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A durable, semi-rigid, single-layered flexible duct having a sleeve made of a single aluminum layer and a resilient wound element disposed at the mid-point of the overlap region of the aluminum layer. The wound element imparts corrugations to the sleeve, such that the duct is extendible between a co

A durable, semi-rigid, single-layered flexible duct having a sleeve made of a single aluminum layer and a resilient wound element disposed at the mid-point of the overlap region of the aluminum layer. The wound element imparts corrugations to the sleeve, such that the duct is extendible between a compacted configuration suitable for storage and for shipping and an extended configuration suitable for installation in a gas transport arrangement. Closely and evenly-spaced ridges that are situated in between the corrugations, add rigidity and durability to the duct. The inward-facing surface of the aluminum ribbon is substantially smooth and featureless except for the helical corrugations imparted by wire winding and the closely and evenly-spaced ridges. The aluminum sleeve is of a predetermined thickness rendering the duct substantially rigid when in an extended configuration and enabling the duct to maintain its substantial rigidity upon extension from a compacted configuration.

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1. A durable semi-rigid, flexible duct having an axis running the length of said duct, comprising: a single aluminum ribbon, having an innermost and outermost side;a resilient wound element, wherein said wound element is disposed at the mid point of the overlap region of said aluminum ribbon, such t

1. A durable semi-rigid, flexible duct having an axis running the length of said duct, comprising: a single aluminum ribbon, having an innermost and outermost side;a resilient wound element, wherein said wound element is disposed at the mid point of the overlap region of said aluminum ribbon, such that said innermost side of said ribbon overlaps with the outermost side of a previous wrapping;wherein said wound element imparts corrugations to said aluminum ribbon, said aluminum ribbon being formed with a plurality of closely and evenly-spaced ridges embossed in between a pair of said corrugations, such that said duct is axially extendible between a compacted configuration suitable for storage and for shipping and an extended configuration suitable for installation in an air transport arrangement;wherein said aluminum ribbon is of a predetermined thickness rendering said duct substantially rigid when in said extended configuration and enabling said duct to maintain its substantial rigidity upon extension from said compacted configuration; andwherein said closely and evenly-spaced ridges impart additional rigidity to said duct, causing said duct to be resilient and withstand heavy impact forces, which might crush the duct and reduce its diameter. 2. The duct of claim 1, wherein said duct is in said extended configuration after having been compressed to said compacted configuration, wherein the relative length between them, is in a ratio which may vary in a range between 1:2.5 to 1:5, between said compacted configuration and said extended configuration, and said aluminum ribbon having an inward-facing surface being substantially smooth and featureless except for said wound corrugations and said closely and evenly-spaced ridges. 3. The duct of claim 1, wherein said aluminum foil ribbon layer is of a thickness in a range of 80 to 100 microns. 4. The duct of claim 3, wherein, when L=2 meters and d=10 centimeters, c≦0.001M, and wherein, when said duct is in said extended configuration upon extension from said compacted configuration, c≦0.003M. 5. The duct of claim 1, wherein said duct has a cross-sectional configuration selected from the group which consists of: a circular configuration, a polygonal configuration and a compound configuration wherein said duct is partially circular and partially polygonal. 6. The duct of claim 1, wherein, when a predetermined length L of said duct, of diameter d, is in the extended configuration and is disposed horizontally and supported at a first end thereof, said duct is operative to bend under the influence of gravitational force such that a second unsupported end thereof is lower than said first supported end by no more than y, such that (y/L)×100≦p, wherein p is a predetermined percentage of L. 7. The duct of claim 1, wherein, when a predetermined length L of said duct, of diameter d, is in the extended configuration and is disposed horizontally and supported at both ends thereof, said duct is operative to bend under the influence of gravitational force such that the central portion thereof is lower than the level of said supported ends by no more than c, such that (c/L)×100≦q, wherein q is a predetermined percentage of L. 8. The duct of claim 1, wherein said resilient wound element is fabricated of a metal having spring-like resilience. 9. The duct of claim 8, wherein said resilient wound element is a wound galvanized wire having a diameter in the range of 0.9 to 1.3 millimeters. 10. The duct of claim 1, wherein said duct is selected from the group which consists of: a gas transport duct; and a duct for enclosing utility supply lines. 11. The duct of claim 1, wherein said duct has a cross-sectional configuration selected from a group which consists of: circular, polygonal, square; and rectangular configuration. 12. The duct of claim 1, wherein said closely and evenly-spaced ridges of said duct serve as threads that enable a screw-type connection. 