provides a full-hinge node supporting technology, so that the VGT structure has high reusability;

4) based on K, T, Y and pin roll nodes for energy consumption of the internal structure of the embedded hyperbolic paraboloid, the novel VGT technology can be customized according to different stages of load and different curved surfaces of an outer wall and needs, can provide a quantitative bending working frequency range and a fatigue life, can work safely in a stress whole life range, is convenient to replace energy-consuming wearing parts, and has excellent durability;

5) the VGT full-hinge node control processing technology based on the integral assembly interference detection and collision error distribution algorithm enables the integral assembly type integral installation of the VGT to determine the optimal gap between assembly and service of all nodes in advance, gives out the optimal error mode of customized load deformation control of the VGT structure, enables the inclination of the main bearing panel to effectively avoid out-of-plane torsional damage, and forms a structural edge form which is beneficial to reducing self-excited vibration caused by bearing plate galloping and plant containers.

Drawings

FIG. 1 is a VGT design principle of the present invention;

FIG. 2 is a block diagram of the present invention;

FIG. 3 is a left side view of FIG. 2;

FIG. 4 is a structure view of a triangular energy-consuming support frame;

figure 5 is an energy dissipating node at a in figure 2;

figure 6 is a pin shaft energy dissipation node structure diagram at B in figure 3;

FIG. 7 is an enlarged view of a hyperbolic paraboloid energy dissipating member;

FIG. 8 is a view of a wearing part dedicated to the cambered surface;

fig. 9 is a view of the structure of the anti-loosening reverse clamping vulnerable gasket.

1-upper bearing plate; 2-a lower bearing plate; 3-upper chord; 4-a lower chord; 5-vertical rod; 6-diagonal rod; 8-K shaped nodes; 9-special wearing parts for cambered surfaces; 10-rectangular energy dissipation pipes; 11-square energy dissipation pipes; 12-diagonal bar connection; 13-a vertical bar connecting piece; 14-wall connectors; 15-pasting a wallboard; 16-hyperbolic paraboloid energy dissipating components; 17-high strength lockbolt; 18-loosening prevention and reverse clamping of the vulnerable gasket; 19-a bearing plate connection member; 20-mounting holes for wearing parts with cambered surfaces; 21-oblique saw teeth.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the embodiments of the present invention will be described accurately and completely with reference to the accompanying drawings, and it is to be understood that the described embodiments are some, but not all embodiments of the present invention. All other embodiments, which can be obtained by a person skilled in the art without any inventive step based on the embodiments of the present invention, are within the scope of the present invention. Thus, the following detailed description of the embodiments of the present invention, presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. All other embodiments, which can be obtained by a person skilled in the art without any inventive step based on the embodiments of the present invention, are within the scope of the present invention.

Referring to fig. 2-7, an ultra-light vertical greening intelligent assembling structure based on active energy dissipation technology comprises two triangular energy dissipation support frames, and the two triangular energy dissipation support frames are connected through an upper chord 3 and a lower chord 4.

The triangular energy dissipation support frame comprises two square energy dissipation pipes 11, a rectangular energy dissipation pipe 10, a vertical rod 5 and two inclined rods 6, wherein the two square energy dissipation pipes 11 and the rectangular energy dissipation pipe 10 form three vertexes of the triangular energy dissipation support frame, the vertical rod 5 and the two inclined rods 6 form three sides of the triangular energy dissipation support frame, and two ends of the vertical rod 5 are respectively connected with the two square energy dissipation pipes 11; the two square energy dissipation pipes 11 are respectively fixed on the wall body through the wall pasting plates 15.

An upper chord 3 is connected between square energy consumption pipes 11 positioned at the upper parts of the two triangular energy consumption support frames, and a lower chord 4 is connected between rectangular energy consumption pipes 10 of the two triangular energy consumption support frames; an upper bearing plate 1 is arranged between the oblique rods 6 on the upper portion of the two triangular energy dissipation support frames, and a lower bearing plate 2 is arranged between the oblique rods 6 on the lower portion of the two triangular energy dissipation support frames.

The initial included angle of two adjacent sides of the triangular energy-consuming support frame is 60 degrees. The vertical greening intelligent assembling structure is made of magnesium-aluminum alloy.

