Annular-pleated circular braid
Aspects of this disclosure can be used to implement a braided cover comprising a plurality of left handed fibers and a plurality of right-handed fibers braided into a hollow tube of fabric. Such a braided cover may be adapted to form a plurality of annular ridges and annular valleys along the longitudinal length of the braided cover when compressed from an extended length to a compressed length.
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This is a continuation in part of, and claims priority from, U.S. patent application Ser. No. 14/455,461 filed on Aug. 8, 2014 titled “Retractable Elastic Bungee Hose”, which is itself a non-provisional of, and claims priority from, U.S. provisional patent application 61/864,555, filed Aug. 10, 2013, titled “Retractable Elastic Bungee Hose.” This document also claims priority from U.S. Provisional Patent Application 62/069,831, filed on Oct. 29, 2014, titled “Pleating Machine for Braided Covers”, and U.S. Provisional Patent Application 62/078,358, filed on Nov. 11, 2014, titled “Pleating Machine for Braided Tubes”. The disclosures of each of those documents, except for provisional patent application 62/078,358, are hereby incorporated by reference in their entireties.
BACKGROUND OF INVENTIONThe disclosed technology can be used to implement hollow braided covers, and more specifically to hollow braided covers that extend lengthwise when an extending longitudinal force is applied, and retract lengthwise when a retracting longitudinal force is applied.
BACKGROUND Prior ArtThe present state of the art of linearly extendable and retractable hoses includes both spring biased and elastic biased hoses. Prior art designs seen in U.S. Pat. No. 8,291,941 and U.S. Pat. No. 8,479,776 comprise two connector ends with an inner elastic tube and an inelastic outer cover. The outer cover and the inner elastic tube are connected at one end to an inlet connector (source connector) and connected at their other end to an outlet connector. The inelastic outer cover is generally unattached, unbonded, and unsecured to the inner elastic tube between the two connector ends. The outer covers comprise a braided or woven nylon, polyester or polypropylene, and/or other braided or woven material. The braided or woven outer cover is designed to not expand radially or longitudinally so that, the actual length and width of the outer cover determines the maximum length and maximum width of the hose in its expanded condition. Thus, this final length and diameter of the non-elastic outer cover is the final diameter and the final length of the extendable and retractable hose when it is in its expanded condition and in use to transport or deliver a fluid. These prior art elastic hoses also have covers that maintain the same wall thickness in both the extended and retracted positions. This means that the outer cover must fold when the hose retracts.
SUMMARYThe disclosed technology can be used to create an annularly pleated circular braid that allows for much greater extension ratios than are currently possible with a standard braided cover. This is because the annular pleats on the braided cover allow the braided fabric to compress more compactly longitudinally. The disclosed annularly pleated circular braid can be used to implement both bungee cords and self-extending hoses with expansion ratios well over 6-to-1. The disclosed technology can also be used to implement elastic extendible and retractable hoses 30, 40 and 50 (bungee hoses) and bungee cords 60 and, 63, and 65 which can comprise a pleated bungee-like outer cover 36 to provide greater extension ratios, better environmental wear resistance (i.e. friction with ground) and/or lower stresses between inner elastic tubes 34 and 44, and outer cover 36. Unlike prior art outer cover 26 which defines a maximum length and a maximum width (diameter), the disclosed outer cover 36 can extend and contract lengthwise (longitudinally), and also expand and contract width-wise (radially).
The disclosed elastic retractable and extendible pressure hoses 30, 40 and 50 will also be referred to in this document as an “elastically retractable pressure hose”, “elastic retractable hose”, “retractable hose”, “elastic bungee hose”, “bungee hose”, and possibly other similar terms. These bungee hose designs can be implemented with an outer cover 36 that has significantly different properties and structure from prior art outer covers. For example, outer cover 36 can be braided, knitted, woven, and/or wrapped so that it can widen radially when it is longitudinally retracted and constrict radially when longitudinally lengthened. This means that outer cover 36 may have neither a well-defined maximum length, nor a well-defined maximum diameter (width). Outer cover 36 seen in
Outer cover 36 can have a similar structure to the braided cover on prior art bungee cords or shock cords commonly found today. Outer cover 36 and bungee cord covers can extend and retract with their inner elastic cores (which could be, for example, an elastic tube or a set of one or more elastic cords) without the need for significant folding or unfolding of the outer cover material, or significant motion between the elastic inner core and the outer cover. However, to achieve significant expansion ratios for the hoses disclosed herein, a controlled pleating of the outer cover can be used. Thus, outer cover 36 can be designed to fold and compress into evenly spaced and like-sized annular ridges 36r (pleats) along its length when retracted. This can provide an improved appearance for the elastic retractable hose in its retracted position when compared to prior art retractable elastic hoses which generally fold into a haphazard jumble of folded fabric along its length. Like a bungee cord, outer cover 36 can be designed to increase in diameter and thickness as it retracts longitudinally to provide a smooth transition between extended and retracted lengths. The result is that an outer cover 36 such as disclosed herein can provide a substantially even and smooth exterior for retractable hoses 30, 40 and 50 when fully retracted and provide a finished and an esthetically pleasing look to bungee hoses 30, 40 and 50.
The outer ridges 36r of cover 36 can also be coated with a wear resistant material to create wear rings 39. This can provide a more durable exterior surface for cover 36, and also help cover 36 consistently return to its pleated retracted shape. Outer cover 36 can also have a wall thickness that can thicken as cover 36 is retracted and thin as cover 36 is extended lengthwise (extend longitudinally). These properties of outer cover 36, where they are present, can provide retractable hoses 30, 40 and 50 with the feel of a bungee-cord both when extended and retracted, as well as providing other benefits, such as a better esthetic appearance when retracted, greater extension to retracted length ratios, and the ability to use higher denier yarns to improve the wear resistance of outer cover 36. Also an outer cover 36 can be implemented to have the ability to move and expand with inner elastic tubes 34 and 44, which can reduce wear on the outer surface of elastic tube 34 and 44 thereby increasing the useful life of hoses 30, 40 and 50.
