Faired article

Abstract

A rope or cable having a series of loops and/or fairings extending laterally in spaced relation along its length is disclosed. In one embodiment, the fairings are composed of a series of strands which splay outwardly from a jacket applied onto a core. In one species of this embodiment, a layer of resilient material surrounds the core, and the jacket is braided over base portions of the fairings which overlie the resilient layer. In another species of this embodiment, the core is provided by an elongated cable, and the jacket is provided by a helically-wrapped tape which anchors the strands to the cable. In another embodiment, a central core is omitted and a braided jacket surrounds base portions of the strands to secure the fairings.Methods and apparatus for producing the faired articles are also disclosed.

Description

The present invention relates to elongated structures such as ropes or cables having fairings or streamers extending laterally therefrom and to a method and apparatus for producing such structures. More particularly, the present invention relates to so-called faired ropes and methods and apparatus for their manufacture.

In conducting oceanographic studies, and undersea surveillance, hydrophones are customarily utilized to study undersea acoustics. Usually, a series of hydrophones are mounted at spaced intervals along the length of a cable which extends above the ocean floor between buoys which are anchored to the sea bed by guy cables. The hydrophones mounted in this manner are able to pick up sound waves such as waves generated by undersea oil and mineral exploration activities, submarines, aquatic life, etc.

It has been discovered that the hydrophone cable, as well as the guy cables, tend to vibrate when subjected to ocean currents. The strumming noise or sound produced by the vibrating cables are detected by the hydrophones, and the detected noise is known to interfere with the acoustic studies. In addition, it has been discovered that the strumming attracts fish, and fish have been known to attack the cable. Since it is desirable for such studies to be conducted with a minimum of background noise, it should be apparent that a cable structure which does not have a proclivity to vibrate in response to ocean currents is highly desirable.

It is known that the vibrations and hence the sound produced by vibrating undersea cables can be attenuated by providing fairings or streamers at spaced intervals along the length of the cable. The fairings are normally fabricated of a flexible material which extends laterally of the cable so that each fairing is capable of disposing itself on the downstream side of the cable to break-up vorticies as the sea water flows across the cable. Thus the cause of cable strumming is eliminated or reduced and cable drag also tends to be reduced.

One type of faired cable which has been used comprises a series of flat relatively-narrow tapes or ribbons secured to the cable at spaced intervals along its length. Although this type of faired cable may function satisfactorily in certain situations, it has limitations. For instance, the tapes are highly flexible. As a result, they can wrap completely around the cable in response to changes in the direction of ocean currents. Needless to say, such wrapping is undesirable since it prevents the fairings from functioning properly. The tapes also have a proclivity for tearing and becoming disconnected from the cable during deployment and recovery. Furthermore, such a faired cable is expensive to manufacture.

There are applications where a strong rope capable of providing fastening points at spaced intervals along its length is desirable. For example, such a rope would find particular utility as a means for connecting a fishing net to a net line. Needless to say, such a rope which is capable of being mass produced economically is highly desirable.

With the foregoing in mind, it is a primary object of the present invention to provide a novel faired rope or cable which is particularly suited for use in oceanographic applications where a minimum of cable-generated noise is desirable.

It is another object of the present invention to provide an improved method and apparatus for manufacturing a faired rope or for securing fairings to an existing steel cable in a continuous and economical manner.

Another object of the present invention is to provide a rope having unique fairings which tend to resist wrapping about the body of the rope in response to changes in direction of fluid flowing across the rope.

It is yet another object of the present invention to provide a faired rope ro cable structure which has a minimum of drag when subjected to flowing fluids.

A still further object of the present invention is to provide an improved structure for anchoring fairings to a rope or cable in such a manner as to prevent the fairings from separating from the rope.

As another object, the present invention provides a unique method and apparatus for producing a rope having a series of loops or hangers spaced apart along its length to afford attachment of articles to the rope at spaced intervals.

Yet another object of the present invention is to provide a method and apparatus for producing an elongated article which has a series of fairings spaced apart and secured along its length by a braided jacket but which does not have a separate core element.

Another object of the present invention is to produce a novel faired cord having a relatively small diameter which affords storage in a compact space.

