CN106284673A - The most double-deck flexible rack film combinative structure - Google Patents

Abstract

The invention discloses the most double-deck a kind of flexible rack film combinative structure, be made up of bottom radial telescopic net structure and upper membrane structure, grid structure is made up of plural hoop chain scissor mechanism and plural radial direction bilayer chain scissor mechanism；Radial telescopic net structure is divided into continuous print Bu Mo district each other on the projection surface, and Bu Mo district includes interior tetragon, the first middle tetragon, the second middle tetragon and outer tetragon；Membrane structure is made up of the first film unit, the second film unit and tertiary membrane unit, and described first film unit, the second film unit and tertiary membrane unit are formed by the film material of montant and overlying.The present invention is synchronized to stretch by the most double-deck chain scissor mechanism and hoop chain scissor mechanism, the membrane structure with montant described in the employing of top, so that rack film combinative structure is flexible freely, expansion and contraction is big, structure is reasonable, design and construct simple, is particularly suitable for the building of medium and small span.

Description

The most double-deck flexible rack-film combinative structure

Technical field

The present invention relates to a kind of radial deployable rack-film combinative structure with the most double-deck chain scissor mechanism, and It it is a kind of radial telescopic net-film combinative structure with top montant.

Background technology

Deployable structure is a kind of new structure grown up nearly over half a century, in aerospace, building structure and military work The fields such as journey play an important role.Being mainly characterized by of deployable structure has two kinds of stable configurations: completely folded state and complete Entirely organize work state.When folded state, structure is drawn at a certain given shape, under the effect of extraneous driving force, and structure Progressively launch, reach fully deployed duty, be then locked as steady statue.This structure becomes tight after folding completely Bundle shape, be sufficiently spread out fixing after reach original operating state, it is possible to cover bigger space.

Film grid structure can be opened up and mixed the feature of deployable structure and membrane structure.Can open up film grid structure uses membrane material to have Many advantages:

1) from heavy and light.The weight of film material only has 1.3-1.5kN/m², the reduction of grid structure weight, make bottom supporting construction and The cross dimensions on basis can also reduce accordingly, is substantially reduced construction costs.

2) reduce energy resource consumption, save expense.Film material light transmittance is generally dependent on material and coating, and range is from almost 100% transparent to the opaquest.The light transmittance of common buildings film material about 15%, even if so complete grid structure can be opened up Also can make full use of nature light during expansion, daytime, use can reduce artificial lighting.

3) speed of application is fast.

Summary of the invention

The invention provides that a kind of vertical rigidity is good, shrinkage factor big and simple in construction be prone to the radial telescopic net that folds- Film combinative structure.Meet the various functions requirement built grid structure can be opened up, also there is the advantages such as design and easy construction.

For reaching above-mentioned purpose, the technical solution used in the present invention is:

The most double-deck a kind of flexible rack-film combinative structure, this combinative structure is by bottom radial telescopic net structure and upper membrane Structure forms, it is characterised in that described radial telescopic net structure by plural hoop chain scissor mechanism and two with On radial direction bilayer chain scissor mechanism composition, hoop chain scissor mechanism arranged concentric, radially double-deck chain scissor mechanism edge The radial arrangement of the annulus that described hoop chain scissor mechanism is formed；Hoop chain scissor mechanism is cut with scissors by multiple hoop symmetry scissors Unit is connected to annular end to end；The most double-deck chain scissor mechanism is made up of the horizontal chain scissor mechanism of two-layer up and down alignd, Wherein every layer of chain scissor mechanism is connected to linear by multiple radial symmetric scissors hinge unit end to end；Described hoop symmetry scissors are cut with scissors Formed by the first connecting rod that two length is equal is hinged in the middle of bar, described radial symmetric scissors hinge by two length equal the Two connecting rods are hinged composition in the middle of bar；Two-layer horizontal chain scissor mechanism is radially descended to pass through with hoop chain scissor mechanism respectively In the middle part of the second connecting rod of radial symmetric scissors hinge unit, the hinged realization in first connecting rod end with hoop symmetry scissors hinge unit connects Connect.

