US3169542A - Inflatable buildings - Google Patents

Inflatable buildings Download PDF

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US3169542A
US3169542A US166877A US16687762A US3169542A US 3169542 A US3169542 A US 3169542A US 166877 A US166877 A US 166877A US 16687762 A US16687762 A US 16687762A US 3169542 A US3169542 A US 3169542A
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canopy
panels
panel
building
ground
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Neumark Otto Walter
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P Frankenstein and Sons Manchester Ltd
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Frankenstein & Sons Manchester
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    • EFIXED CONSTRUCTIONS
    • E04BUILDING
    • E04HBUILDINGS OR LIKE STRUCTURES FOR PARTICULAR PURPOSES; SWIMMING OR SPLASH BATHS OR POOLS; MASTS; FENCING; TENTS OR CANOPIES, IN GENERAL
    • E04H15/00Tents or canopies, in general
    • E04H15/20Tents or canopies, in general inflatable, e.g. shaped, strengthened or supported by fluid pressure
    • E04H15/22Tents or canopies, in general inflatable, e.g. shaped, strengthened or supported by fluid pressure supported by air pressure inside the tent

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  • This invention relates to inflatable buildings of the type comprising a canopy of flexible impermeable material which is adapted to be supported solely by a maintained internal air pressure in the region of 0.03 to 0.5 lb. per sq. in. (gauge) and has means for preventing any excessive leakage of such air between its periphery and the ground.
  • Such buildings are commonly made in a domed or blister shape, but have also been designed with a part-cylindrical body portion and rounded ends, a form which is particularly suitable for temporary warehouses, exhibition halls and the like.
  • the ideal cross-sectional shape for such a building is semi-circular, because the uplift forces resulting from inflation then act vertically upon the peripheral anchorage of the canopy, but where the building is to be of considerable span (as in the case of an exhibition hall) this arrangement involves an excessive overall height and renders the building particularly subject to the action of winds which by producing a reduction of atmospheric pressure over a considerable part of its surface and hence increasing local differences between the internal and external pressures, may very greatly augment the normal hoop stress in the canopy material, usually a rubberized fabric.
  • the total uplift load being dependent upon the floor area of the building and the difference between the internal and external air pressures on the canopy, is of course subject to increase by wind forces affecting the pressure differential as above described.
  • the present invention is based upon an appreciation of the above-mentioned factors, and has for its object to provide an improved construction of air-supported building which can be made of wide span without the use of heavy and expensive material and hence without afi'ecting the portability of the buildings when deflated.
  • anchorages including cables, the ends of which are fixed to suitable supports at higher levels than the area being covered.
  • Guy lines from the canopy are attached to the cables.
  • additional anchorages are conveniently arranged in parallel rows, thus producing a reeded effect in the canopy, and preferably the load taken by any one row of such additional anchorages is distributed by attachment of the individual tethering means to a continuous flap or series of flaps dependent from the canopy, such flap or flaps having inverted catenary profiles between its or their successive conections to the tethering means above mentioned.
  • peripheral and additional anchorages aforesaid will be made direct to the ground (as by means of screw-pickets), but when the canopy is of very wide span or when it is important to avoid obstruction of the area covered thereby, each row of guys forming the additional anchorages may be connected to a strong cable whose ends are fixed to the ground or to artificial supports, which may be situated at a generally higher level than the area to be covered.
  • FIG. 1 is a part-sectional side elevation of an air-supported building embodying the present invention.
  • FIG. 2 is a part-sectional end elevation of the same.
  • FIG. 3 is an enlarged section on the line 33 of FIG. 2.
  • FIG. 4 is a fragmentary cross-sectional view showing a preferred arrangement of the joint between juxtaposed V canopy panels.
  • FIG. 5 is a fragmentary plan view of a preferred form of canopy panel.
  • FIG. 6 shows a detail of such canopy panel drawn to a larger scale.
  • FIG. 7 is a fragmentary plan view showing an alternative form of canopy panel
  • FIG. 8 is a view corresponding to FIG. 4 but showing canopy panels of yet another form and one method of joining the same together.
  • PEG. 9 is a fragmentary perspective view illustrating an alternative method of connecting adjacent canopy panels of the form shown in FIG. 8.
  • FIG. 12 is a schematic view showing the canopy of FIGS. 10 and 11 in course of erection, and,
  • FIG; 13 is a fragmentary view corresponding to FIG. 10 but showing a modified arrangement.
  • the method of construction forming the subject of the present invention results in an air-supported building of generally rectangular planform, the required canopy It) being made up of a plurality of elongated panels 11 of flexible impermeable material (such as a coated fabric) which are disposed lengthwise of the building and whose lateral margins 11a are arranged to make substantially air-tight contact with one another when the canopy is inflated.
  • flexible impermeable material such as a coated fabric
  • each panel 11 is provided with primary tethering point 12 at corresponding equally spaced positions along both longitudinal edges, which are shaped to inverted catenary profiles between such points, the several panels 11 being assembled side-by-side with the 3 tethering points 12 at one edge of each panel opposite those at the juxtaposed edge of the next panel.
