Abstract
A self-wrapping sleeve and method of construction thereof is provided. The sleeve includes an elongate multilayered tubular wall having opposite edges extending along a longitudinal axis of the sleeve between opposite ends of the sleeve. The opposite edges are biased into a self-wrapping configuration about the longitudinal axis to define an internal cavity bounded by the tubular wall. The tubular wall includes a non-woven layer of intertwined fibers and a textile layer of interlaced filaments, wherein the non-woven layer is fixed to the textile layer via needled fibers of the non-woven layer being entangled with filaments of the textile layer.
Claims
1. A self-wrapping sleeve for routing and protecting elongate members, comprising: an elongate wall having opposite edges extending lengthwise along a longitudinal axis between opposite ends, said opposite edges being biased into a self-wrapped configuration about the longitudinal axis to define an internal cavity, said opposite edges being extendable away from one another under an externally applied force to expose the internal cavity for insertion or removal of the elongate members and return to their self-wrapped configuration upon removal of the externally applied force, said wall including a non-woven layer of intertwined fibers and a textile layer of interlaced filaments, wherein the non-woven layer is fixed to the textile layer via fibers of the non-woven layer being entangled with filaments of the textile layer.
2. The self-wrapping sleeve of claim 1, wherein said wall has a plurality of circumferentially extending first band portions and a plurality circumferentially extending second band portions alternating with one another along the length of the sleeve, said first band portions being needle punched with fibers of said nonwoven layer being entangled with said filaments of said textile layer and said second band portions not being needled punched such that said fibers of said non-woven layer are not entangled said filaments of said textile layer.
3. The self-wrapping sleeve of claim 1, wherein at least one of said non-woven layer and said textile layer is heat-set to bias said opposite edges into the self-wrapped configuration about the longitudinal axis.
4. The self-wrapping sleeve of claim 3, wherein said non-woven layer is heat-set to bias said opposite edges into the self-wrapped configuration about the longitudinal axis.
5. The self-wrapping sleeve of claim 4, wherein textile layer is not heat-set.
6. The self-wrapping sleeve of claim 3, wherein said textile layer is heat-set to bias said opposite edges into a self-wrapped configuration about the longitudinal axis.
7. The self-wrapping sleeve of claim 6, wherein said non-woven layer is not heat-set.
8. The self-wrapping sleeve of claim 3, wherein said non-woven layer and said textile layer are each heat-set to bias said opposite edges into the self-wrapped configuration about the longitudinal axis.
9. The self-wrapping sleeve of claim 1, wherein said wall further includes a metal foil layer sandwiched between said non-woven layer and said textile layer, wherein said fibers of said non-woven layer entangled with said textile layer pass through said metal foil layer.
10. The self-wrapping sleeve of claim 9, wherein said nonwoven layer, said textile layer and said metal foil layer are fixed to one another solely via said fibers of said non-woven layer being entangled with said filaments of said textile layer.
11. A method of construction a self-wrapping sleeve, comprising: providing an elongate non-woven layer; providing a textile layer; laying the non-woven layer and the textile layer in overlying relation with one another; needle punching the non-woven layer to entangle fibers of the non-woven layer with filaments of the textile layer to form a multilayered wall having opposite edges of the non-woven layer and the textile layer extending lengthwise between opposite ends; and heat-setting the wall into a tubular self-wrapped configuration with the opposite edges being biased into overlapping relation with one another to define an internal cavity.
12. The method of claim 11, further including needling a plurality of circumferentially extending first band portions in the nonwoven layer causing the fibers of the nonwoven layer to become entangled with filaments of the textile layer and forming a plurality circumferentially extending non-needled second band portions extending between and alternating with the first band portions, wherein the fibers of the nonwoven layer within the second band portions are free from being entangled with filaments of the textile layer.
13. The method of claim 12, further including forming the wall having a convolute contour via the first band portions forming valleys and the second band portions forming peaks.
14. The method of claim 11, further including arranging the textile layer to form an inner surface of the sleeve and arranging the non-woven layer to form an outer surface of the sleeve.
15. The method of claim 11, further including sandwiching a metal foil layer between the non-woven layer and the textile layer and penetrating the metal foil layer with the fibers of the non-woven layer that are entangled with the textile layer.
16. The method of claim 11, further including fixing the nonwoven layer and the textile layer to one another solely via the fibers of the non-woven layer being entangled with the filaments of the textile layer.
17. The method of claim 11, further including imparting a heat-set in at least one of the non-woven layer and the textile layer to bias the opposite edges of the wall into overlapping relation with one another without imparting a heat-set in the other of the non-woven layer and the textile layer.
18. The method of claim 17, further including imparting a heat-set in the non-woven layer.
19. The method of claim 17, further including imparting a heat-set in the textile layer.
20. The method of claim 11, further including imparting a heat-set in both the non-woven layer and the textile layer to bias the opposite edges of the wall into overlapping relation with one another without heat-setting the other of the non-woven layer and the textile layer.