Described radial telescopic net structure is divided into continuous print Bu Mo district each other, described Bu Mo district to include interior four on the projection surface Limit shape, the first middle tetragon, the second middle tetragon and outer tetragon；

The radially double-deck chain scissor mechanism of described interior tetragon is symmetrical, and four summits of described interior tetragon include adjacent three Individual radial direction bilayer chain scissor mechanism and first summit of the hoop hinged formation of chain scissor mechanism of inner side, the second summit and Three summits, and it is positioned at radial direction bilayer chain scissor mechanism and the hinge of hoop chain scissor mechanism of the second summit and radially adjoining The 4th summit that the midpoint of contact is constituted；

The radially double-deck chain scissor mechanism of described outer tetragon is symmetrical, and four summits of described outer tetragon include adjacent three Individual radial direction bilayer chain scissor mechanism and the 5th summit of the hoop hinged formation of chain scissor mechanism in outside, the 6th summit and Seven summits, and it is positioned at radial direction bilayer chain scissor mechanism and the hinge of hoop chain scissor mechanism of the 6th summit and radially adjoining The 8th summit that the midpoint of contact is constituted；

The radially double-deck chain scissor mechanism of described first middle tetragon is symmetrical, and four summits of described middle tetragon are positioned at On adjacent three radially chain scissor mechanism, wherein, two summits are positioned at the most double-deck chain scissor mechanism of adjacent three On the radial direction bilayer chain scissor mechanism of middle both sides and be positioned on same hoop chain scissor mechanism, another two summit is positioned at adjacent Three radially on chain scissor mechanism the most double-deck in the middle of double-deck chain scissor mechanism and push up with two other respectively The half that spacing is the spacing being separated by hoop chain scissor mechanism of the hoop chain scissor mechanism at some place；

The radially double-deck chain scissor mechanism of described second middle tetragon is symmetrical, four summits of described second middle tetragon Being positioned on the most double-deck chain scissor mechanism of adjacent three, wherein, two summits are positioned at the most double-deck chain of adjacent three The intermediate radial bilayer chain scissor mechanism of scissor mechanism with on the pin joint of adjacent two hoop chain scissor mechanism, other two Individual summit lay respectively in adjacent three radially double-deck chain scissor mechanism on the radial direction chain bilayer shape scissor mechanism of both sides and Midpoint between adjacent two hoop chain scissor mechanism；

Interior tetragon S, the first middle tetragon is N number of, and the second middle tetragon is M, outer tetragon P, S=X/2, N=(Y-2) X/2, M=(Y-1) X/2, P=X/2, X are the number of the most double-deck chain scissor mechanism, and Y is hoop chain scissors machine The number of structure；

Described membrane structure is made up of the first film unit, the second film unit and tertiary membrane unit, described first film unit, the second film Unit and tertiary membrane unit are formed by the film material of montant and overlying；Described interior tetragon connects described first film unit, Described first middle tetragon and the second middle tetragon connect described second film unit, described outer tetragon connects Described tertiary membrane unit；The montant lower end of described first film unit is both connected to constitute on the second summit of described interior tetragon, The montant lower end of described second film unit is both connected to constitute being positioned at of described first middle tetragon and the second middle tetragon On the most double-deck chain scissor mechanism on the midpoint on two summits；The montant lower end of described tertiary membrane unit is both connected to constitute institute State on the 6th summit of outer tetragon；The other end of described montant is fixed with described film material, the surrounding of film material and described interior four limits Remaining summit of shape, the first middle tetragon, the second middle tetragon and outer tetragon is fixed, the film between adjacent Bu Mo district Material is connected smoothly at boundary.

Described radial direction bilayer chain scissor mechanism is evenly arranged on described annulus, and described hoop chain scissor mechanism is being justified The radially equidistant placement of ring.

The number of described hoop chain scissor mechanism is 3～10, and the number of described radial direction bilayer chain scissor mechanism is 10～40.

Described first connecting rod is straight-bar.

Described first connecting rod is plane straight-bar.

Described second connecting rod is straight-bar.