More specifically, the faired rope of the present invention comprises a core having a plurality of yarns surrounded by a layer of resilient material and a jacket braided around the core. Each fairing is provided by a yarn having a base portion anchored between the core and the jacket and leg portions extending laterally away from the core through the jacket. The base portions of the fairing yarns are disposed lengthwise of the rope along at least one side thereof, and the leg portions of axially-adjacent fairing yarns compose each fairing. The braided jacket tightly surrounds the legs of the fairing yarns at the juncture with their bases, and the fairing yarns are preferably of a resilient material. Thus, the fairings are capable of resilient deflection relative to the rope, and they tend to resist wrapping about the rope in response to changes in undersea currents.

In manufacturing the faired rope of the present invention or in applying fairings to a pre-existing cable, the core thereof is advanced lengthwise through a braider which applies the protective jacket around the core, and a length of fairing yarn is laid axially along the core as it advances through the braider to form a base for each fairing. A first length of the fairing yarn extends away from the core and through the eye of a needle which is mounted upstream of the braider for reciprocation in a path parallel to the path of movement of the core. As the core advances and the braid yarns move about the core, the needle is extended, and the first length of the yarn is displaced forwardly through the braid yarns to a limit position where it is gripped by a hook mounted on a frame which overlies the core. The hook engages the yarn, and a second length of yarn is pulled through the eye of the needle as the needle retracts through the braid yarn. The movement of the braid yarns causes the rearwardly-extending length of the fairing yarn to move downwardly against the core to engage the other length of yarn and to form a loop projecting upwardly from the core. Continued operation of the braider causes the jacket to overlay another portion of the fairing yarn which is in contact with the core for forming the base of the next fairing. The fairing loops are severed as the rope advances by a stationary knife mounted on the gripping-hook frame. The axial movement of the core is sensed and converted into a signal which actuates the needle-extension mechanism each time the core moves through a predetermined distance.

The needle and gripping assemblies are designed to cooperate with one another to form each fairing automatically with a minimum of moving parts. For this purpose, the needle is provided with a lateral recess rearwardly of its eye, and a guideway connects the tip of the needle with the lateral recess. The guideway is sized to engage the upper end of the hook which is mounted for resilient deflection relative to the frame of the gripping assembly. Thus, as the needle advances into its forward limit position, the hook engages in the guideway and is deflectd downwardly until it registers with the recess, whereupon it moves upwardly to engage behind the yarn for gripping the same and holding it as the needle retracts. The hook also deflects laterally as the needle retracts to disengage the recess. The movement of the rope is sensed by means engaged with the body of the rope and operable through a variable speed transmission to rotate a cam. The cam actuates a switch connected in an electrical circuit to provide the signal to the needle-actuator. The variable-speed transmission permits the relation between the movement of the rope and the extension of the needle to be varied in order to adjust the spacing between the fairings on the rope.

If desired, the needle nose and hook may be inverted to enable the loops to disengage the hook automatically as the article is being manufactured for producing a rope having a series of loops spaced apart along its length. Also, the faired article may be produced by the above method and apparatus without first providing a separate core element.

These and other objects, features and advantages of the present invention should become apparent from the following description when taken in conjunction with the accompanying drawings in which;

FIG. 1 is a side elevational view of a length of faired rope embodying the present invention, a portion of the protective jacket being removed to expose the construction of the core of the rope;

FIG. 2 is a greatly-enlarged, fragmentary sectional view of the faired rope illustrated in FIG. 1;

FIG. 3 is a greatly-enlarged, cross-sectional view of a filament of a preferred fairing yarn;

FIG. 4 is a view illustrating schematically apparatus for practicing the present invention;

FIG. 5 is a greatly-enlarged, fragmentary view of a portion of the needle and gripping assembly illustrated in FIG. 4, the view illustrating in full-lines the needle in its forward limit position and illustrating in broken lines the needle during retraction from its forward limit position;

FIG. 6 is a side elevational view of the needle and gripping assembly illustrated in FIG. 5;

FIG. 7 is an enlarged end elevational view taken along lines 7--7 of FIG. 6 to illustrate a guideway provided in the front end of the needle;

FIGS. 8-12 are views illustrating schematically the movement of the fairing yarn during operation of the apparatus of the present invention;