The tip of montant 5 and down tube 6 is fixed on square power consumption pipe 11 or rectangle power consumption pipe 10 through two montant connecting piece 13 or down tube connecting piece 12, montant connecting piece 13, down tube connecting piece 12 are the plate of buckling, and the plate of buckling passes through the bolt fastening on square power consumption pipe 11 or rectangle power consumption pipe 10, and the tip of montant 5 and down tube 6 is located and connects through high strength check bolt 17 between two plates of buckling, lies in on the high strength check bolt 17 that to be equipped with hyperbolic paraboloid power consumption piece 16 between montant 5, down tube 6 and the plate of buckling, is equipped with the quick gasket 18 of the reverse chucking of locking of preventing moving on the check bolt 17 of excelling in. Referring to fig. 9, the anti-loosening reverse-clamping vulnerable gasket 18 comprises two washers, the contact part of the two washers is provided with oblique saw teeth 21 in opposite directions, and two outer surfaces of the two washers are respectively welded on the bent plate and the high-strength anti-loosening bolt 17.

The upper bearing plate 1 is provided with a round hole for placing green plants, a wearing part 9 special for the cambered surface (see figure 8) is arranged on the upper bearing plate 1 near the round hole, and two ends of the wearing part 9 special for the cambered surface are provided with mounting holes 20 for the wearing part for the cambered surface.

Referring to fig. 1, in the manufacturing process, firstly, grading the service load of the VGT structure according to the environmental parameters customized by a user, determining the design values of internal force and deformation, and selecting a reasonable magnesium-aluminum alloy material and a modification process thereof; secondly, carrying out pneumatic shape finding on the VGT structure to determine an optimal wind-resistant section; designing parameters of a hyperbolic paraboloid of an internal active energy dissipation structure of the VGT and a connection mode according to the energy consumption index of the VGT; and then, determining an overlapping inspection path and mode of the VGT structural part by using a VGT integral assembling and disassembling error control algorithm, giving numerical control machining parameters and error control accuracy of customized accuracy after eliminating collision, finally debugging the initial positions of the adjustable main bearing plate, the core connecting piece and the wearing part, and finally giving the rated parameters and performance indexes of the VGT through wind load simulation inspection.

According to the design scheme of the VGT, the technical scheme and the implementation way of the novel VGT intelligent structure provided by the invention are as follows:

1. ultra-light VGT structure technology

The VGT ultra-light structure mainly comprises 3 technologies, wherein the light high-strength magnesium-aluminum alloy-rare earth material with good specific strength and specific rigidity is adopted, all VGT components are connected through deformation controllable hinges, and the VGT ultra-light structure is designed based on a temporary structure assembly theory.

In order to improve the strength-to-mass ratio of the VGT to the maximum extent, the invention adopts a magnesium-aluminum alloy-rare earth material, and an aluminum alloy formed after the treatment of an improved T6 process is used as a base material, thereby greatly reducing the weight of the VGT structure. Based on a temporary assembly structure theory, a section and component global optimization algorithm is adopted, the VGT structure is subjected to optimization design according to load grading and deformation control degrees, optimal form design under the structure safety condition is guaranteed, and the impact stress bearing capacity of the structure under the action of shear stress is improved by pre-tensioning a plate sub-structure in combination with a specially designed full-hinge joint, so that the functional section size of the main structure is reduced, and the weight of the VGT structure is reduced to the maximum extent.

2. VGT reusable unit full-hinge node design based on temporary structure theory

The VGT structure energy dissipation is an active energy dissipation mode, mainly accomplishes the energy dissipation function through the full hinge node of special design to through interim structure theory, hierarchical to the load, adopt VGT to warp global optimum and local stress control's optimization calculation, carried out the novel inner structure design based on node vulnerable component to the reusable component, this technique is not only full hinge node not only becomes the main device of control VGT static and dynamic deformation, also is the reusable basic assurance of VGT structure.

3. VGT intelligent energy dissipation node design

The energy dissipation node is an important component of a VGT structure full-hinge node and consists of a peripheral aluminum alloy main material and an internal limiting energy dissipation structure. The node appearance adopts whole stamping forming technology, and is connected through cup joint and round pin axle cover, divide into rectangle and board-like two kinds of connections.

The energy dissipation structure adopts hyperbolic paraboloids as energy dissipation parts, 2-4 energy dissipation secondary base planes are embedded in each node, a curved surface single parabolic surface is fixedly connected with the interior of each node, the rest are free ends, work done by external force is quickly consumed through deformation of the curved surface, and the stable structure of the VGT is kept.

All component dimensions were checked by Inventor and xstel interference and collision, and then output a numerical control validation interface file, made by numerical control machining equipment.

4. Wind-resistant design of adjustable inclined strut and inclined panel of VGT

Because the VGT can be in service at the outer wall of higher floor, through calculating VGT structure wind-load, utilize Y, T and K special initiative energy dissipation node and triangle support connecting piece with initial 60 structure tilt panel, as the basic holding surface of growth of green planting, along with the growth of green planting, combine non-contact image recognition data's intelligence supplementary, through the angle of adjusting the down tube, realize that the VGT structure is anti-wind, the plant promotes easy, the optimal structure geometry and the low energy consumption system of whole management.