Described second connecting rod is plane straight-bar.

Described montant is straight-bar.

When flexible rack is in its fully unfolded position, film material is in tensioning state, bears the external world and the lotus of structure self Carrying, now the distance between the affixed angle point of film unit is maximum；When flexible rack is in contraction state, the affixed angle of film unit Distance Shortened between point, film material generation fold.

Beneficial effect:

The present invention is synchronized to stretch by the most double-deck chain scissor mechanism and hoop chain scissor mechanism, described in the employing of top Having the membrane structure of montant, so that rack-film combinative structure is flexible freely, expansion and contraction is big, and its structure is reasonable, design Simple with construction, hoop symmetry scissors hinge unit folding direction is vertical plane, makes grid structure have bigger vertical rigidity.Open The use closing film material meets the functional requirement of building, and makes dead load light, and convenient and quick construction is particularly suitable for Middle Or Small Span The building of degree.

Accompanying drawing explanation

Below in conjunction with the accompanying drawings and embodiment the present invention is described in more detail:

Fig. 1 is rack of the present invention-film combinative structure schematic diagram.

Fig. 2 is the most double-deck chain scissor mechanism and the hinged schematic diagram of hoop chain scissor mechanism.

Fig. 3 is the symmetrical scissors hinge unit signal of the most double-deck chain scissor mechanism of composition and hoop chain scissor mechanism Figure.

Fig. 4 is that 3 kinds of film units of component film structure arrange schematic diagram.

Fig. 5 is the first film unit schematic diagram of component film structure.

Fig. 6 is the second film unit schematic diagram of component film structure.

Fig. 7 is the tertiary membrane cell schematics of component film structure.

Detailed description of the invention

Referring to Figure of description, the present invention is made more detailed description:

As it is shown in figure 1, a kind of radial telescopic net-film combinative structure 1.This combinative structure by bottom radial telescopic net structure and Upper membrane structure forms, and wherein grid structure is by the most double-deck chain scissor mechanism of 3 hoop chain scissor mechanism 2 and 16 4 compositions.Wherein, hoop chain scissor mechanism 2 is made up of 48 hoop symmetry scissors hinge unit 3, hoop chain scissor mechanism 2 edge Evenly spaced radial layout；The most double-deck chain scissor mechanism 4 is made up of 12 radial symmetric scissors hinge unit 5, the most double-deck Chain scissor mechanism 4 circumferentially uniform intervals is arranged.

Described radial telescopic net structure is divided into continuous print Bu Mo district each other, described Bu Mo district to include interior four on the projection surface Limit shape AFGH, the first middle tetragon ABCD, the second middle tetragon ACEF and outer tetragon BIJK.Described interior tetragon In three summit FGH be the most double-deck chain scissor mechanism of adjacent three and the hoop chain scissor mechanism pin joints of inner side, And it is positioned at the radial direction bilayer chain scissor mechanism of the second summit H and radially adjoining and the pin joint of hoop chain scissor mechanism The 4th summit A that midpoint is constituted；Described outer tetragon summit IJK be adjacent three radially double-deck chain scissor mechanism and The point of the hoop hinged formation of chain scissor mechanism in outside, and it is positioned at the radial direction bilayer chain of the 6th summit K and radially adjoining The 8th summit B that the midpoint of the pin joint of scissor mechanism and hoop chain scissor mechanism is constituted；Described first middle tetragon edge The most double-deck chain scissor mechanism is symmetrical, and four summits of described first middle tetragon are positioned at adjacent three radially two-layer chain On shape scissor mechanism, wherein, the radial direction two-layer chain of both sides during C, D summit is positioned at the most double-deck chain scissor mechanism of adjacent three On shape scissor mechanism and be positioned on same hoop chain scissor mechanism, it is the most double-deck that another two summit A, B are positioned at adjacent three On the most double-deck chain scissor mechanism of in the middle of chain scissor mechanism one and respectively with the hoop chain at two other place, summit The spacing of shape scissor mechanism is the half of the spacing being separated by hoop chain scissor mechanism；Described second middle tetragon is radially Double-deck chain scissor mechanism is symmetrical, and four summits of described second middle tetragon are positioned at the most double-deck chain of adjacent three and cut In formula mechanism, wherein, C, F summit is positioned at the intermediate radial bilayer chain scissors of the most double-deck chain scissor mechanism of adjacent three Mechanism is with on the pin joint of adjacent two hoop chain scissor mechanism, and two other summit A, E lay respectively at adjacent three footpath In double-deck chain scissor mechanism on the radial direction bilayer chain scissor mechanism of both sides and be positioned at adjacent two hoop chain scissors machines Midpoint between structure；