  • each panel 11 is 120 feet long by 60 feet wide, but should the required length of the canopy exceed that of a single panel, two or more of the latter may be suitably overlapped, with the tethering points 12 of each panel in register with those of the panel or panels overlapping it.
  • Opposed tethering points 12 of the laterally-juxtaposed panels 11 are connected together by snap-links 13 (FIG. 4) or equivalent devices from which adjustable guy-lines 14 lead to screw-pickets 15 driven into the ground in parallel rows along the ground-plan of the building, whose dimensions are of course substantially smaller than those of the assembled canopy 16.
  • the periphery of the latter is located in known manner, either by attachment to screw-pickets 16 at the adjacent corners of the several panels 11 or canopy sections, or by providing at the ends of each such panel or section a tube or pocket for ballasting material.
  • Inflation of the canopy It is effected by means of flexible trunking from an external ventilating fan while the juxtaposed edges of the panels 11 or canopy sections are temporarily held together byspring clips or other means. It may be found desirable to inflate the canopy from one side, the several panels or sections having previously been laid out upon the ground in echelon towards that side so that they will inflate consecutively, the pressure built up beneath any given panel or section tending to seal the joint beneath that panel or section and the one next to be inflated.
  • Leakage of air beneath the periphery of the canopy 10 may be substantially eliminated by so arranging the guy attachments to its peripheral parts that the latter engage the ground over a width of several feet and are held in contact therewith by the internal pressure to provide a reflected seal.
  • loose strips of flexible impermeable material may be arranged to overlie the junction of the canopy with the ground so as to fill out all concavities and thus form supplementary reflected seals.
  • the juxtaposed marginal portions 11a of the several panels are restrained by the guy-lines 14 during inflation of the canopy 10 so that the latter eventually assumes a reeded form as shown in FIGS. 1 and 2, the internal pressure acting radially upon the curved surfaces of the panels whilst pressing tightly together with inwardly directed flaps represented by their tethered marginal portions 11a, and thus rendering unnecessary any clips or other means previously applied to such portions.
  • each reed is' produced by suitably gathering up the marginal portions of the adjacent panels 11 as shown in FIG. 3 for which purpose the longitudinal edge of such panels are provided with intermediate tethering points 17, any required number of which may be engaged by a suitable snap-link 13 or the like associated with a further guy-line 14.
  • a similar gathering up of the marginal portions 11a may be necessary where the ends of the panels are anchored to the ground, but the resultant folds in the canopy material do not significantly affect the air-tightness of the building, the rate of leakage from the latter being readily maintainable at the minimum needed for effective ventilation.
  • a short tunnel or vestibule of rigid or relatively rigid construction equipped with doors to serve as an air-lock for inward or outward traffic of personnel or vehicles may be pushed through the canopy It at any of the self-sealing joints between the reeds, the inturned marginal portions 11a of the adjacent panels then engaging the exterior of such tunnel or vestibule in an air-tight manner.
  • Emergency exit of personnel in the event of fire can readily be effected without difificulty through any of the canopy joints aforesaid.
  • guy-lines 14 In order to increase the stability of the upper part of (3. the canopy 19 against powerful wind forces, it is preferred not to lead guy-lines 14 vertically front the various tethering points 13, but to connect each of the latter to two or more pickets 15 which are offset horizontally therefrom, and some of these divergent pairs of guy-lines may be arranged in planes longitudinal to the building (FIG. 1) and others in transverse planes (as indicated in FIG. 2).
  • FIG. 4 illustrates a convenient rain-proof assembly at each such gully, a continuous flap 18 of flexible impermeable material being united externally to each panel 11 near one lateral edge thereof so as to conform to the V section of the gully and the free edge of this gutter flap being overlaid by a narrower flap 19 similarly associated with the adjacent panel.
  • flaps such as 18 may be attached to each panel 11 adjacent both lateral edges thereof.
  • the overlapping edges of the flaps i8, 19 are preferably secured together by means of opposed flexible strips 26, 21 whose respective materials are such that they become mutually adherent on being manually pressed together.
  • Convenient touch fastener strips are sold under the registered trademark Velcro, and similar provision may be made between the coacting marginal portions 11a of the juxtaposed panels to further seal the joint against air-leakage, particularly during the initial stages of inflation.
  • Other known joining means such as tie-tapes or press-studs may be substituted-for the touch fastener strips 20, 2i. and cords attached to the underside of the gutter flap 18 may be passed between the coacting panel margins 11a so that the lay of the gutter, if disturbed during the initial inflation, can readily be re-arranged from inside the building.
  • Each canopy panel 11 is conveniently made up as shown in FIG. 5 by sewing or otherwise securing together a plurality of strips 22 of coated fabric which extend across the width thereof, consecutive strips being of such lengths, and their ends being straight-cut at'such angles that the assembled panel exhibits the required series of catenary curves along both lateral edges.
  • the free longitudinal edge of the endrnost strips 22 may likewise be cut as catenaries.