OBJECTIVES AND ADVANTAGESAccordingly, several objects and advantages which can be obtained using various embodiments of the disclosed technology are:
Protecting Inner Elastic Tube
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- a) To provide an elastically retractable pressure hose (bungee hose) comprising a braided, knitted, woven, and/or wrapped reinforcement outer cover that can extend and retract along with an inner elastic tube to reduce friction and wear between the inner elastic tube and reinforced outer cover.
- b) To provide an elastically retractable pressure hose comprising a hollow braided reinforcement outer cover that can extend and retract along with an inner elastic tube to reduce friction and wear between the inner elastic tube and reinforced outer cover.
- c) To provide an elastically retractable pressure hose comprising a braided, knitted, woven, and/or wrapped reinforcement outer cover that can extend and retract along with an inner elastic tube to reduce friction and wear between the inner elastic tube and reinforced outer cover, with a solid lubricant applied to the interior of the outer reinforcement cover and/or to the outer surface of the inner elastic tube.
- d) To provide an elastically retractable pressure hose comprising a hollow braid outer cover that can extend and retract along with an inner elastic tube to reduce friction and wear between the inner elastic tube and reinforced outer cover, with a solid lubricant applied to the interior of the outer reinforcement cover and/or to the outer surface of the inner elastic tube.
- e) To provide an elastically retractable pressure hose comprising a braided, knitted, woven, and/or wrapped reinforcement outer cover that can extend and retract along with an inner elastic tube to reduce friction and wear between the inner elastic tube and reinforced outer cover, with a lubricant applied to the interior of the outer reinforcement cover and/or to the outer surface of the inner elastic tube.
- f) To provide an elastically retractable pressure hose comprising a hollow braided outer cover that can extend and retract along with an inner elastic tube to reduce friction and wear between the inner elastic tube and reinforced outer cover, and a solid lubricant applied to the interior of the outer reinforcement cover and/or to the outer surface of the inner elastic tube.
- g) To provide an elastically retractable pressure hose comprising a hollow braided outer cover that can extend and retract along with an inner elastic tube to reduce friction and wear between the inner elastic tube and reinforced outer cover, and a liquid lubricant applied to the interior of the outer cover and/or to the outer surface of the inner elastic tube.
- h) To provide an elastically retractable pressure hose comprising a braided, knitted, woven, and/or wrapped reinforced outer cover and an inner elastic tube, where the structure of the outer cover allows it to extend and contract longitudinally with the inner elastic tube.
- i) To provide an elastically retractable pressure hose comprising a braided, knitted, woven, and/or wrapped reinforced outer cover and an inner elastic tube, where the structure of the outer cover increases in diameter when compressed longitudinally and decreases in diameter when extend longitudinally, whereby the outer cover can extend and retract along with the inner elastic tube to reduce friction and wear between the inner elastic tube and reinforcement outer cover.
- j) To provide an elastically retractable pressure hose comprising a reinforcement outer cover and an inner elastic tube, where the structure of the outer cover allows it to extend and contract longitudinally with the inner elastic tube and wherein a plurality of friction and/or bonding points are defined on the retractable pressure hose that bond the inner elastic tube to the interior surface of outer cover to stabilize the inner elastic tube and minimize localized overstretching and breakage of the inner elastic tube.
- k) To provide an elastically retractable pressure hose comprising a reinforcement outer cover and an inner elastic tube with a plurality of protrusions on the inner elastic tube (ring shaped protrusions, bumps, etc.) for stabilizing the inner elastic tube within the reinforcement cover to prevent localized overstretching and breakage of the inner elastic tube, where the structure of the outer cover allows it to extend and contract longitudinally with the inner elastic tube.
- l) To provide an elastically retractable pressure hose comprising a reinforcement cover and an inner elastic tube with a plurality of ring shaped bonds between the reinforcement cover and the inner elastic tube are used to stabilize the inner elastic tube within the reinforcement cover to prevent localized over-stretching and breakage of the inner elastic tube, where the structure of the outer cover allows it to extend and contract longitudinally with the inner elastic tube.
- m) To provide an elastically retractable pressure hose comprising a reinforcement outer cover and an inner elastic tube, wherein the structure of the outer cover allows it to extend and contract longitudinally with the inner elastic tube, wherein the inner elastic tube has a natural outside diameter that is substantially the same as the natural inside diameter of the outer cover when the hose is collapsed, and wherein the inner elastic tube provides support for the outer cover when the hose is retracted so that the outer cover retracts to a smooth exterior surface (very few folds in outer cover fabric).
- n) To provide an elastically retractable pressure hose comprising a reinforcement outer cover and an inner elastic tube, wherein the structure of the outer cover allows it to extend and contract longitudinally with the inner elastic tube, wherein the inner elastic tube has a natural length that is matched to the length of the outer cover when compressed longitudinally, so that the outer cover collapses to a smooth outer surface and fibers making up the outer cover are snugly packed longitudinally, and wherein the inner elastic tube provide support for the outer cover when the hose is retracted, but does not bind against the outer cover when retracted.
Bonded Elastic Tube
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- o) To provide an elastically retractable pressure hose (bungee hose) comprising a tube shaped outer reinforcement cover and an inner elastic tube (inner elastic hose), where the inner elastic tube provides a retracting bias to retract the retractable pressure hose, where the inner elastic tube is bonded to the outer reinforcement cover at a plurality of separate areas to control the longitudinal collapse and folding of the outer reinforcement cover when the linearly retractable pressure hose retracts, wherein the structure of the outer cover allows it to extend and contract longitudinally with the inner elastic tube.