Membrane structure is to be made up of 8 the first membrane structure unit, 8,8 tertiary membrane construction units 9 of 7,16 the second membrane structure unit. Described first film unit the 7, second film unit 8 and tertiary membrane unit 9 are formed by the film material 10 of montant and overlying.In described four Described first film unit, cloth on described first middle tetragon ABCD, the second middle tetragon ACEF is arranged in shape AFGH of limit Put described second film unit 8, described outer tetragon BIJK arranges described tertiary membrane unit 9.Erecting of described first film unit 7 Bar lower end is connected to constitute on the second summit H of described interior tetragon AFGH, and the montant lower end of described second film unit 8 is all connected with Constitute described first middle tetragon ABCD and the second middle tetragon ACEF radial direction bilayer chain scissor mechanism on two On the midpoint on summit；The montant lower end of described tertiary membrane unit 9 is connected to constitute the 6th summit K of described outer tetragon BIJK On.The other end of described montant is fixed with described film material, the surrounding of film material and described interior tetragon, the first middle tetragon, the Remaining summit of two middle tetragons and outer tetragon is fixed, and the film material between adjacent Bu Mo district seamlessly transits even at boundary Connect.

As in figure 2 it is shown, hoop chain mechanism 2 respectively with the chain scissor mechanism of two-layer up and down of the most double-deck chain mechanism 4 By two endpoint nodes and every layer of radial symmetric scissors hinge unit second connecting rod of hoop symmetry scissors hinge unit first connecting rod Middle hinged joint 6 connect.Thus, by the effect of this hinged joint, it is achieved radial direction two-layer chain shape in grid structure moving process Scissor mechanism 4 and the synchronization telescope of hoop chain scissor mechanism 2.

The most double-deck chain scissor mechanism of composition as shown in Figure 3 and the symmetrical scissors hinge unit of hoop chain scissor mechanism It it is the parallel scissors hinge unit being most widely used at present.The length of connecting rod of symmetrical scissors hinge unit is equal, and by connecting rod Between a pin-connected joints be connected, connecting rod is only capable of around vertically relatively rotating the axis of connecting rod place plane with this, and other Degree of freedom is restricted completely；Connection between the most symmetrical scissors hinge unit is by the hinged realization of boom end hinged joint. This unit is the line keeping parallelism of its end hinged joint in motor process.

As shown in Figure 4, when radial telescopic net-film combinative structure is fully deployed, 3 kinds of film units are covered with whole grid structure. Wherein 8 the first membrane structure unit 7 are arranged in interior tetragon Bu Mo district, are circumferentially evenly arranged；16 the second membrane structure unit 8 It is arranged in the Bu Mo district of the first middle tetragon and the second middle tetragon composition；Outside 8 tertiary membrane construction units 9 are arranged in Tetragon Bu Mo district, is circumferentially evenly arranged.

As it is shown in figure 5, the first membrane structure unit 7 of innermost circle is arranged on interior tetragon AFGH, wherein summit F, H, G exists At the pin joint of adjacent innermost circle hoop chain scissor mechanism 2 and the most double-deck chain scissor mechanism 4；Summit A is the most right Claim on the radial direction bilayer chain scissor mechanism 4 at axle place, and be in and the middle of adjacent hoop chain scissor mechanism.First Montant is arranged at summit H point, and film material 10 upper end is fixed on the first montant upper end, bottom and summit F, G, H concrete mutually.