  • FIG. 7 illustrates a modified construction which permits each canopy panel to be made of uniform width throughout, its lateral margins 11a being eyeleted at regular intervals for the connection thereto of triangular sections of balloon netting 26 whose apices form the primary tethering points 13, or alternatively radiating cords may lead directly from each of the latter to a suitable number of points on the panel edge so as to spread the tethering stress along it in a similar manner.
  • each panel 11 or canopy sections may be mechanically connected at or near their juxtaposed edges as shown in FIG. 8.
  • each panel is of uniform width and a separate strip 27 of flexible impermeable material is secured along a medial line at 28 to the outer side of one edge only of such panel.
  • the pendant part of this strip 27 has itsedge hemmed, reinforced, and formed into a series of catenary curves so as to correspond to the integral marginal flap 11a of one of the panels shown in FIGSQl to 6 Whilst the other part of the strip is adapted for detachable connection to the free edge 29 of the next panel.
  • the connecting means indicated at 30 may be of any suitable type; for example the strip 27 and panel edge 29 may be overlapped as shown, a row of studs on one memher being passed through eyelets in the other and secured by circlips or the like, or both members may be eyeleted for connection together by Dutch or chain lacing.
  • the strip 27 and panel edge 29 may be secured together by means of a slide fastener, or similar sets of loops thereon may be interdigitated and a wire or other flexible member threaded through them, or again use may be made of hooks and eyes, or loops and toggles.
  • the joint is preferably covered internally by means of a sealing flap secured to one of the juxaposed members.
  • FIG. 9 Yet another method of mechanically connecting the lateral edges of two adjacent panels 11 is illustrated in FIG. 9.
  • a strip 27 attached to the edge of one panel is overlapped by the marginal portion 29 of the other panel (as shown in FIG. 8), the strip 27 having parallel webbing bands 31, 32 respectively sewn at intervals along its edge and to its outer side at some distance from such edge, whilst the overlapping portion 29 has further parallel bands 33, 34 which are similarly secured to its edge and its inner side, and ropes 35, 36 are threaded through alternate bights of the bands 31, 34 and 32, 33 respectively.
  • each row of guy-lines 14 forming the additional anchorages being connected to a strong cable 37 whose ends are fixed to the ground or to artificial supports, which will normally be at a higher level than the area to be covered.
  • the contour of the ground covered is quite unimportant; that is to say, the building can be arranged to con ceal or shelter a hillock just as easily as a depression.
  • each such side has the cable attachment points 39 situated along an upwardly convex line, whilst the endmost cables 37 may have their extremities fixed at or adjacent the floor of the valley 38.
  • Suitable members of the panels 11 are assembled in endwise overlapping relation to form complete canopy sections each of a width somewhat greater than the horizontal spacing of the cables 37 and exceeding by one the number of such cables provided.
  • the periphery of the canopy 16 (as represented by the free edges of its two endmost sections and the extremities of those intervening) is lo- 7 cated either by attachment to screw-pickets or by ballasting as previously described.
  • the uplift load is transmitted through the rows of guy-lines 14 to the cables 37 which thereupon adopt inverted catenary curves as shown.
  • the canopy may, of course, be stabilized against wind forces, by connecting each of several tethering points 12 to spaced points on the adjacent cable 37 or to corresponding points in two adjacent cables.
  • the cables 37 may be anchored to the tops of stands or banked seating ll around the arena 41, as shown in FIG. 13, or such stands or banking may provide abutments for cables anchored at ground-level externally thereof.
  • FIG. 13 also illustrates the alternative arrangement of the canopy 10 with its reeds running transversely of the cables 37.
  • An inflatable building comprising, a canopy composed of a plurality of connected flexible strips having inturned longitudinal edge portions forming dependent flaps, the flaps on one panel being facially opposed to those on adjacent panels, loop members passing through the flaps of adjacent panels, tethering cables extending from the loop members to the ground, and drain strips on the canopy mounted over the meeting points of adjacent flaps and bridging the points of connection of the same.
  • An inflatable building comprising, a canopy composed of a plurality of connected flexible panels at least one of which has inturned longitudinal edge portions forming dependent flaps, the flaps on one panel being facially opposed to the adjacent panel, the lower edges of adjacent panels being out of contact, a strip having one edge attached to an intermediate portion of said one panel, said strip depending below said panels, and means on the lower end of said strip for anchoring the same to a fixed base.
  • An inflatable building comprising a plurality of elongated panels convex in cross-section and located sideby-side, the lower edges of adjacent panels being in juxtaposed position over a substantial area, air pressure within said canopy pressing on said panels causing said lower edges to seal the joints between said adjacent panels against leakage from inside the canopy, means attached to said lower edges at spaced points having tethers thereon extending to and anchored in a fixed base.
  • An inflatable building comprising a canopy composed of at least one pair of convex panels connected together at their lower edges, said connection including the lower edges of said panels being inturned, means securing the lower edges together and anchoring said panels to a fixed base, touch fastener strips facing each other on said lower edges of said panels, said touch fastener strips being J adhered to eachothar and sealing against air leakage out of said building at the connection between said panels.