- p) To provide an elastically retractable pressure hose comprising a tube shaped outer reinforcement cover and an inner elastic tube, where the inner elastic tube provides a retracting bias to retract the retractable hose, wherein the structure of the outer cover allows it to extend and contract longitudinally with the inner elastic tube, wherein the inner elastic tube is bonded periodically to the outer reinforcement cover with a plurality of annular ring shaped bonds for longitudinal controlling the collapse and folding of the outer reinforcement cover when the linearly retractable pressure hose retracts, and wherein an optional lubricant can be applied between the plurality of annular ring shaped bonds to the interior surface of the outer reinforcement cover and/or to the exterior surface of the inner elastic tube to reduce friction between the two surfaces.
- q) To provide an elastically retractable pressure hose comprising an outer reinforcement cover encompassing an inner elastic tube, wherein the structure of the outer cover allows it to extend and contract longitudinally with the inner elastic tube, where the inner elastic tube provides a retracting bias to retract the retractable hose, wherein the inner elastic tube is bonded to the inside of the outer reinforcement cover with a plurality of small bonding spots or dots across its surface to control the longitudinal collapse and folding of the outer reinforcement cover when the linearly retractable pressure hose retracts and extends, and wherein an optional lubricant can be applied between the plurality of small bonding spots or dots to the interior surface of the outer reinforcement cover and/or to the exterior surface of the inner elastic tube to reduce friction between the two surfaces.
- r) To provide an elastically retractable pressure hose comprising an outer reinforcement cover and an inner elastic tube, where the inner elastic tube is a substantially cylindrical tube and provides a retracting bias for retracting the retractable hose, wherein the structure of the outer cover allows it to extend and contract longitudinally with the inner elastic tube, wherein the inner elastic tube is bonded periodically to the inside of the reinforcement outer cover to control the longitudinal collapse and folding of the reinforcement outer cover when the linearly retractable pressure hose retracts, wherein an optional lubricant can be applied between the periodic bonds to the interior surface of the outer reinforcement cover and/or to the outer surface of the inner elastic tube to reduce friction between the two surfaces.
- s) To provide an elastically retractable pressure hose comprising a reinforcement outer cover and an inner elastic tube, wherein the structure of the outer cover allows it to extend and contract longitudinally with the inner elastic tube, wherein the inner elastic tube has a plurality of protrusions on its exterior surface (e.g. ridges, bumps, etc.) and provides a retracting bias for retracting the retractable hose, wherein the inner elastic tube has a natural outside diameter that is substantially the same as the natural inside diameter of the outer cover when the hose is collapsed, wherein the inner elastic tube provide support for the outer cover when the hose is retracted so that the outer cover retracts to a smooth exterior surface (few misplaced or misshaped folds in outer cover fabric).
- t) To provide an elastically retractable pressure hose comprising a reinforced outer cover and an inner elastic tube, wherein the structure of the outer cover allows it to extend and contract longitudinally with the inner elastic tube, wherein the inner elastic tube has a plurality of protrusions on its exterior surface (e.g., ridges, bumps, etc.) and provides a retracting bias for retracting the retractable hose, wherein the inner elastic tube has a natural length that is matched to the length of the outer cover when compressed longitudinally, so that the outer cover collapses to a smooth outer surface and fibers making up the outer cover are snugly packed longitudinally, wherein the inner elastic tube provide support for the outer cover when the hose is retracted but does not bind against the outer cover when retracted.
- u) To provide an elastic retractable pressure hose such as described in items e) through t) wherein a solid lubricant is such as a paraffin wax, Teflon coating, and/or other solid polymer coatings is used between the inner elastic tube and outer cover.
- v) To provide an elastic retractable pressure hose such as described in items e) through t) wherein a liquid lubricant such as a natural oil, synthetic oil, gel, or other oily liquid is used between the inner elastic tube and the outer cover.
- w) To provide an elastic retractable pressure hose such as described in items e) through t) wherein a lubricant between the inner elastic tube and the outer cover reduces chaffing and wear on the exterior surface of the inner elastic tube.
- x) To provide an elastic retractable pressure hose that has a retracted length and a wide range of extended lengths dependent on tension supplied by the use to the exterior of the hose.
Pleated Circular Braid
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- y) To provide a hollow or circular braided tube with annular pleats formed along a longitudinal length of the braided tube.
- z) To provide a hollow or circular braided tube adapted to form annular pleats along its length when shortened to a retracted position.
- aa) To provide a hollow or circular braided tube with annular pleats that are heat set into yarn used to form the braided tube.
- bb) To provide a hollow or circular braided tube with annular pleats that are heat set into yarn used to form the braided tube, wherein the heat set comprises melting the outer annular ridges of the pleats.
- cc) To provide a hollow or circular braided tube with annular pleats that are heat set into yarn used to form the braided tube, wherein the heat set comprises bonding a ring polymer to the outer annular ridges of the annular pleats.
FIG. 4C Elastic bungee cord comprising a pleated braided cover and an inner plurality of elastic cords.
FULLY RETRACTED LENGTH or Retracted Length—this should be understood as, for a Bungee hose (retractable hose) and the components disposed along its length (e.g., outer cover 36, inner elastic tube 34, etc) the length of the hose or those components when they are fully retracted (i.e., when there is substantially no fluid pressure within its elastic tube and a minimal amount of external tension on the bungee hose itself).
EXTENDED LENGTH—this should be understood as, for a retractable hose and the components disposed along its length, the length the hose or those components extend to when the hose is pressurized with a fluid and no extension forces are applied other than fluid pressure.
FULLY EXTENDED LENGTH—this should be understood as, for a retractable hose and the components disposed along its length, the length to which the hose or components return when (1) an external pressure which stretched the hose to its Maximum Stretched Length (defined infra) has been removed and (2) there is a differential between ambient pressure and pressure for fluid inside the hose sufficient to extend the hose at its extended length. In general, the Fully Extended Length for a given hose or component will be greater than the Extended Length for that same hose or component, due to resistance exerted by the components of the hose to fully returning to the Extended Length. The differential between Fully Extended Length and Extended Length for any particular hose will largely be based on the friction between the components making up the hose. For lubricated hoses the Fully Extended Length might only be a few percent longer than the Extended Length, while for nonlubricated hoses, the Fully Extended Length might be up to fifteen percent (or more) longer than the Extended Length.