The invention mainly comprises intelligent energy dissipation node material selection and structure, quick assembly and disassembly of the integral structure of the VGT, reusable controllable technology, integral section shape finding of the VGT structure and self-excited vibration resistance design, and the contents of the invention are respectively explained in detail below.

1. Intelligent energy dissipation node structure design

The intelligent energy dissipation node design mainly comprises the following processes of node appearance selection. Because the VGT node can bear impact and large wind load, firstly, a deformation threshold value of a structure in a normal use limit state is obtained through a calculation model established by ABAQUS on the appearance of the node, the structural shape and boundary size under the limit staged load of the VGT structural node are given, after the design internal force of the section of the VGT node is determined, for a temporary VGT, 2 years or 4 years are taken as the design years according to the customized service life of a user, based on the principle that the total weight is lightest or the section of a bearing plate and the section of the node is optimal, based on the temporary structural design theory, the specific rigidity and the specific strength value of the magnesium-aluminum alloy are selected, accordingly, a T6 deformation magnesium-aluminum alloy post-treatment strengthening process is given, under the condition of giving higher quenching temperature and linear change quenching rate, the 3-level aging is adopted to prolong the heat preservation time of deformation of the magnesium-aluminum alloy, so that the magnesium-aluminum alloy used by the VGT, by adding a proper amount of rare earth containing copper and manganese elements, the special high-strength corrosion-resistant VGT magnesium-aluminum alloy material is formed, and a special aluminum alloy energy dissipation node manufacturing material is provided for meeting customized requirements.

After the work is finished, according to the energy consumption index of the VGT, determining the area of a hyperbolic paraboloid (saddle surface) in the node, consolidating the parabolic surface and the hyperbolic surface on one side of the saddle surface in the inside of the lap joint node, keeping the other side of the saddle surface free, determining the connection curve length of Y, T, the K-shaped node and the energy-consuming paraboloid in the pin shaft node according to different energy consumption distribution, and making the inner saddle surface of the triangular energy-consuming support frame node for controlling the left and right swing of the VGT into a 2-4-layer multi-surface superposition form according to the requirement; to prevent that the crossing current of VGT bearing plate in the wind from surging and shaking, the assembly scheme sets up flat saddle face in the round pin axle node, and the pneumatic appearance of cooperation main loading board realizes the rapid stabilization under unfavorable wind carried and the impact load.

Besides actively dissipating external force from the structure dynamic load response, the VGT intelligent active energy consumption node accurately feeds back the extracted high-precision structure dynamic deformation information to an energy consumption saddle surface node deformation overlapping area inside the node through a non-contact image transmission technology, a mechanism control system for node deformation energy consumption is implemented in advance, and an active energy consumption mechanism of the VGT structure is started through load information, so that the safety, durability and stability of the VGT structure in high-rise service are guaranteed to the maximum extent.

2. VGT reusable assembling structure design

The VGT assembling structure is shown in figure 2, adopts a temporary structure assembling theory, consists of a triangular energy-consuming support frame, a chord member and a bearing panel, and is assembled through a high-strength anti-loose bolt 17.

The triangular energy dissipation support frame is shown in figure 3 and comprises a web member, a wall pasting plate 15, energy dissipation pipes and node connecting pieces, wherein the web member is composed of two inclined rods 6 and a vertical rod 5, the inclined rods and the vertical rod intersect to form an initial angle of 60 degrees in a plane, the energy dissipation pipes and the corresponding connecting pieces are connected to form Y, T-shaped nodes (A in figure 2) and K-shaped nodes 8 respectively, a bearing plate is connected with the triangular energy dissipation support frame through pin shaft nodes, hyperbolic paraboloid energy dissipation pieces 16 are arranged inside the nodes, and the VGT energy dissipation node structure is shown in figures 4 and 5.

The VGT reusable technology is completed by designing specially connected wearing parts. The initiative of VGT energy consumption makes VGT triangle-shaped energy consumption support K, Y, T and the low cycle fatigue characteristic of round pin axle node more outstanding, and the inside of energy consumption node can take place great reciprocating motion under some loads simultaneously, consequently has the characteristic of big amplitude low cycle fatigue concurrently, considers VGT's concatenation accumulative damage simultaneously, in the junction between plant container and the panel, has designed special vulnerable component 9 of cambered surface, has designed the locking reverse chucking vulnerable gasket 18 at K, Y, T and round pin axle node, through the design of these two kinds of special vulnerable components, guarantees the purpose of VGT used repeatedly 1000 times.