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  • Engineering & Computer Science (AREA)
  • Architecture (AREA)
  • Physics & Mathematics (AREA)
  • Fluid Mechanics (AREA)
  • Civil Engineering (AREA)
  • Structural Engineering (AREA)
  • Tents Or Canopies (AREA)

Description

Feb. 16, 1965 Filed Jan. 17, 1962 O. W. NEUMARK INFLATABLE BUILDINGS 2 Sheets-Sheet 1 i INVENTOR: i i TTO WALTER NEWARK Feb. 16, 1965 o. w. NEUMARK INFLATABLE BUILDINGS 2 Sheets-Sheet 2 Filed Jan. 17, 1962 mvsmon;
OTTO WALTER NEUMARK BY 6mm+ United States Patent 3,169,542 INFLATABLE BUHDENGS @tto Walter Neumarh, Heaton Mersey, Stochport, England, assignor to P. Frankenstein Sons (Manchester) Ltd, a company of Great Britain Filed .ian. 17, 1962, Ser. No. 166,377 7 Claims. (Cl. 135-1) This invention relates to inflatable buildings of the type comprising a canopy of flexible impermeable material which is adapted to be supported solely by a maintained internal air pressure in the region of 0.03 to 0.5 lb. per sq. in. (gauge) and has means for preventing any excessive leakage of such air between its periphery and the ground.
Such buildings (conveniently termed air supported to distinguish them from other inflatable types in which the canopy is double-walled and divided into several infiatable segments, or is assocaited with a skeleton of inflatable tubes) are commonly made in a domed or blister shape, but have also been designed with a part-cylindrical body portion and rounded ends, a form which is particularly suitable for temporary warehouses, exhibition halls and the like.
Theoretically the ideal cross-sectional shape for such a building is semi-circular, because the uplift forces resulting from inflation then act vertically upon the peripheral anchorage of the canopy, but where the building is to be of considerable span (as in the case of an exhibition hall) this arrangement involves an excessive overall height and renders the building particularly subject to the action of winds which by producing a reduction of atmospheric pressure over a considerable part of its surface and hence increasing local differences between the internal and external pressures, may very greatly augment the normal hoop stress in the canopy material, usually a rubberized fabric.
The wind resistance offered by any air-supported building, and also the quantity of canopy material required to span a given width of floor, can obviously be reduced by bringing the centre (or axis) of curvature below ground level, but this will necessitate a greater radius of curvature, and hence a greater stress in the canopy material, than is the case with a building of semi-circular cross-section, and furthermore as the centre (or axis) of curvature of the canopy is brought below ground level, the uplift'forces acting upon its peripheral anchorage acquire an increasing inward horizontal component whoseeffect is to disturb the security of the airseal between the canopy and the ground.
The total uplift load, being dependent upon the floor area of the building and the difference between the internal and external air pressures on the canopy, is of course subject to increase by wind forces affecting the pressure differential as above described.
The present invention is based upon an appreciation of the above-mentioned factors, and has for its object to provide an improved construction of air-supported building which can be made of wide span without the use of heavy and expensive material and hence without afi'ecting the portability of the buildings when deflated.
In the case of buildings with very wide spans there may be provided additional anchorages including cables, the ends of which are fixed to suitable supports at higher levels than the area being covered. Guy lines from the canopy are attached to the cables.
These additional anchorages are conveniently arranged in parallel rows, thus producing a reeded effect in the canopy, and preferably the load taken by any one row of such additional anchorages is distributed by attachment of the individual tethering means to a continuous flap or series of flaps dependent from the canopy, such flap or flaps having inverted catenary profiles between its or their successive conections to the tethering means above mentioned.
Longitudinal and/ or lateral sway of the inflated building with reference to its peripheral anchorage may beresisted by tethering any given point on the canopy, or on one of the dependent flaps aforesaid, to two pickets or the equivalent which are longitudinally and/ or laterally displaced from the vertical through such point.
Normally the peripheral and additional anchorages aforesaid will be made direct to the ground (as by means of screw-pickets), but when the canopy is of very wide span or when it is important to avoid obstruction of the area covered thereby, each row of guys forming the additional anchorages may be connected to a strong cable whose ends are fixed to the ground or to artificial supports, which may be situated at a generally higher level than the area to be covered.
In the accompanying drawings:
FIG. 1 is a part-sectional side elevation of an air-supported building embodying the present invention.
FIG. 2 is a part-sectional end elevation of the same.
FIG. 3 is an enlarged section on the line 33 of FIG. 2.
FIG. 4 is a fragmentary cross-sectional view showing a preferred arrangement of the joint between juxtaposed V canopy panels.
FIG. 5 is a fragmentary plan view of a preferred form of canopy panel.
FIG. 6 shows a detail of such canopy panel drawn to a larger scale.
FIG. 7 is a fragmentary plan view showing an alternative form of canopy panel, and
FIG. 8 is a view corresponding to FIG. 4 but showing canopy panels of yet another form and one method of joining the same together.