MAXIMUM STRETCHED LENGTH—this should be understood as, for a retractable hose and the components disposed along its length, the length of the hose (or components) when the hose has reached the approximate maximum length to which it can safely be stretched. In most cases this is significantly beyond the Fully Extended Length of the bungee hose (e.g., the Maximum Stretched Length could exceed the Extended Length by 25% or more, while the Fully Extended Length will generally only be 10-15% longer than the Extended Length). For example, in a recent bungee hose prototype, the prototype bungee hose had a Fully Retracted Length of four feet, and would grow to approximately twelve feet from water pressure alone (its Extended Length). After the user pulled on the end of the prototype hose and released it, the prototype bungee hose would maintain a length slightly over thirteen feet (its Fully Extended Length). However, the user could then pull on the end of the bungee hose and stretch it out to twenty feet using about two-hundred Newton (forty-five pounds) of force (tension). This might be considered its Maximum Stretched Length, since greater tension could cause the hose to exert a retractive force which could be high enough to be unsafe for the user, even though the breaking strength of the prototype hose's outer cover was over 2,000 Newton (approximately five-hundred pounds) and more force could be applied to lengthen the hose slightly further. However, application of tension force beyond two-hundred Newton will only slightly further increase the length of the hose and is thus a reasonable force to create a maximum stretched length.
PITCH ANGLE—this should be understood as the angle between the longitudinal axis of fibers comprised by an outer cover and the transverse direction for that cover (transverse direction is shown as vertical in
In
In
In
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In
As stated previously, in
In
With bungee hose 30 in its retracted position, as seen in
When additional tension is added (e.g., as a result of pulling by the user) to bungee hoses 30, 40 or 50, the pitch angle of yarns 36a-b can increase to intermediate pitch angle P2 and beyond. Pitch angle P2 is greater than the pitch angle of approximately 30 degrees which bungee hoses 30, 40 or 50 would achieve when extended by internal pressure alone (i.e., when extended to their Extended Length), but less than the angle such hoses would achieve when extended to their Maximum Stretched Length. The yarns 36a-b can then be held at an intermediate pitch (i.e., when extended to the Fully Extended Length) even after the additional tension is released (e.g., when a user stops pulling) as a result of friction between the yarns 36a-b and the elastic tube 34 and between the yarns 36a-b themselves. For example, prototype hoses have been produced using circular braided tubes for an outer cover 36 made up of yarns having pitch angles of approximately ten degrees when retracted. With a ten degree yarn pitch angle, the prototype hoses were able to expand to a fully extended length of approximately three times their retracted length. Prototypes that had their outer cover compressed even further (even smaller pitch angles from the transverse direction) were able to achieve fully extended lengths greater than four times their retracted length without a stretching force on the hose. When continuously pulled on (stretched) by the user, these prototype hoses easily reached five to six times their retracted lengths during use.
As hose 30 (and hoses 40 and 50) are extended, outer cover 36 tends to go from a larger diameter D3 to a smaller diameter D4. Diameter D4 can be significantly smaller than diameter D3 so that inner elastic tube 34 does not have to expand much radially when pressurized. The angle of yarns 36a-b causes this shrinkage in diameter to happen because of straightening out of the yarns when they are pulled longitudinally. As the pitch angle of yarns 36a-b increases, the diameter of outer cover 36 decreases. With fluid pressure within elastic tube 34, elastic bungee hoses 30, 40 and 50 are easily stretchable by the user simply pulling on the end. This pulling action can further reduce the diameter of outer cover 36 below diameter D4. As outer cover shrinks in diameter, inner elastic tube 34 must also reduce in diameter. Because elastic tube 34 decreases in diameter as the bungee hose is extended, the overall strain within elastic tube 34 is less than if outer cover 36 did not decrease in diameter. Thus, this type of bungee hose can easily reach high expansion ratios without rupturing. Using the disclosed technology, a bungee hose can be implemented which can easily be stretched an additional thirty percent further than its Fully Extended Length simply by being pulled on. This can provide a very stretchable feel, similar to a bungee cord.
In outer cover 36, the denier of the yarn used to form the outer cover influences the ultimate compression ratio in the longitudinal direction, because the yarns can more easily pile up on one another if they are smaller in cross-section. Note that when yarns 36a-b are being compressed in the longitudinal direction, they also tend to expand in the radial direction. During this radial expansion, the radial thickness of outer cover 36 can remain relatively constant for particular ranges of expansion and contraction. As yarns 36a-b are angled closer to the transverse direction (smaller pitch angle), the yarns tend to define a larger diameter on their exterior while at the same time the yarns can define a smaller interior diameter as cover 36 is longitudinally compressed (retracted). In prototype designs, the interior diameter of the outer cover was closely matched with the outside diameter of the inner elastic tube. A small amount of space was left between the inner elastic tube and the pleated outer cover to allow the outer cover to slide freely over the elastic tube. This arrangement provided a well organized and smooth exterior to the prototype hoses when retracted.
Retractable hoses 30, 40 and 50 can have a similar structure with the proper dimensions of outer cover 36, and inner elastic tube 34 or 44. With the correct size of inner elastic tube 34 and outer cover 36, combined with a gentle longitudinal compressive force from the elastic tube (elastic tube 34 length chosen to match compressed length of outer cover 36), then a smooth outer surface can be formed on outer cover 36 with the exterior of elastic tube 34 gently supporting the interior surface of outer cover 36 when retracted. The retracted position seen in
In
In the extended position seen in
In
In
In
In
In
In
Wear rings 39 can provide dimensional stability to hose 50 which tends to return outer cover 36 to the same retracted configuration when pressurized and depressurized over and over again (e.g., if the combined length of the wear rings 39 is greater than the length the hose 50 would take when depressurized in the absence of the rings, then the combined length of the rings can place a limit on the hose's ability to retract, and the outer surfaces could, when the hose 50 is at its retracted length, provide an unbroken barrier between the outer cover 36 of the hose 50 and the surrounding environment). When hose 50 is extended, wear rings 39 protrude outward away from the surface of outer cover 36 to protect cover 36 from wear against surfaces such as pool decks, driveways, sidewalks, etc. Outlet connector 28 is designed to transfer fluid (liquid or gas) from interior channel 35 to an external nozzle or other device that provides a restriction to the flow of fluid through hose 50. Outlet connector 28 is connected to inner elastic tube 34 and outer cover 36 on the opposite end from inlet connector 22, and can be designed to connect to various nozzles or applicator attachments. Outlet connector 28 can be designed with a flow restriction ridge 29 to restrict fluid flow (gas or liquid) out of hose 50 and helps build pressure within elastic tube 34 to extend hose 50 for use.