FIG. 13 is a fragmentary perspective view illustrating the bunching of braid yarns against the side of the needle and fairing yarn during extension of the needle;

FIG. 14 and 15 are side elevational views of modified embodiments of the present invention;

FIG. 16 is a side elevational view of a short section of a faired rope, such as illustrated in FIG. 4, having a series of loops extending therefrom in spaced relation along its length;

FIG. 17 is a schematic diagram similar to FIG. 12 but illustrating apparatus for producing the rope illustrated in FIG. 16;

FIG. 18 is a side elevational view of a small diameter faired cord embodying the present invention;

FIG. 19 is a sectional view taken along line 19--19 of FIG. 18; and

FIG. 20 is a schematic diagram similar to FIG. 12 but illustrating the faired cord being formed without a separate core element.

Referring now to the drawings, FIG. 1 illustrates a short length of a rope or cable asembly 10 embodying the present invention. As best seen therein, the rope assembly 10 comprises a core 11 composed of a plurality of parallel yarns of man-made fibers such as nylon, polyester, Kevlar, etc. surrounded by a layer of resilient material 13, such as neoprene. The core 11 is protected by a braided jacket 14 which surrounds the core 11. The structure of the rope described thus far is set forth more fully in U.S. Patent application Ser. No. 434,627, filed on Jan. 18, 1974, and entitled "Parallel Yarn Rope and Method of Manufacturing". The application is owned by the Assignee of the present application, and a rope having this construction is sold commercially by Wall Industries, Inc. of Beverly, N.J., under the registered trademark, Uniline.

In accordance with the present invention, the rope 10 is provided with a series of fairings or streamers 15, 15 which extend laterally therefrom at spaced intervals along its length. In the illustrated embodiment, the fairings 15, 15 are disposed in a row extending lengthwise of the core along its upper side. Preferably, the fairings are provided by a flexible member such as a fairing yarn Y having strands or filaments F which are of a non-circular cross-section having circular zones connected by frangible weakened sections, as illustrated in FIG. 3, the weakened sections affording desirable longitudinal separation of the circular zones from one another. The strands are twisted slightly to provide the yarn with sufficient coherency to facilitate manufacturing without causing excessive twist-liveliness, as described hereinafter. The filaments are preferably fabricated of a resilient material such as polypropylene, which is also desirable because it reduces the total weight in the water of the faired rope. A fairing yarn of the preferred cross-section and material is sold under the trade designation, Parapro, by Wall Industries, Inc. of Beverly, New Jersey.

The fairings 15, 15 are firmly secured to the rope 10. For this purpose, each fairing 15 is provided by a relatively short length of a multi-stranded fairing yarn which has a substantially U-shaped configuration with outwardly-extending streamer or leg portions 15a, 15a and a base portion 15b connecting the leg portions. The base portion 15b extends for a short distance lengthwise of the rope 10 along at least one side and is anchored between the jacket 14 and the core 11, as illustrated in FIG. 2. The base portions 15b, 15b are aligned endwise longitudinally of the core 11, and the resilient layer 13 interacts with the base portions 15b of the fairing yarn Y and the tightly-braided jacket 14 to anchor the fairings 15,15 securely to the rope 10.

As best seen in FIG. 1, the leg portions 15a, 15a of the fairing yarn are bunched or grouped together tightly at their juncture with the jacket 14 to form the fairing 15. This bunching, combined with the inherent resiliency of the fairing yarn, cooperates to mount the fairings 15, 15 in cantilever fashion with respect to the body of the rope. As a result, the fairings 15, 15 tend to resist wrapping around the rope in response to changes in direction of the fluid flowing across the rope.