PEG. 9 is a fragmentary perspective view illustrating an alternative method of connecting adjacent canopy panels of the form shown in FIG. 8.
FIGS. 10 and 11 are views corresponding to FIGS. 1 and 2 respectively, but showing the building arranged to roof over a valley.
FIG. 12 is a schematic view showing the canopy of FIGS. 10 and 11 in course of erection, and,
FIG; 13 is a fragmentary view corresponding to FIG. 10 but showing a modified arrangement.
As illustrated in FIGS. 1 and 2 the method of construction forming the subject of the present invention results in an air-supported building of generally rectangular planform, the required canopy It) being made up of a plurality of elongated panels 11 of flexible impermeable material (such as a coated fabric) which are disposed lengthwise of the building and whose lateral margins 11a are arranged to make substantially air-tight contact with one another when the canopy is inflated.
For this purpose each panel 11 is provided with primary tethering point 12 at corresponding equally spaced positions along both longitudinal edges, which are shaped to inverted catenary profiles between such points, the several panels 11 being assembled side-by-side with the 3 tethering points 12 at one edge of each panel opposite those at the juxtaposed edge of the next panel.
A convenient size for each panel 11 is 120 feet long by 60 feet wide, but should the required length of the canopy exceed that of a single panel, two or more of the latter may be suitably overlapped, with the tethering points 12 of each panel in register with those of the panel or panels overlapping it.
Opposed tethering points 12 of the laterally-juxtaposed panels 11 (or multi-panel canopy sections) are connected together by snap-links 13 (FIG. 4) or equivalent devices from which adjustable guy-lines 14 lead to screw-pickets 15 driven into the ground in parallel rows along the ground-plan of the building, whose dimensions are of course substantially smaller than those of the assembled canopy 16.
The periphery of the latter is located in known manner, either by attachment to screw-pickets 16 at the adjacent corners of the several panels 11 or canopy sections, or by providing at the ends of each such panel or section a tube or pocket for ballasting material.
Inflation of the canopy It is effected by means of flexible trunking from an external ventilating fan while the juxtaposed edges of the panels 11 or canopy sections are temporarily held together byspring clips or other means. It may be found desirable to inflate the canopy from one side, the several panels or sections having previously been laid out upon the ground in echelon towards that side so that they will inflate consecutively, the pressure built up beneath any given panel or section tending to seal the joint beneath that panel or section and the one next to be inflated.
Leakage of air beneath the periphery of the canopy 10 may be substantially eliminated by so arranging the guy attachments to its peripheral parts that the latter engage the ground over a width of several feet and are held in contact therewith by the internal pressure to provide a reflected seal. When marked uneveness of the ground makes this difiicult, loose strips of flexible impermeable material may be arranged to overlie the junction of the canopy with the ground so as to fill out all concavities and thus form supplementary reflected seals.
The juxtaposed marginal portions 11a of the several panels are restrained by the guy-lines 14 during inflation of the canopy 10 so that the latter eventually assumes a reeded form as shown in FIGS. 1 and 2, the internal pressure acting radially upon the curved surfaces of the panels whilst pressing tightly together with inwardly directed flaps represented by their tethered marginal portions 11a, and thus rendering unnecessary any clips or other means previously applied to such portions.
The round-down shown at the ends of each reed is' produced by suitably gathering up the marginal portions of the adjacent panels 11 as shown in FIG. 3 for which purpose the longitudinal edge of such panels are provided with intermediate tethering points 17, any required number of which may be engaged by a suitable snap-link 13 or the like associated with a further guy-line 14. A similar gathering up of the marginal portions 11a may be necessary where the ends of the panels are anchored to the ground, but the resultant folds in the canopy material do not significantly affect the air-tightness of the building, the rate of leakage from the latter being readily maintainable at the minimum needed for effective ventilation.
It will be understood that a short tunnel or vestibule of rigid or relatively rigid construction equipped with doors to serve as an air-lock for inward or outward traffic of personnel or vehicles, may be pushed through the canopy It at any of the self-sealing joints between the reeds, the inturned marginal portions 11a of the adjacent panels then engaging the exterior of such tunnel or vestibule in an air-tight manner. Emergency exit of personnel in the event of fire can readily be effected without difificulty through any of the canopy joints aforesaid.
In order to increase the stability of the upper part of (3. the canopy 19 against powerful wind forces, it is preferred not to lead guy-lines 14 vertically front the various tethering points 13, but to connect each of the latter to two or more pickets 15 which are offset horizontally therefrom, and some of these divergent pairs of guy-lines may be arranged in planes longitudinal to the building (FIG. 1) and others in transverse planes (as indicated in FIG. 2).
When the canopy 1%) is constrained to a reeded formation as above described, effective drainage is readily effected by adjusting the guy-lines 14 so that all the resultant gullies in such canopy will be slightly inclined towards one end of the building as shown on FIG. 1 or in opposite directions from a watershed at or near the centre of its length.