Description
BRIEF DESCRIPTION OF THE DRAWINGS
[0025] These and other aspects, features and advantages of the disclosure will become readily apparent to those skilled in the art in view of the following detailed description of the presently preferred embodiments and best mode, appended claims, and accompanying drawings, in which:
[0026] FIG. 1 is a perspective view of a sleeve constructed in accordance with an aspect of the disclosure;
[0027] FIG. 2 is a cross-sectional view taken generally along the line 2-2 of FIG. 1;
[0028] FIG. 2A is a view similar to FIG. 2 of a sleeve constructed in accordance with another aspect of the disclosure;
[0029] FIG. 3 is a side view of a sleeve constructed in accordance with an aspect of the disclosure shown be bent into a non-kinked U-shape;
[0030] FIG. 4 is a schematic illustration of a process used to construct a sleeve in accordance with one aspect of the disclosure; and
[0031] FIG. 4A is a view similar to FIG. 4 of a process used to construct a sleeve in accordance with another aspect of the disclosure.
DETAILED DESCRIPTION OF PRESENTLY PREFERRED EMBODIMENTS
[0032] Referring in more detail to the drawings, FIG. 1 illustrates a sleeve 10 constructed in accordance with one aspect of the disclosure that is self-wrapping as a result of being heat-set in construction. The sleeve 10 has elongate multilayered wall 12 having opposite lengthwise extending edges 14, 16 extending generally parallel with a longitudinal axis 18 of the sleeve 10 between opposite open ends 20, 22 of the sleeve. The opposite edges 14, 16 are biased into self-wrapped, overlapping relation with one another to define a tubular internal cavity 24. The opposite edges 14, 16 are extendable away from one another under an externally applied force, when desired, to expose the internal cavity 24 for insertion or removal of an elongate member(s) 26 and automatically return to their self-wrapped configuration upon removal of the externally applied force. The wall includes an outer non-woven layer 28 of intertwined fibers 30 and an inner textile layer 32 of interlaced filaments 34 (the filaments 34 can be monofilaments and/or multifilaments of any desired material, including heat-settable and/or non-heat-settable materials; and can be interlaced via weaving, braiding, knitting using any desired pattern, e.g. plain weave, if woven, or otherwise), wherein the non-woven layer 28 is fixed to the textile layer 32 via fibers 30 of the non-woven layer 28 being entangled with filaments 34 of the textile layer 32 via a needle punch process, such as illustrated in FIGS. 4 and 4A. Accordingly, the non-woven layer 28 and the textile layer 32 can be fixed to one another solely via the needling process without the need for costly secondary fixation mechanisms and processes, such as messy, costly adhesives or other types of fastener devices.
[0033] In accordance with one aspect of the disclosure, as shown in FIG. 4, the nonwoven layer 28 and textile layer 32 are initially constructed as flat layers and are fed into overlying relation with one another, with the nonwoven layer 28 facing a plurality of needles 36 of a needle punch machine 38. The needles 36 are arranged in the desired number and pattern to effect the desired needling pattern (width and density) in the nonwoven layer 28. The needle punch machine 38 is cycled to penetrate the nonwoven layer 28 and the underlying textile layer 32 with the needles 36, whereupon the needles 36 carry a plurality of fibers 30 of the nonwoven layer 28 into entangled relation with the filaments 34 of the textile layer 32. Accordingly, the nonwoven layer 28 and the textile layer 32 are fixed to one another against separation without the need for supplemental bonding and fixation mechanisms, such as an adhesive, though it is contemplated herein that such supplemental bonding mechanisms could be used, if desired. The needling is performed to create first and second circumferentially extending bands 40, 42 that alternate with one another along a length of the layers 28, 32. The first bands 40 are formed having compressed, densified needled fibers 30 and the second bands 42 are formed retaining non-compressed, non-densified and non-needled fibers 30. One skilled in the art will understand that the first and second bands 40, 42 can be formed having any desired width (width is intended to mean the distance extending lengthwise along the axis 18) as desired to impart the desired flex, crush strength and impact resistance (crash protection) to the finish sleeve 10. Upon the flat nonwoven and textile layers 28, 32 being needled and laminated (fixed) to one another to form the material of the multilayered wall 12, the wall 12, which takes on a convolute contour with valleys V of needled material forming the first bands 40, which provide enhanced hoop strength, and peaks P of non-needled material forming the second bands 42, which provide enhanced flexibility, can be subsequently wrapped and heat-formed (heat-set) into a biased, self-wrapping tubular configuration to form the tubular sleeve 10. With at least one or both of the layers 28, 32 of the wall 12 being heat-set to take on its curled configuration, a split, also referred to as seam 44, extends along the length of the sleeve 10, wherein the wall 12 provides the circumferentially enclosed internal cavity 24 when in its relaxed, self-wrapped configuration. It is to be understood that only one of the layers 28, 32 may include heat-settable fibers and filaments, respectively, while the other layer 28, 32 may be void, and thus free of more costly heat-settable fibers and filaments, respectively. Contrarily, where increased curl force is desired to enhance the self-wrapping capability of the wall 12, both layers 28, 32 may include heat-settable fibers and filaments, respectively. With the wall 12 being curled, the internal cavity 24 is generally tubular and readily accessible along the entirety of the central longitudinal axis 18 of the sleeve 10 so that the elongate member(s) 26, such as wires or a wire harness, for example, can be readily disposed into the internal cavity 24, and conversely, removed from the internal cavity 24, such as during service via forcing lengthwise extending free edges 14, 16 of the sleeve 10 away from one another against the heat-set bias imparted within at least a portion of the wall 12 to open the seam 44 against the self-closing, heat-formed biasing force by an amount sufficient to introduce or remove the elongated members 26 through the opened split seam 44.