The lengths of the fairings 15, 15 and their axial spacing may vary, depending upon the vibration and sound attenuation desired. By way of example, a rope of the above construction having a diameter of three-quarter inch, and fairings 5 inches in length spaced apart axially approximately one inch, has been tested satisfactorily. The faired rope which was tested had fairings fabricated of the aforementioned Parapro polypropylene fairing yarn of 7500 denier providing a fairing 15 of 15,000 denier. The axial spacing between the fairings was varied from 1 to 8 inches, and it was determined that a significant change in vibration levels occured when the spacing was varied from 1 to 2 inches, although good vibration damping occurred even at the higher spacings. The tests revealed that the faired rope of the present invention has a vibration or noise level approximately 1/40 to 1/100 of the noise level of a rope of similar construction which does not have fairings. The lengths of the fairings (measured from the outside of the rope) should be in a range of about 5-12 times the rope diameter, and the spacing between the fairings should be in a range of about 0.5 to 3 times the rope diameter. Although it may be possible to employ a nylon monofilament yarn satisfactorily, a nylon multifilament yarn should not be used except in those situations where wrapping would not be objectionable.

In manufacturing the faired rope of the present invention, the fairings 15, 15 are produced automatically in a continuous manner as the core 11 advances axially. To this end, the apparatus illustrated in FIG. 4 is provided for manipulating the fairing yarn Y during braiding of the jacket 14 in such a manner as to cause the fairings 15, 15 to be formed downstream of the braider.

As best seen therein, the braider causes braid yarns 14a, 14a to move in a path about the core 11 in a braid zone Z, and the fairing yarn Y is fed into the braid zone Z where it is manipulated by a needle 21 and gripping assembly 25. The needle 21 is reciprocated parallel to the path of movement of the core 11 and through the path of movement of the braid yarns 14a, 14a by a linear-actuator 22 mounted upstream or rearwardly of the braid zone Z. A spreader ring 23 surrounds the core 11 and is secured to the braider upstream of the braid zone Z to engage the braid yarns 14a, 14a as they advance about the core 11. When the needle 21 is in its home position, illustrated in broken lines in FIG. 4, tie braider functions to braid the yarns 14a, 14a about the core 11 as it advances forwardly in the direction of the arrow. When in the home position, a short length of the braid yarn (which forms the base 15b ) is disposed against the upper side of the core 11, and a longer first length Y extends laterally and rearwardly from the core through a guide or eye 20 of the needle 21 and to a supply cone (not shown).

In order to form the loops 15',15', the needle 21 is extended into its forward limit position, illustrated in full lines in FIG. 4, and the fairing yarn Y is gripped by the gripping assembly 25. Thus, when the needle 21 retracts into its home position, another or second length Y" of the fairing yarn is pulled through the eye 20 of the needle 21, and this length Y" extends rearwardly from the gripping assembly 25 and through the path of movement of the braid yarns 14a, 14a. The various positions of the needle 21, gripping assembly 25, and fairing yarn Y are illustrated schematically in FIGS. 8-12. For instance, in FIG. 8, the needle 21 is in its home position, as in FIG. 4. In FIG. 9, the needle 21 is illustrated in its forward limit position with the yarn Y gripped by the hook 32 of the gripping assembly 25. FIG. 10 illustrates the position of the needle 21 immediately after retraction through the braid yarns 14a, 14a with the fairing yarn Y extending through the braid yarns 14a, 14a and toward the hook from a position relatively close to the needle 21. FIG. 11 illustrates the needle 21 adjacent its home position, and FIG. 12 illustrates the needle 21 in its home position. The aforedescribed action of the braid yarns 14a, 14a in displacing both legs Y' and Y" of the fairing yarn Y toward the core 11 is illustrated with particularity in FIGS. 10 and 11.

During the brief period of time while the needle 21 is in its forward limit position, the braid yarns 14a, 14a tend to bunch against the sides of the needle 21 since it is located in the path of movement of the braid yarns. For instance, see FIGS. 5 and 13. However, after the needle 21 disengages the braid yarns 14a, 14a, the braid yarns cooperate with the gripping assembly 25 to cause the lengths Y' and Y" of the fairing yarn Y to be displaced laterally inward against the core 11. Continued braiding of the braid yarns 14a,14a about the portion of the fairing yarn Y engaged with the core 11 causes the base portion 15b of the next fairing 15 to be formed, and continued reciprocation of the needle 21 in cooperation with the gripping assembly 25 and the action of the braider causes the succession of axially-spaced loops 15',15' to be produced.