FIG. 4 illustrates a convenient rain-proof assembly at each such gully, a continuous flap 18 of flexible impermeable material being united externally to each panel 11 near one lateral edge thereof so as to conform to the V section of the gully and the free edge of this gutter flap being overlaid by a narrower flap 19 similarly associated with the adjacent panel. Alternatively flaps such as 18 may be attached to each panel 11 adjacent both lateral edges thereof.
To prevent their disturbance by wind the overlapping edges of the flaps i8, 19 are preferably secured together by means of opposed flexible strips 26, 21 whose respective materials are such that they become mutually adherent on being manually pressed together. Convenient touch fastener strips are sold under the registered trademark Velcro, and similar provision may be made between the coacting marginal portions 11a of the juxtaposed panels to further seal the joint against air-leakage, particularly during the initial stages of inflation. Other known joining means such as tie-tapes or press-studs may be substituted-for the touch fastener strips 20, 2i. and cords attached to the underside of the gutter flap 18 may be passed between the coacting panel margins 11a so that the lay of the gutter, if disturbed during the initial inflation, can readily be re-arranged from inside the building.
Each canopy panel 11 is conveniently made up as shown in FIG. 5 by sewing or otherwise securing together a plurality of strips 22 of coated fabric which extend across the width thereof, consecutive strips being of such lengths, and their ends being straight-cut at'such angles that the assembled panel exhibits the required series of catenary curves along both lateral edges. The free longitudinal edge of the endrnost strips 22 may likewise be cut as catenaries.
The effect of the catenary curves is, of course, to dis tribute the tethering stresses as uniformly as possible along the length of the panel 10, the constituent strips 11 before assembly together having their ends hemmed at 23 (FIG. 6) to provide tunnels through which wire or cord reinforcements 24 are threaded. By cutting off the corners of each strip 22 before its ends are hemmed over, the reinforcing members 24 are left exposed, opposite the transverse seams 25 of the panel, to provide the primary and intermediate tethering points 13, 17 for the latter.
FIG. 7 illustrates a modified construction which permits each canopy panel to be made of uniform width throughout, its lateral margins 11a being eyeleted at regular intervals for the connection thereto of triangular sections of balloon netting 26 whose apices form the primary tethering points 13, or alternatively radiating cords may lead directly from each of the latter to a suitable number of points on the panel edge so as to spread the tethering stress along it in a similar manner.
If desired, the several panels 11 or canopy sections may be mechanically connected at or near their juxtaposed edges as shown in FIG. 8. In this case each panel is of uniform width and a separate strip 27 of flexible impermeable material is secured along a medial line at 28 to the outer side of one edge only of such panel. The pendant part of this strip 27 has itsedge hemmed, reinforced, and formed into a series of catenary curves so as to correspond to the integral marginal flap 11a of one of the panels shown in FIGSQl to 6 Whilst the other part of the strip is adapted for detachable connection to the free edge 29 of the next panel.
The connecting means indicated at 30 may be of any suitable type; for example the strip 27 and panel edge 29 may be overlapped as shown, a row of studs on one memher being passed through eyelets in the other and secured by circlips or the like, or both members may be eyeleted for connection together by Dutch or chain lacing.
Alternatively, the strip 27 and panel edge 29 may be secured together by means of a slide fastener, or similar sets of loops thereon may be interdigitated and a wire or other flexible member threaded through them, or again use may be made of hooks and eyes, or loops and toggles. In all such cases, the joint is preferably covered internally by means of a sealing flap secured to one of the juxaposed members.
Yet another method of mechanically connecting the lateral edges of two adjacent panels 11 is illustrated in FIG. 9. In this casev a strip 27 attached to the edge of one panel is overlapped by the marginal portion 29 of the other panel (as shown in FIG. 8), the strip 27 having parallel webbing bands 31, 32 respectively sewn at intervals along its edge and to its outer side at some distance from such edge, whilst the overlapping portion 29 has further parallel bands 33, 34 which are similarly secured to its edge and its inner side, and ropes 35, 36 are threaded through alternate bights of the bands 31, 34 and 32, 33 respectively.
Although the invention has heretofore been particularly described with reference to a reeded construction of rectangular building with the reeds running longitudinally thereof, it should be understood that such reeds may equally well be directed at right angles to the length of the building and that the latter may be of square or irregular planform, the reeds in the last-mentioned case being directed either longitudinally or transversely and of diiferent lengths.
The subdivision of the enclosed space by rows of guylines leading to ground-anchors does not constitute any serious detriment in the case of an exhibition hall, since stands erected within the latter can be placed in corresponding rows with unobstructed aisles between them.
However, such an arrangement would obviously be impracticable in a building erected over a sports stadium, and for covering such an arena or when the building is made of very wide span for the purpose of roofing over a valley or other natural feature (for example, to conceal or shelter military installations located therein) the method of anchorage illustrated in FIGS. and 11 may be adopted, each row of guy-lines 14 forming the additional anchorages being connected to a strong cable 37 whose ends are fixed to the ground or to artificial supports, which will normally be at a higher level than the area to be covered. It should be emphasized however, that in erecting such a building the contour of the ground covered is quite unimportant; that is to say, the building can be arranged to con ceal or shelter a hillock just as easily as a depression.