3. Integral section and self-excited vibration resistance design of VGT structure

The self-excited vibration is a more serious damage form of the VGT in a high-rise outer wall, and is mainly caused by the pressure difference at the sharp change position of the wind section due to the blunt body shape of the plant container and the thinner bearing plate. In order to overcome the self-excited vibration caused by the wind load and avoid triggering subsequent galloping, the invention carries out wind vibration resisting design on the VGT, the plant container and the plant classification, combines the pneumatic characteristics and the wind sensitivity parameters of the plant container, the inclined bearing plate and the plant quality and state distribution on the basis of pneumatic shape finding, and designs the semi-arc angle and the inverted frustum-shaped plant container of the VGT main bearing panel on the basis of the pneumatic coupling sensitivity analysis of the plant container, the inclined bearing plate and the plant quality and state distribution in a full-hinge connection state. According to the VGT customization requirement, the possible frequency distribution range of plants is taken as frequency modulation reference, the weight distribution of soil and moisture in the plant containers is determined by a frequency-dependent nonlinear vibration calculation method, the distances and the number of the plant containers in the main bearing plate are arranged at unequal intervals, so that the geometrical negative damping which possibly occurs to the whole VGT structure and the section of the VGT structure under the impact and wind load double nonlinear dynamic action is reduced to the maximum extent, and the stability of the structure under the large wind load is maintained to the maximum extent.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the present invention, and those skilled in the art can still make modifications to the technical solutions described in the above embodiments, or make equivalent substitutions for some technical features. Therefore, if such modifications and variations of the present invention fall within the scope of the claims of the present invention and their equivalents, the present invention is also intended to include such modifications and variations.

Claims (5)

1. The utility model provides an ultralight vertical greening intelligence spelling structure based on initiative energy dissipation technique which characterized in that:

the energy-saving support comprises two triangular energy-consuming support frames, wherein the two triangular energy-consuming support frames are connected through an upper chord (3) and a lower chord (4);

the triangular energy-consuming support frame comprises two square energy-consuming tubes (11), a rectangular energy-consuming tube (10), a vertical rod (5) and two inclined rods (6), wherein the two square energy-consuming tubes (11) and the rectangular energy-consuming tube (10) form three vertexes of the triangular energy-consuming support frame, the vertical rod (5) and the two inclined rods (6) form three sides of the triangular energy-consuming support frame, and two ends of the vertical rod (5) are respectively connected with the two square energy-consuming tubes (11); the two square energy dissipation pipes (11) are respectively fixed on the wall body through wall pasting plates (15);

an upper chord (3) is connected between square energy dissipation pipes (11) positioned at the upper parts of the two triangular energy dissipation support frames, and a lower chord (4) is connected between rectangular energy dissipation pipes (10) of the two triangular energy dissipation support frames; the energy-consuming support frame is characterized in that an upper bearing plate (1) is arranged between the inclined rods (6) of the two triangular energy-consuming support frames positioned on the upper portion, and a lower bearing plate (2) is arranged between the inclined rods (6) of the two triangular energy-consuming support frames positioned on the lower portion.

2. The ultra-light vertical greening intelligent assembling structure based on the active energy dissipation technology as recited in claim 1, wherein:

the initial included angle of two adjacent sides of the triangular energy-consuming support frame is 60 degrees.

3. The ultra-light vertical greening intelligent assembling structure based on the active energy dissipation technology as recited in claim 2, wherein:

the end parts of the vertical rod (5) and the diagonal rod (6) are fixed on the square energy consumption pipe (11) or the rectangular energy consumption pipe (10) through two vertical rod connecting pieces (13) or diagonal rod connecting pieces (12), the vertical rod connecting pieces (13) and the diagonal rod connecting pieces (12) are bent plates, the bent plates are fixed on the square energy consumption pipe (11) or the rectangular energy consumption pipe (10) through bolts, the end parts of the vertical rod (5) and the diagonal rod (6) are positioned between the two bent plates and connected through a high-strength anti-loosening bolt (17), a hyperbolic paraboloid energy consumption piece (16) is arranged on the anti-loosening high-strength bolt (17) and positioned between the vertical rod (5), the diagonal rod (6) and the bent plates, and an anti-loosening reverse clamping vulnerable gasket (18) is arranged on the high-strength anti-;

the anti-loosening reverse clamping easy-damage gasket (18) comprises two gaskets, and the contact part of the two gaskets is provided with oblique saw teeth (21).

4. The ultra-light vertical greening intelligent assembling structure based on active energy dissipation technology as claimed in claim 3, wherein:

the green plant cultivation container is characterized in that a round hole is formed in the upper bearing plate (1) and used for placing a green plant container, and a special wearing part (9) for the cambered surface is arranged on the upper bearing plate (1) close to the round hole.

5. The ultra-light vertical greening intelligent assembling structure based on active energy dissipation technology as claimed in claim 4, wherein:

the triangular energy dissipation support frame is made of magnesium-aluminum alloy.

Images