In
Pleated outer cover 36 can also be used as a bungee cord cover to allow the elastic cords an inner elastic core inside to be stretched more than six times their its original length. In FIGS. 4A-B 4A-C, we see bungee style tie-downs developed by the inventor for use in tying or securing items for travel. Prior to the development of the longitudinally pleated braid, conventional Bungee Cords were limited to approximately 2× (two times their retracted length). Now with the longitudinally pleated braid, 6× or more expansion is possible for a bungee style tie-down. This allows a one-foot long elastic cord core, incorporating an outer cover made with the disclosed longitudinal pleating technology, to operate as a bungee cord and stretch up to six feet to tie down items like a bungee cord. Various types of inner elastic core can be used in this type of implementation, and
In FIGS. 4A-B 4A-C, we see bungee cords 60 and 63 and 65 using pleated cover 36 to obtain a high stretched-to-retracted length ratio. Bungee cord 60 comprises previously discussed elastic tube 34 and pleated braided cover 36. Both elastic tube 34 and braided cover 36 are attached to bungee cord hook end 62 at one end and attached to a similar hook end at their other ends. Ribs 33 and lubricant 37 are optional. Bungee cord 63 comprises previously discussed pleated braided cover 36 and a solid core elastic band cord 64. Bungee cord hook end 62 is attached to one end of both braided cover 36 and elastic band cord 64 and a second hook end (not shown) similar to hook end 62 is attached to the other ends of braided cover 36 and elastic band cord 64. Bungee cord 65 comprises previously discussed pleated braided cover 36 and a plurality of elastic cords 67 positioned within the breaded cover 36. Bungee cord hook end 62 is attached to one end of both braided cover 36 and elastic cords 67 and a second hook end (not shown) similar to hook end 62 is attached to the other ends of braided cover 36 and elastic cords 67.
In FIGS. 4A-B 4A-C, we see two three bungee cords 60 and 63, respectively and 65 comprising hook ends 62, a pleated outer cover 36 and an elastic core comprising either elastic hose tube 34 or, solid core elastic cord 64, and a plurality of elastic cords 67, respectively. In
In
In FIGS. 4A-B 4A-C, pleat ridges 36r have been heat set into the outer cover 36 so that it tends to form the annular pleats as shown when retracted. Setting the shape of the pleats can contribute to the stable operation of pleated braided cover 36. In embodiments where the pleats' valleys 36v and/or ridges 36r are not stabilized on cover 36, the pleated cover can be at greater risk of losing its orderly shape and not retracting properly. Several methods can be used to stabilize the pleats, such as: 1) bonding a polymer material to fibers and/or yarns 36a-b at ridges 36r on cover 36 (see
In
As the burner nozzles 72 direct their flames 71 across the outer surface of pleated cover 36, the intense heat from the high temperature flames 71, may require only a fraction of a second to melt the outer surface of ridges 36r and form the plurality of melted surfaces 77 on the exposed portions of yarns 36a-b. During this melting process, the interior portions of pleated braided cover 36 can remain relatively cool compared to ridges 36r. Braided cover 36 can be slightly extended longitudinally from its fully compressed (fully retracted) position during the melting process so that ridges 36r do not significantly touch their neighbors on either side. With cover 36 slightly longitudinally extended in this way, flames 71 tend to cool quickly as they passes through the narrow gap between pleats (between ridges 36r) and tend not to provide sufficient heat to bond the sides of the pleats together where the pleats might be lightly touching each other.
Each of the yarns 36a-b can comprise many individual filaments that can be twisted together or untwisted. In
In
Adhesives
As the reader should understand from the previous discussions, the use of bonding agents, bonding structures, and adhesives for bonding specific components of the disclosed bungee pressure hoses together can be useful for a hose's proper operation and durability. However, the composition of these bonding materials, and the positioning, shaping and applying of the bonding structures can vary greatly. For example, the bonding structures (bonding rings 38) used to bond inner elastic tube 34 to outer cover 36 can take the form of bonding strips that follow a spiral path, small segments (short strips), or small dots that are periodically positioned along the hose, or even random patterns of bonding patches or pads (not shown, see bonding rings 38 and 48 if segmented). During manufacturing, these bonding structures and/or adhesives can be first applied to the inner elastic tube, or outer cover, and/or to additional components to form structures such as bonding rings 38, bonding rings 48, bonding pads (not shown), or bonding dots (not shown). The bonding materials can also be applied before, during or after the construction of particular parts of the retractable hose. Further, the bonding structures can also be applied in a non-adhesive state to the inner elastic tube, and/or outer cover and then later, after assembly, be activated to bond these components together to complete the retractable hose. The bonding agents themselves (plus any support structures) can comprise a very diverse set of materials, including, but are not limited to, adhesives, polymer adhesives, UV cured adhesives, thermally cured adhesives, chemically cured adhesives, flexible thermal polymers, soft elastomers, foamed polymers and/or elastomers, etc. Finally, the bonding structures and bonding agents can comprise the actual hose structure itself, in which case, no additional bonding structures or adhesives are needed (e.g., linear elastic tube is thermally and/or mechanically bonded to the outer cover).