13. The duct of claim 12, wherein said screw-type connection is provided by a duct connector ring comprising tooth-like projections matching said closely and evenly-spaced ridges of said duct, said projections provided on one side thereof, the other side thereof comprising means for connection to additional accessories. 14. The duct of claim 13, wherein said means for connection comprises an annular ridge, for connection to an adaptor ring formed with an annular groove on one side thereof, said groove matching said annular ridge of said duct connector ring, so that when said adaptor ring and said duct connector ring are brought together they connect via a snap-on connection between said annular ridge and said annular groove, and wherein the other side of said adaptor ring is the appliance connection side for connecting to at least one of a dryer and pipe. 15. The duct of claim 13, wherein said duct connector ring is connected to a lint trap, for the purpose of collecting lint that is released from said duct, so as not to allow said lint to scatter around the vicinity of the dryer, said lint trap comprising a top part having an integrally formed said adaptor ring, including said annular groove for connecting to said connector ring. 16. The duct of claim 15, wherein said duct connector ring is connected to a draft blocker which is utilized for the exhaust on the end of said duct, connecting it through a wall, said draft blocker comprising, an inlet section functioning as said adaptor ring for connecting to said connector ring threaded onto said duct. 17. A method for manufacturing a semi-rigid, flexible duct, comprising the steps of: a) providing a mandrel of preselected diameter for fabricating a duct therearound;b) providing a continuous aluminum ribbon, having an innermost and outermost side, of predetermined thickness;c) wrapping said continuous ribbon with a predetermined overlap around said mandrel to form a sleeve, wherein said sleeve is formed by the overlap of said ribbon upon itself, such that said innermost side of said ribbon overlaps with the outermost side of a previous wrapping;d) applying glue to said continuous ribbon for the bonding of said overlap, wherein said glue is cured by a drying drum;e) winding a resilient wound element disposed at the mid point of said overlap of said aluminum ribbon, thereby to form a duct; andf) forming ridges on said aluminum ribbon by causing engagement of multiple ridged break-down wheels with a modified roller, while said aluminum ribbon is in between them, wherein said ridged break-down wheel is supported by a mounting arm external to said mandrel. 18. The method of claim 17, wherein said step e) of winding a wire includes the sub-step of aligning said wire with the overlap of said first ribbon so that the wire is approximately centered at the mid-point of the overlap of said aluminum ribbon. 19. The method of claim 17, wherein said step c) of winding said aluminum ribbon and said step e) of winding the wire, are performed by rotating said mandrel as said aluminum ribbon and the wire, are respectively taken up by said mandrel, continuously and with predetermined phase differences therebetween, with respect to the rotation of said mandrel. 20. The method of claim 17, wherein said step c) of winding said aluminum ribbon and said step e) of winding the wire are performed continuously and with a first preselected phase difference therebetween, with respect to the rotation of said mandrel. 21. The method of claim 17, wherein said modified roller of said step f) of forming ridges on said aluminum ribbon, is modified by adding circumferential grooves to the distal end of said roller, and wherein said grooves match said ridges on said break-down wheels, and wherein said grooves and said ridges mesh with each other by engagement, while said aluminum ribbon is in between them, thus forming said closely and evenly-spaced ridges on said aluminum ribbon. 22. The method of claim 17, wherein said arm supporting said break-down wheel is adjustably moved into position during the setup of said manufacturing process, and once established is maintained during production. 23. The method of claim 17, and further including, after said step e) of winding, the additional step of imparting to at least a portion of said duct, a polygonal cross-sectional configuration. 24. The method of claim 23, and wherein said additional step of imparting a polygonal cross-sectional configuration to at least a portion of said duct comprises imparting thereto a square or rectangular cross-sectional configuration. 25. The method of claim 17, wherein said aluminum ribbon maintains a substantially constant and identical tension, while being wrapped around said mandrel, in the range of 75-80 kgf, and wherein said wire is also maintained in the same said tension of said aluminum ribbon. 26. The method of claim 17, wherein said mandrel comprises a plurality of rollers each mounted so as to be individually rotatable on a fixed plate at a predetermined angle, each comprising a set of precision-shaped grooves for accepting said wire, and wherein said grooves are precision-spaced apart in order to accept a predetermined flow of said wire, established by said predetermined angle of said rollers, onto said mandrel, such that said wire becomes a spiral form within said duct being drawn off said mandrel in an automatic fashion. 27. The method of claim 26 wherein each of said rollers is mounted on said plate so as to provide a flexible spring-like action which absorbs any irregularities in said tension and irregularities associated with said wire and said ribbons.