In order to provide the fairings 15,15 with free ends, the loops 15',15' are severed as the rope assembly 10 advances. For this purpose, a stationary knife 26 having an upwardly and forwardly inclined cutting blade 27 is mounted in a stationary frame 28 a spaced distance above the path of movement of the rope 10. Thus, as the rope 10 advances, the loops 15',15' engage the blade 27 and are severed, thereby forming double-legged fairings, such as indicated in 15" in FIG. 4. Thereafter, the rope assembly 10 enters a heating chamber 30 which cures the rope 10, as described in the referenced patent application. When the rope assembly 10 exits the dryer 30, after passing over rollers therein, the fairings have the tufted appearance illustrated in the lower right-hand corner of FIG. 4.

The present invention provides novel apparatus for use in practicing the method steps described thus far. To this end, the needle 21 is designed to cooperate with the gripping assembly 25 in a manner which causes the fairing yarn Y to be gripped automatically when the needle 21 reaches its forward limit position. In the illustrated embodiment, the gripping means 25 includes a hook 32 fabricated of resilient material such as spring steel, and the hook is mounted at its rear end by fasteners 33 and 34 connected to one side of the stationary frame 28. The hook 32 has an upper end 32a which is forwardly-turned and normally disposed in the path of movement of the needle 21 when the hook 32 is in its home position illustrated in FIG. 4. Thus, the hook 32 is engaged by the front end 21a of the needle 21 as the needle extends. The hook 32 is biased into this position by virtue of its mounting to the frame 28 and its inherent resiliency.

In order to grip the yarn Y, the needle 21 is provided with a lateral recess 21b located rearwardly of its eye 20 and a downwardly-open, longitudinally-extending guideway 21c extending from its front end 21a to the recess 21b, as illustrated in FIGS. 6 and 7. As best seen in FIG. 6, the front end or tip 21a of the needle 21 is upturned, and the guideway 21c is sized to receive the upper end 32a of the hook 32. Thus, when the needle 21 engages the upper end 32a of the hook 32, it displaces the hook 32 downwardly against its bias, into the position illustrated in broken lines in FIG. 6. After the needle 21 reaches its forward limit position, illustrated in full lines in FIG. 4, the upper end 32a of the hook 32 enters the lateral recess 21b in the needle 21 and springs upwardly by its inherent resiliency to cause its upper end 32a to be disposed above the level of the needle-eye 20. Hence, as the needle 21 retracts, the upper end 32a of the hook 32 engages the fairing yarn Y and holds the same adjacent the frame 28 while the needle 21 retracts to its home position and pulls fairing yarn Y through its eye 20. It is noted that the hook 32 is mounted to the frame 28 in a manner which also affords lateral movement of its upper end 32a, so that the hook 32 is capable of sliding out of the recess 21b and along the side of the needle 21 as the needle 21 retracts.

As the lengths Y' and Y" of the fairing yarn Y move downwardly to form the loop 15, they tend to vibrate laterally due to their engagement with the braid yarns 14a,14a. In order to prevent this motion from causing the loops 15',15' to disengage the frame 28, the rearward end of the frame 28 is provided with a curved nose 28a adjacent the braid zone Z, as illustrated in FIG. 5, and at least one nozzle 35 is provided adjacent the nose 28a to direct a stream of air forwardly against the upper ends of the loops 15',15'. The nose 28a curves around the rearward end of the hook 32 and toward the side of the frame 28 on which the hook 32 is mounted and cooperates with the air emitted from the nozzle 35 to ensure that the loops 15',15' straddle the frame 28 as they advance. As noted heretofore, the fairing yarn Y should have enough twist to form coherent loops but not too must twist as to be twist-lively at the front end of the frame 28.

In producing the fairings 15,15, it is important for the core 11 of the rope to be spaced from the upper edge 28b of the frame 28 a dimension B (FIG. 8) which is less than the stroke A of the needle 21 to ensure smooth operation of the apparatus. By way of example, the dimension A should be about twice the dimension B to produce the fairings of the illustrated embodiment. At a minimum, however, the dimension A should be at least as great as the dimension B.