As shown in Figure 6, the second membrane structure unit 8 is arranged in the first middle tetragon and the second middle tetragon Bu Mo district In.Four summit ABCD of described first middle tetragon are positioned on the most double-deck chain scissor mechanism of adjacent three, wherein, Summit CD is positioned in adjacent three radially double-deck chain scissor mechanism on the radial direction bilayer chain scissor mechanism of both sides and is positioned at On same hoop chain scissor mechanism, another two summit AB is positioned in the middle of the most double-deck chain scissor mechanism of adjacent three On individual radial direction bilayer chain scissor mechanism and respectively with the spacing of the hoop chain scissor mechanism at CD place, summit for being separated by hoop The half of the spacing of chain scissor mechanism；Four summit ACEF of described second middle tetragon are positioned at adjacent three radial direction On double-deck chain scissor mechanism, wherein, summit CF is positioned at the intermediate radial pair of the most double-deck chain scissor mechanism of adjacent three Layer chain scissor mechanism is with on the pin joint of adjacent two hoop chain scissor mechanism, and two other summit AE lays respectively at adjacent Three radially in double-deck chain scissor mechanism on the radial direction bilayer chain scissor mechanism of both sides and be positioned at adjacent two hoop chains Midpoint between shape scissor mechanism；Second montant lower end is arranged in the first middle tetragon and the centre of the second middle tetragon The midpoint of the most double-deck scissors hinge body, film material 10 top of top attachment is fixed on montant upper end, and bottom is thrown with tetragon The summit concrete mutually of shadow.

As it is shown in fig. 7, the tertiary membrane construction unit 9 of outmost turns is arranged on outer tetragon BIJK, summit I, J, K are adjacent Outmost turns hoop chain scissor mechanism 2 and the most double-deck chain scissor mechanism 4 pin joint at；Summit B is in radial symmetry axis On the radial direction bilayer chain scissor mechanism 4 at place, and it is in and the middle of adjacent hoop chain scissor mechanism.3rd montant Being arranged at summit K point, film material 10 upper end is fixed on the 3rd montant upper end, bottom and summit I, J, K concrete mutually.

Claims (8)

1. the most double-deck flexible rack-film combinative structure, this combinative structure is by bottom radial telescopic net structure and top Membrane structure forms, it is characterised in that described radial telescopic net structure is by plural hoop chain scissor mechanism and two Above radial direction bilayer chain scissor mechanism composition, hoop chain scissor mechanism arranged concentric, the most double-deck chain scissor mechanism Radial arrangement along the annulus that described hoop chain scissor mechanism is formed；Hoop chain scissor mechanism is by multiple hoop symmetry scissors Hinge unit is connected to annular end to end；The most double-deck chain scissor mechanism is by the horizontal chain scissor mechanism group of two-layer up and down alignd Becoming, wherein every layer of chain scissor mechanism is connected to linear by multiple radial symmetric scissors hinge unit end to end；Described hoop symmetry is cut Formula hinge is formed by the first connecting rod that two length is equal is hinged in the middle of bar, and described radial symmetric scissors hinge is equal by two length Second connecting rod hinged composition in the middle of the bar；Radially descend two-layer horizontal chain scissor mechanism respectively with hoop chain scissor mechanism By cutting with scissors the hinged reality in first connecting rod end of unit in the middle part of the second connecting rod of radial symmetric scissors hinge unit with hoop symmetry scissors Now connect,

Described radial telescopic net structure is divided into continuous print Bu Mo district each other, described Bu Mo district to include interior four limits on the projection surface Shape, the first middle tetragon, the second middle tetragon and outer tetragon；

The radially double-deck chain scissor mechanism of described interior tetragon is symmetrical, and four summits of described interior tetragon include adjacent three Individual radial direction bilayer chain scissor mechanism and first summit of the hoop hinged formation of chain scissor mechanism of inner side, the second summit and Three summits, and it is positioned at radial direction bilayer chain scissor mechanism and the hinge of hoop chain scissor mechanism of the second summit and radially adjoining The 4th summit that the midpoint of contact is constituted；