Inner Elastic Tube ConstructionIn
In
In
In
Lubricant 37 can be a liquid lubricant, a solid lubricant, and/or a mixture of solid and liquid lubricants. Solid polymer powders or small beads can also be used as a solid lubricant. Some lubricant examples include, but are not limited to oils, paraffin wax, wax mixtures, other soft polymers, Teflon, graphite, solid polymer coatings, elastomer coatings, etc. These lubricants 37 can be coated on the interior of outer cover 36, on the fibers of outer cover 36, and/or on the exterior of inner elastic tubes 24, 34, and 44. Liquid lubricants can be applied from the exterior through outer cover 36 to coat the inside surface of cover 36 because of the porous nature of outer cover. Solid lubricants, like paraffin wax, that can be melted, can also be applied to the exterior of outer cover 36 and allowed to wick through the fabric of cover 36 and/or be forced through cover 36 to its interior surface by a number of methods (e.g., application of a compressed gas).
Of the lubricants tested so far, paraffin candle wax has worked the best. The soft solid nature of paraffin provides a smooth lubrication between the two surfaces, and does not wash away or drain away during use, nor while not in use. Wax also easily wicks into the fabric of cover 36 when heated to its melting point. Wax and other lubricating polymers can also continue to provide protection even after hundreds of hose extension and retraction cycles. Waxes may also be combined with other ingredients or additives to make the wax have various other properties. By adding additional ingredients or additives, a wax or soft polymer can be made sticky and/or gooey so that it can shift with the inner elastic tube and/or outer cover, while at the same time help hold the inner hose in a particular position when the hose is retracted. These sticky and/or gooey polymers can operate as a weak adhesive, providing weak bonding between the elastic tube and outer cover to maintain their relative position during operation. These sticky and gooey polymers can be tailored to slide easily when a small constant force is applied (acting like a thick lubricant) while at the same time resisting strong fast forces to act like an adhesive. Other additives might be used to increase the melting temperature (warmer climates) of the wax or soft polymer, and in other situations be used to reduce the melting temperature (colder climates). Other lubricating solid polymers can comprise polymers that can be bonded to the fibers of outer cover 36 and also make a low friction contact interface with the outer surface of the elastic tubes (i.e., elastic tubes 24, 34, and 44). The lubricant may also comprise a solid lubricant that is coated on the yarn or fibers that make up outer cover 36 before outer cover 36 is woven or braided.
Pleated covers 36 and 76 can be manufactured by first braiding a round braid tube with a circular braiding machine, or other similar machine, then pleating the braided tube with repeating annular pleats and the setting the shown pleated shapes by heat setting, coating with polymers, and/or using other shape holding methods. Once, pleated covers 36 and 76 have a set shape, as shown in
The manufacturing of pleated outer cover 76 seen in
In tests, a very-high temperature heat gun, produced sufficiently hot air, at greater than 1400 degrees Fahrenheit, and radiant heat to produce melted portions 77, on a pleated cover similar to cover 36, that were nearly indistinguishable from melted portions 77 produced by a propane flame. In some designs quickly heating the exterior of cover 36 is important to properly melting of portions 77 without heating and shrinking the valley portions of the cover. Slower heating can cause excessive heating of underlying portions of pleated cover 36 which can tend to cause yarns 36a-b (and cover 36) to shrink significantly and can also make the resulting pleated braid stiff. Thus, heating of portions 77 can be done quickly to prevent shrinkage of fibers 36a-b. Heated air, and burned gasses, cool quickly as they pass between the small closely-packed fibers of cover 36, but if heat is applied for more than about one-half a second, the heat begins to penetrate deeper into cover 36 and starts to cause the interior portions of the fibers to begin to shrink. When this interior shrinkage happens there is nothing to support the outer ridges and the entire cover 36 tends to shrink in diameter. This shrinkage can cause problems if the shrinkage of cover 36 was not taken into account for the final product. Ideally, only the outer ridge is heated sufficiently for the fibers to shrink and/or melt so that the underlying fibers can support the outer ridge and help resist the shrinkage of fibers there. For pleated braid about 0.80 inches in outside diameter, the dwell time for the heated air or gasses should kept below one second to prevent significant shrinkage. Ideally for most nylons and polyesters heating times under one-half second can be used to keep shrinkage minimal. However, temperatures should be high enough to melt the outer ridge and form melted portions 77 during this one-half second or less of heat. This can require relatively high temperatures above about 1500 degrees Fahrenheit. Thus, in many cases the heating of melted portions 77 should be done very quickly before hot gasses, flame, or radiant heat have time to penetrate deeper into braided cover 36 and cause excessive shrinkage.
In
In
Before we go further in the discussion of bungee hoses 30, 40 and 50 please review the section marked “Definition of Terms” in this document for the definition of a few special terms used in describing bungee hoses. In
In
In
In
In FIGS. 4A-B 4A-C, bungee cords 60 and, 63 and 65 can operate in substantially the same way as standard bungee cords, with hook ends 62 allowing them to attach to various places on vehicles to tie down items. The bungee cord itself, comprising pleated cover 36 and an elastic core (i.e., elastic tube 34 and, elastic cord 64 and a plurality of elastic cords 67) allow it to stretch to hold these items in place. Unlike typical bungee cords, the disclosed bungee cord can stretch to over six times its original length to wrap and hold objects that need securing.
In
In
The use of a radially expandable and longitudinally stretchable outer cover with an inner elastic tube significantly changes the dynamics of a retractable hose (bungee hose) and its operational characteristics. An outer cover such as disclosed herein can be implemented to facilitate stretching longitudinally and radially by orienting all the yarns that comprise the outer cover at an acute angle with respect to the longitudinal axis of the bungee hose (yarns oriented neither longitudinal nor tangential).