When roofing over a valley 38 as shown, a plurality of such cables 37 of appropriate length and breaking strain are slung side-by-side between reinforced concrete blocks 39 or other secure fixtures provided at equal horizontal intervals, along opposite sides of such valley. As seen in elevation, each such side has the cable attachment points 39 situated along an upwardly convex line, whilst the endmost cables 37 may have their extremities fixed at or adjacent the floor of the valley 38.
Suitable members of the panels 11 are assembled in endwise overlapping relation to form complete canopy sections each of a width somewhat greater than the horizontal spacing of the cables 37 and exceeding by one the number of such cables provided.
In erecting the canopy 10 the several multipanel sections thereof are hauled endwise on to the sagging cables 37 and allowed to drape over the latter as shown in FIG. 12,
. 6 while the connection of their lateral edges (preferably by the means illustrated in FIG. 9) and attachment of their guy-lines 14 to the cables is being progressively effected.
When the whole area to be concealed or sheltered has been covered in this manner, the periphery of the canopy 16 (as represented by the free edges of its two endmost sections and the extremities of those intervening) is lo- 7 cated either by attachment to screw-pickets or by ballasting as previously described.
On inflation of the canopy it} to a reeded form, the uplift load is transmitted through the rows of guy-lines 14 to the cables 37 which thereupon adopt inverted catenary curves as shown.
The canopy may, of course, be stabilized against wind forces, by connecting each of several tethering points 12 to spaced points on the adjacent cable 37 or to corresponding points in two adjacent cables.
When a similar building is to be erected over a sports stadium or the like, the cables 37 may be anchored to the tops of stands or banked seating ll around the arena 41, as shown in FIG. 13, or such stands or banking may provide abutments for cables anchored at ground-level externally thereof. It will be noted that FIG. 13 also illustrates the alternative arrangement of the canopy 10 with its reeds running transversely of the cables 37.
I claim:
1. An inflatable building comprising, a canopy composed of a plurality of connected flexible strips having inturned longitudinal edge portions forming dependent flaps, the flaps on one panel being facially opposed to those on adjacent panels, loop members passing through the flaps of adjacent panels, tethering cables extending from the loop members to the ground, and drain strips on the canopy mounted over the meeting points of adjacent flaps and bridging the points of connection of the same.
2. An inflatable building as provided for in claim 1, wherein the tethering cables extend divergently from the loop members to the ground, and detachable fastening means provided between the faces of the flaps to couple the same together.
3. An inflatable building according to claim 1 in which touch fastener strips are located on adjacent panels, said touch strips being adhered to each other and sealing against air pressure leakage at the junction of said panels.
4. An inflatable building comprising, a canopy composed of a plurality of connected flexible panels at least one of which has inturned longitudinal edge portions forming dependent flaps, the flaps on one panel being facially opposed to the adjacent panel, the lower edges of adjacent panels being out of contact, a strip having one edge attached to an intermediate portion of said one panel, said strip depending below said panels, and means on the lower end of said strip for anchoring the same to a fixed base.
5. An inflatable building according to claim 4 in which a drain band is attached to the outer face of said canopy at the junction of said strip with said adjacent panel.
6. An inflatable building comprising a plurality of elongated panels convex in cross-section and located sideby-side, the lower edges of adjacent panels being in juxtaposed position over a substantial area, air pressure within said canopy pressing on said panels causing said lower edges to seal the joints between said adjacent panels against leakage from inside the canopy, means attached to said lower edges at spaced points having tethers thereon extending to and anchored in a fixed base.
7. An inflatable building comprising a canopy composed of at least one pair of convex panels connected together at their lower edges, said connection including the lower edges of said panels being inturned, means securing the lower edges together and anchoring said panels to a fixed base, touch fastener strips facing each other on said lower edges of said panels, said touch fastener strips being J adhered to eachothar and sealing against air leakage out of said building at the connection between said panels.
FOREIGN PATENTS 128,422 6/ 19 Great Britain. References Qited Eiy'the Examiner 2 ,1 7/25 Great Britain.
UNITED S TES PATENTS 5 3;; gg
5/11 Schutte 244128 X r HARRISON R. MOSELE-Y, Primary Examiner.
6/57 Leathertman 13515X T 1 v 9/58 Lcatheman 135 1 10 DONLEY J. SLOCKING, CHARLES QCONNELL, 2/60 Cline 135-4 X Examiners. 3/62 Bird 135-1

Claims (1)

  1. 6. AN INFLATABLE BUILDING COMPRISING A PLURALITY OF ELONGATED PANELS CONVEX IN CROSS-SECTION AND LOCATED SIDEBY-SIDE, THE LOWER EDGES OF ADJACENT PANELS BEING IN JUXTAPOSED POSITION OVER A SUBSTANTIAL AREA, AIR PRESSURE WITHIN SAID CANOPY PRESSING ON SAID PANELS CAUSING SAID LOWER EDGES TO SEAL THE JOINTS BETWEEN SAID ADJACENT PANELS AGAINST LEAKAGE FROM INSIDE THE CANOPY, MEANS ATTACHED TO SAID LOWER EDGES AT SPACED POINTS HAVING TETHERS THEREON EXTENDING TO AND ANCHORED IN A FIXED BASE.