[0034] In the embodiment of FIG. 2, the non-woven layer 28 and the textile layer 32 form the entirety of the multilayered sleeve 10, unless a further layer is desired, as discussed below. Accordingly, the construction of the sleeve 10 eliminates the requirement for additional layers of material to provide protection or other functions, e.g. curling. The material of the nonwoven layer 28 can be provided, at least in part, of any type and combination of heat-formable fibrous materials. The material may be selected as an abrasion resistant, flexible, resilient, acoustic dampening polymeric material, such as polyester, for example. The exemplary selected fibrous material selected to be incorporated into the nonwoven layer 28 may be, without limitation, poly(ethylene terephthalate) (PET). The material may include a base polymeric material (such as PET, by way of example and without limitation) combined with any number and type of polymeric or non-polymeric filler materials (e.g., chopped waste fabric, shop rags, Asian cardboard, etc.). The sleeve 10 is well suited to protect the elongate members 26 within the internal cavity 24 against abrasion, vibration, thermal conditions and damage from impact largely via the nonwoven layer 28, while also inhibiting snagging with the elongate members 26, rattling and squeaking, or otherwise producing unwanted harshness and/or noise largely via the textile layer 32. In addition, as a result of the nonwoven layer 28 being needled to the textile layer 32 in the first bands 40 and not needled in the second bands 42, the sleeve 10 can be routed about meandering paths and sharp corners, as illustrated in FIG. 3, without causing the seam 44 to open and without causing the wall 12 to kink. The first bands 40 of needled fibers 30 are densified and impart enhanced crush (hoop) strength to the wall, while the second bands 42 of non-needled fibers 30 are not densified via needling, and thus, impart flexibility to the sleeve 10, thereby providing a synergy of enhanced hoop strength and enhanced flexibility that allows the sleeve 10 to function as intended, without jeopardizing the ability of the wall 12 to remain in its fully wrapped state about the elongate member(s) 26. Further yet, the materials and processes used to construct the sleeve 10 are economical in manufacture and in use.
[0035] As shown in FIGS. 2A and 4A, a sleeve 110 constructed in accordance with another aspect of the disclosure provided, wherein the same reference numerals as used above, offset by a factor of 100, are used to identify like features. The sleeve 110 has a wall 112 that includes a nonwoven layer 128, as textile layer 132, and a metal foil layer 46, such as a metal foil layer of aluminum or other suitable metal material, sandwiched between the nonwoven layer 128 and the textile layer 132. The wall 112 is constructed similarly as discussed above for the wall 12; however, prior to performing the needling process, as discussed above, the foil layer 46 is sandwiched between the outer nonwoven layer 128 and the inner textile layer 132. With the respective layers 128, 46, 132 overlying one another, preferably such that their respective outer peripheries are in flush alignment with one another, the needling process is performed, as discussed above, to form the axially alternating first and second bands 140, 142. As best shown in FIG. 4A, the needled fibers 130 of the nonwoven layer 128 penetrate through the metal foil layer 46 to entangle with the filaments 134 of the textile layer 132. Accordingly, the respective layers 128, 46, 132 are fixed to one another without need for further fixing mechanisms, as discussed above, though, additional fixing mechanisms could be used, if desired. Of course, cost is reduced if further fixing mechanisms are avoided. Then, upon forming the fixed lamination of the nonwoven layer 128, metal foil layer 46 and textile layer 132, the wall 112 can be heat-formed to permanently bias opposite edges 114, 116 of the wall 112 into overlapping relation with one another to form a tubular sleeve 112. The presence of the metal foil layer 46 enhances protection against thermal effects as well as against electromagnet interference, as will be appreciated by a skilled artisan in view of the disclosure herein.
[0036] Obviously, many modifications and variations of the present invention are possible in light of the above teachings. It is contemplated that all features of all claims and of all embodiments can be combined with each other, so long as such combinations would not contradict one another. It is, therefore, to be understood that within the scope of the appended claims, the invention may be practiced otherwise than as specifically described.