Although the above description contains many concrete examples, these should not be viewed as limiting the scope of the protection provided by this or any related document. Instead, the above description should be considered illustrative of some of the presently preferred approaches to implementing aspects of the inventor's technology. For example, many alternate solid and liquid lubricants can be used, and, in implementations where an outer cover is bonded to an inner elastic tube, many different ways of bonding can be used to achieve specific characteristics for a particular bungee hose. The choice of material for the inner elastic tube and the outer cover is very diverse and many natural and synthetic polymers can be used. Also, many additional combinations of outer cover, lubricants, inner elastic tube, and bonding methods are possible. Finally, while a hollow circular braided tube is the presently preferred structure for the outer cover of the bungee hose, many other knits, braid styles, and weaves can be substituted that provide a regular repeating pleated pattern and allows the hose to retract radially when extended longitudinally and expands radially when longitudinally retracted.
Thus, the scope of this invention should not be limited to the above examples but should be determined from the following claims.
Claims
1. A tube comprising a plurality of left-handed and right-handed fibers braided to form a channel inside the tube and adapted to longitudinally extend from a compressed length to an extended length
- in response to a longitudinal extension force, wherein:
- a) the tube is adapted to, when contracting from its extended length to its compressed length, compress into a plurality of annular pleats, each annular pleat comprising an annular ridge and an annular valley and having an inner diameter which is greater at the annular ridge than at the annular valley; and
- b) for each annular pleat, the annular ridge from that annular pleat and the annular valley from that annular pleat are both centered around a longitudinal axis of the channel inside the tube;
- wherein the tube is adapted to compress compresses into the plurality of annular pleats based on as a result of the plurality of left-handed and right-handed fibers being heat set into a configuration comprising the plurality of annular pleats; and
- wherein each annular ridge from the plurality of annular pleats comprises a plurality of areas melted in the pleated configuration.
2. The tube of claim 1, wherein the plurality left-handed and right-handed fibers define a first pitch angle between about 5 to 20 degrees when the tube is at the compressed length.
3. The tube of claim 2, wherein the plurality left-handed and right-handed fibers define a second pitch angle of about 30 degrees when the tube is at the extended length.
4. The tube of claim 1, wherein the extended length is at least four times the compressed length.
5. The tube of claim 1, wherein the tube comprises a middle cover disposed in the channel inside the tube.
6. The tube of claim 1, wherein the tube is adapted to compress further compresses into the plurality of annular pleats based on, for each annular pleat from the plurality of annular pleats, as a result of a polymer material being bonded to the annular ridge of that annular pleat.
7. The tube of claim 1, wherein the fibers from the plurality of left-handed fibers and the plurality of right-handed fibers are yarns.
8. A tube comprising a braided fabric comprising a plurality of right and left handed fibers formed into a circular braid defining an interior channel, wherein the braided fabric is adapted to:
- a) longitudinally extend from a compressed length to an extended length in response to a longitudinal extension force;
- b) compress from the extended length to the compressed length in response to a longitudinal compression force; and
- c) form a plurality of repeating annular pleats when at the compressed length;
- wherein the braided fabric is adapted to form forms the plurality of repeating annular pleats based on as a result of being heat set into a configuration comprising the plurality of annular pleats; and
- wherein each pleat from the plurality of repeating annular pleats comprises an annular ridge, and wherein the fibers comprised by the braided tube are melted at the annular ridges from the plurality of repeating annular pleats.
9. The tube of claim 8, wherein the braided fabric is adapted to form further forms the plurality of repeating annular pleats based on as a results of a polymer material bonded to the braided fabric.
10. The braided tube of claim 9, wherein:
- a) each annular pleat from the plurality of repeating annular pleats comprises an annular ridge; and
- b) the polymer material is bonded to the annular ridges from the plurality of annular pleats.
11. A tube comprising:
- a) a tube shaped cover comprising a plurality of left-handed and right-handed fibers braided to form a channel inside the tube shaped cover and adapted to longitudinally extend from a compressed length to an extended length in response to a longitudinal extension force;
- b) a pleat forming means for forming a plurality of annular pleats along a length of the tube shaped outer cover when it contracts from the extended length to the compressed length, wherein: i) each annular pleat from the plurality of annular pleats comprises an annular ridge and an annular valley and has an inner diameter which is greater at its annular ridge than at its annular valley; and ii) for each annular pleat, the annular ridge from that annular pleat and the annular valley from that annular pleat are both centered around a longitudinal axis of the channel inside the tube shaped cover;
- wherein the pleat forming means is the plurality of left-handed and right-handed fibers, the plurality of left-handed and right-handed fibers having been heat set into a configuration comprising the plurality of annular pleats; and
- wherein the plurality of left-handed and the plurality of right-handed fibers comprise melted portions.
12. The tube of claim 11, wherein the pleat forming means comprises a polymer material bonded to the plurality of annular pleats.
13. The tube of claim 12, wherein the polymer material comprises a polymer material bonded to the annular ridges from the plurality of annular pleats.
14. The tube of claim 7, wherein the plurality of areas melted in the pleated configuration are melted sufficiently to make the yarns resistant to sliding past one another.
15. The tube of claim 7, wherein:
- a) the yarns comprise individual yarns, each of the individual yarns comprising a plurality of filaments; and
- b) the yarns in the plurality of areas melted in the pleated configuration are partially bonded, with the bonding primarily being between filaments within individual yarns.
16. A tube comprising a plurality of left-handed and right-handed fibers braided to form a channel inside the tube and adapted to longitudinally extend from a compressed length to an extended length
- in response to a longitudinal extension force, wherein:
- a) the tube is adapted to, when contracting from its extended length to its compressed length, compress into a plurality of annular pleats, each annular pleat comprising an annular ridge and an annular valley and having an inner diameter which is greater at the annular ridge than at the annular valley; and
- b) for each annular pleat, the annular ridge from that annular pleat and the annular valley from that annular pleat are both centered around a longitudinal axis of the channel inside the tube;
- wherein the tube is adapted to compress compresses into the plurality of annular pleats based on, for each annular pleat from the plurality of annular pleats, as a result of a polymer material being bonded to the annular ridge of that each annular pleat.