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US3277615A (en) * 1964-04-14 1966-10-11 Danny C Marquez Air-inflated building structure
US3373531A (en) * 1966-04-04 1968-03-19 Air Tech Ind Inc Wide span inflated structure
US3391504A (en) * 1967-03-13 1968-07-09 Terence W. Mclorg Air supported shelter
FR2081791A1 (en) * 1970-03-09 1971-12-10 Goodyear Tire & Rubber
US3762108A (en) * 1969-08-18 1973-10-02 Environmental Structures Inc Inflatable building with reinforced seam
US3854257A (en) * 1973-08-27 1974-12-17 M Lobel Sealing structure
US3857209A (en) * 1973-11-02 1974-12-31 Goodyear Tire & Rubber Inflatable shelter and flexible wall therefor
US3924363A (en) * 1974-05-22 1975-12-09 Goodyear Tire & Rubber Inflatable shelter
US4047335A (en) * 1975-11-18 1977-09-13 Darmstadt Robert M Pneumatic load-supporting structures
US4096669A (en) * 1977-07-06 1978-06-27 Seaman Corporation Membrane building segment connection
US4257199A (en) * 1979-05-31 1981-03-24 Kazuo Kuboyama Stadium cover
US4676032A (en) * 1983-10-28 1987-06-30 Pierre Jutras Inflatable wall structure
JPS63277382A (en) * 1987-05-08 1988-11-15 株式会社竹中工務店 Method and device for introducing tension in suspension film structure
EP0490628A1 (en) * 1990-12-10 1992-06-17 Michael A. Thompson Indoor golf facility
US5904003A (en) * 1998-04-09 1999-05-18 Stephen; John W. Retractable stadium cover
US6571815B1 (en) 2001-07-24 2003-06-03 Jimmy Hill Sun shield
US20090145046A1 (en) * 2005-10-14 2009-06-11 Thoeny Theodore T Inflatable structures
US10287795B2 (en) * 2017-03-06 2019-05-14 Air Structure American Technologies, Inc. Raceways for fabric structures

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GB128422A (en) * 1918-07-03 1919-06-26 George Holt Thomas Improvements in Airships.
US1402077A (en) * 1920-03-16 1922-01-03 Lanchester Frederick William Construction and roofing of buildings for exhibitions and like purposes
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Cited By (22)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3277615A (en) * 1964-04-14 1966-10-11 Danny C Marquez Air-inflated building structure
US3373531A (en) * 1966-04-04 1968-03-19 Air Tech Ind Inc Wide span inflated structure
US3391504A (en) * 1967-03-13 1968-07-09 Terence W. Mclorg Air supported shelter
US3762108A (en) * 1969-08-18 1973-10-02 Environmental Structures Inc Inflatable building with reinforced seam
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US3638368A (en) * 1970-03-09 1972-02-01 Environmental Structures Inc Inflatable shelter and method of erection
US3854257A (en) * 1973-08-27 1974-12-17 M Lobel Sealing structure
US3857209A (en) * 1973-11-02 1974-12-31 Goodyear Tire & Rubber Inflatable shelter and flexible wall therefor
US3924363A (en) * 1974-05-22 1975-12-09 Goodyear Tire & Rubber Inflatable shelter
US4047335A (en) * 1975-11-18 1977-09-13 Darmstadt Robert M Pneumatic load-supporting structures
US4096669A (en) * 1977-07-06 1978-06-27 Seaman Corporation Membrane building segment connection
US4257199A (en) * 1979-05-31 1981-03-24 Kazuo Kuboyama Stadium cover
US4676032A (en) * 1983-10-28 1987-06-30 Pierre Jutras Inflatable wall structure
JPS63277382A (en) * 1987-05-08 1988-11-15 株式会社竹中工務店 Method and device for introducing tension in suspension film structure
EP0490628A1 (en) * 1990-12-10 1992-06-17 Michael A. Thompson Indoor golf facility
US5904003A (en) * 1998-04-09 1999-05-18 Stephen; John W. Retractable stadium cover
US6571815B1 (en) 2001-07-24 2003-06-03 Jimmy Hill Sun shield
US20090145046A1 (en) * 2005-10-14 2009-06-11 Thoeny Theodore T Inflatable structures
US10287795B2 (en) * 2017-03-06 2019-05-14 Air Structure American Technologies, Inc. Raceways for fabric structures
US20190226226A1 (en) * 2017-03-06 2019-07-25 Air Structures American Technologies, Inc. Raceways for fabric structures
US10822828B2 (en) * 2017-03-06 2020-11-03 Air Structures American Technologies, Inc. Raceways for fabric structures

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