The radially double-deck chain scissor mechanism of described outer tetragon is symmetrical, and four summits of described outer tetragon include adjacent three Individual radial direction bilayer chain scissor mechanism and the 5th summit of the hoop hinged formation of chain scissor mechanism in outside, the 6th summit and Seven summits, and it is positioned at radial direction bilayer chain scissor mechanism and the hinge of hoop chain scissor mechanism of the 6th summit and radially adjoining The 8th summit that the midpoint of contact is constituted；

The radially double-deck chain scissor mechanism of described first middle tetragon is symmetrical, and four summits of described middle tetragon are positioned at On the most double-deck chain scissor mechanism of adjacent three, wherein, two summits are positioned at the most double-deck chain scissors of adjacent three In mechanism on the radial direction bilayer chain scissor mechanism of both sides and be positioned on same hoop chain scissor mechanism, another two summit is positioned at On a chain scissor mechanism the most double-deck in the middle of the most double-deck chain scissor mechanism of adjacent three and respectively with other two The half that spacing is the spacing being separated by hoop chain scissor mechanism of the hoop chain scissor mechanism at place, individual summit；

The radially double-deck chain scissor mechanism of described second middle tetragon is symmetrical, four summits of described second middle tetragon Being positioned on the most double-deck chain scissor mechanism of adjacent three, wherein, two summits are positioned at the most double-deck chain of adjacent three The intermediate radial bilayer chain scissor mechanism of scissor mechanism with on the pin joint of adjacent two hoop chain scissor mechanism, other two Individual summit lay respectively in adjacent three radially double-deck chain scissor mechanism on the radial direction bilayer chain scissor mechanism of both sides and Midpoint between adjacent two hoop chain scissor mechanism；

Interior tetragon S, the first middle tetragon is N number of, and the second middle tetragon is M, outer tetragon P, S=X/2, N=(Y-2) X/2, M=(Y-1) X/2, P=X/2, X are the number of the most double-deck chain scissor mechanism, and Y is hoop chain scissors machine The number of structure；

Described membrane structure is made up of the first film unit, the second film unit and tertiary membrane unit, described first film unit, the second film Unit and tertiary membrane unit are formed by the film material of montant and overlying；Described interior tetragon connects described first film unit, Described first middle tetragon and the second middle tetragon connect described second film unit, described outer tetragon connects Described tertiary membrane unit；The montant lower end of described first film unit is both connected to constitute on the second summit of described interior tetragon, The montant lower end of described second film unit is both connected to constitute being positioned at of described first middle tetragon and the second middle tetragon On the most double-deck chain scissor mechanism on the midpoint on two summits；The montant lower end of described tertiary membrane unit is both connected to constitute institute State on the 6th summit of outer tetragon；The other end of described montant is fixed with described film material, the surrounding of film material and described interior four limits Remaining summit of shape, the first middle tetragon, the second middle tetragon and outer tetragon is fixed, the film between adjacent Bu Mo district Material is connected smoothly at boundary.

Radial direction bilayer the most according to claim 1 stretches rack-film combinative structure, it is characterised in that: described radial direction is double-deck Chain scissor mechanism is evenly arranged on described annulus, and described hoop chain scissor mechanism is in the radially equidistant placement of annulus.

Radial direction bilayer the most according to claim 1 and 2 stretches rack-film combinative structure, it is characterised in that: described hoop chain The number of shape scissor mechanism is 3～10, and the number of described radial direction bilayer chain scissor mechanism is 10～40.

Radial direction bilayer the most according to claim 3 stretches rack-film combinative structure, it is characterised in that: described first connecting rod For straight-bar.

Radial direction bilayer the most according to claim 4 stretches rack-film combinative structure, it is characterised in that: described first connecting rod For plane straight-bar.

Radial direction bilayer the most according to claim 3 stretches rack-film combinative structure, it is characterised in that: described second connecting rod For straight-bar.

Radial direction bilayer the most according to claim 6 stretches rack-film combinative structure, it is characterised in that: described second connecting rod For plane straight-bar.

Radial direction bilayer the most according to claim 1 stretches rack-film combinative structure, it is characterised in that: described montant is straight Bar.