17. A tube comprising a braided fabric comprising a plurality of right and left handed fibers formed into a circular braid defining an interior channel, wherein the braided fabric is adapted to:
- a) longitudinally extend from a compressed length to an extended length in response to a longitudinal extension force;
- b) compress from the extended length to the compressed length in response to a longitudinal compression force; and
- c) form a plurality of repeating annular pleats when at the compressed length;
- wherein the braided fabric is adapted to form forms the plurality of repeating annular pleats based on as a result of a polymer material bonded to the braided fabric.
18. The braided tube of claim 17, wherein:
- a) each annular pleat from the plurality of repeating annular pleats comprises an annular ridge; and
- b) the polymer material is bonded to the annular ridges from the plurality of annular pleats.
19. A tube comprising:
- a) a tube shaped cover comprising a plurality of left-handed and right-handed fibers braided to form a channel inside the tube shaped cover and adapted to longitudinally extend from a compressed length to an extended length in response to a longitudinal extension force;
- b) a pleat forming means for forming a plurality of annular pleats along a length of the tube shaped outer cover when it contracts from the extended length to the compressed length, wherein: i) each annular pleat from the plurality of annular pleats comprises an annular ridge and an annular valley and has an inner diameter which is greater at its annular ridge than at its annular valley; and ii) for each annular pleat, the annular ridge from that annular pleat and the annular valley from that annular pleat are both centered around a longitudinal axis of the channel inside the tube shaped cover;
- wherein the pleat forming means comprises a polymer material bonded to the plurality of annular pleats.
20. The tube of claim 19, wherein the polymer material comprises a polymer material bonded to the annular ridges from the plurality of annular pleats.
21. A bungee cord adapted to longitudinally extend from a retracted length to a stretched length in response to a longitudinal extension force, the bungee cord comprising:
- a tube-shaped outer cover made of a fabric that folds when the bungee cord transitions to the retracted length, wherein the fabric of the tube-shaped outer cover is braided and comprises a plurality of left-handed and right-handed fibers braided to form a channel inside the outer cover, and wherein the outer cover is adapted to longitudinally extend from a compressed length to an extended length in response to the longitudinal extension force;
- an inner elastic core positioned within the outer cover;
- a first hook end coupled to the outer cover and the inner elastic core at a first end of the bungee cord; and
- a second hook end coupled to the outer cover and the inner elastic core at a second end of the bungee cord,
- wherein the outer cover at the compressed length defines a plurality of annular pleats and each annular pleat provides an annular ridge and an annular valley, and
- wherein the plurality of left-handed and right-handed fibers are heat set into a configuration that forms the plurality of annular pleats.
22. The bungee cord of claim 21, wherein the stretched length is at least three times the retracted length.
23. The bungee cord of claim 21, wherein the stretched length is at least four times the retracted length.
24. The bungee cord of claim 21, wherein the stretched length is at least six times the retracted length.
25. The bungee cord of claim 21, wherein the inner elastic core comprises an elastic hose defining an interior channel.
26. The bungee cord of claim 21, wherein the inner elastic core comprises a solid elastic cord.
27. The bungee cord of claim 21, wherein the inner elastic core comprises a plurality of elastic cords.
28. The bungee cord of claim 21, wherein the fabric of the tube-shaped outer cover is woven and adapted to longitudinally extend from a compressed length to an extended length in response to the longitudinal extension force.
29. The bungee cord of claim 28, wherein the tube-shaped outer cover crumples when transitioned to the compressed length.
30. The bungee cord of claim 21, wherein the plurality of annular pleats are further defined by bonding a polymer to the left-handed and right-handed fibers at each annular ridge.
31. The bungee cord of claim 21, wherein the plurality left-handed and right-handed fibers define a first pitch angle between about 5 to 20 degrees when the outer cover is at the compressed length.
32. The bungee cord of claim 21, further comprising a middle cover interposing the outer cover and the inner elastic core.
33. The bungee cord of claim 21, further comprising a lubricant interposing the outer cover and the inner elastic core.
34. A bungee cord adapted to longitudinally extend from a retracted length to a stretched length in response to a longitudinal extension force, the bungee cord comprising:
- a tube-shaped outer cover made of a woven fabric that folds and crumples to form a plurality of annular pleats when the bungee cord transitions to the retracted length;
- an inner elastic core positioned within the outer cover;
- a first hook end coupled to the outer cover and the inner elastic core at a first end of the bungee cord; and
- a second hook end coupled to the outer cover and the inner elastic core at a second end of the bungee cord,
- wherein the plurality of annular pleats are heat set into a configuration that forms the plurality of annular pleats.
35. A bungee cord adapted to longitudinally extend from a retracted length to a stretched length in response to a longitudinal extension force, the bungee cord comprising:
- a tube-shaped outer cover made of a braided fabric comprising a plurality of left-handed and right-handed fibers braided to form an inner channel, and wherein the outer cover is adapted to longitudinally extend from a compressed length to an extended length in response to the longitudinal extension force;
- an inner elastic core positioned within the inner channel;
- a first hook end coupled to the outer cover and the inner elastic core at a first end of the bungee cord; and
- a second hook end coupled to the outer cover and the inner elastic core at a second end of the bungee cord,
- wherein the outer cover at the compressed length defines a plurality of annular pleats and each annular pleat provides an annular ridge and an annular valley, and
- wherein the plurality of annular pleats are defined by bonding a polymer to the left-handed and right-handed fibers at each annular ridge.
36. The bungee cord of claim 35, wherein the plurality of left-handed and right-handed fibers are further heat set into a configuration that forms the plurality of annular pleats.
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Type: Grant
Filed: Jan 28, 2019
Date of Patent: Apr 7, 2020
Assignee: Ragner Technology Corporation (Newberry, FL)
Inventor: Gary Dean Ragner (Gainesville, FL)
Primary Examiner: Russell D Stormer
Application Number: 16/259,233
International Classification: D02G 3/22 (20060101); D02G 3/32 (20060101); F16L 57/06 (20060101); B32B 7/12 (20060101); F16L 11/12 (20060101); B32B 1/08 (20060101); B32B 5/02 (20060101);