The fairings 15,15 are spaced apart at equal intervals along the length of the rope 10. Such spacing is ensured in the method of the present invention wherein the longitudinal displacement of the rope 10 is sensed, the sensed displacement is converted into a control signal, the needle 21 is extended in response to the signal, and the needle 21 is automatically retracted. In practicing these method steps, the linear actuator 22 includes a piston 37 slidably mounted within a casing 38. The needle 21 is connected to the forward end of the piston 37, and an elongated rod 39 extends rearwardly through the casing 38 beyond its rearwardmost end 38b. A pressure fluid, in the present instance compressed air, is supplied alternately to the front end 38a and the rear end 38b of the casing 38 by a solenoid-actuated valve assembly 40 which is connected to a source of pressure fluid (indicated as P) and to an exhaust (indicated as E). Thus, the admission of pressure fluid into the rear end 38b of the casing 38 drives the piston 37 forwardly and extends the needle 21; whereas the admission of pressure fluid into the front end 38a of the casing causes the piston 37 to move in the rearward direction to retract the needle 21.

In order to extend the needle 21 in response to a measured displacement of a rope assembly 10, the displacement of the rope is sensed by a line shaft 41 which, as described in the aforementioned patent application, cooperates with a tensioning roller 42 engaged with the rope assembly 10 in the drying chamber 30. The line shaft 41 is connected through a variable speed transmission 43 to a rotatable shaft 44 which mounts a circular cam 45. The cam 45 has a lobe 45a which actuates a normally-open switch 46 each time the shaft 44 makes one complete revolution. The switch 46 is connected in a circuit 48 to the left-hand solenoid 40a of the valve assembly 40 to actuate the same when the cam-lobe 45a engages the switch 46. When actuated, the solenoid 40a displaces the spool 40b of the valve assembly 40 leftward to cause pressure fluid to be supplied to the rear end 38b of the casing 38 and to be exhausted from the front end 38a to drive the piston 37 forwardly, and hence to extend the needle 21. In the illustrated embodiment, the cam-lobe 45a is designed to ensure displacement of the spool 40b into its leftward limit position, where it remains until returned to its rightward limit position.

In order to return the needle 21 automatically to its home position, a limit switch 47 is mounted on the rear end 38b of the cylinder 38. A cam element 39a, mounted on the rod 39, engages the limit switch 47 as the needle 21 moves into its forward limit position. The normally-open limit switch 47 is electrically connected to the righthand solenoid 40c by the circuit 49 and operates to energize the solenoid 40c when engaged by the cam element 39a. When the solenoid 40c is energized, the valve spool 40b is displaced rightward, and pressure fluid is applied to the front end 38a of the cylinder 38 and exhausted from the rear end 38b, thereby driving the piston 37 leftward and retracting the needle 21. Preferably, the cam element 39a is mounted for adjustment longitudinally relative to the operating rod 39, and the cam element 39a is positioned at such a location on the rod 39 as to cause the solenoid 40c to be activated slightly before the needle 21 reaches its forward limit position in order to compensate for the response time required by the control system and to provide an air cushion in the front end 38a of the cylinder 38 for minimizing shocks and vibrations in the needle-actuator mechanism.

For purposes of illustration, the cam lobe 45a is shown displaced clockwise from the extend-needle limit switch 46, having caused the needle 21 to move substantially into its forward limit position. The cam element 39a on the piston rod 39 is illustrated in a position where it is engaged with the limit switch 47 as the switch 47 is actuated. The solenoid valve 40 is illustrated in its neutral position corresponding to the brief interval during which the switch 47 is causing it to reverse directions.

For the purpose of varying the axial spacing between the fairings 15,15, the transmission 43 is provided internally with means to vary the ratio between the angular displacement of the line shaft 41 and the angular displacement of its output shaft 44. The internal mechanism is operated by an adjustment wheel 43a outside the transmission 43. Thus, by rotating the adjusting wheel 43a, the displacement of the rope assembly 10 required before the needle 21 is actuated may be varied, and the spacing between the fairings 15,15 may be varied accordingly.

Although the faired rope illustrated in FIGS. 1 and 2 has fairings extending along only one side, it may be desirable in certain applications for a rope 210 (FIG. 14) to be provided with two or more rows of fairings 115,115. The rows may be offset angularly with respect to one another such as along diametrically-opposite sides of the rope. Such a faired rope would be manufactured by providing a second needle and gripping assembly offset with respect to the first needle and gripping assembly.

Although the present invention has been described with reference to applying fairings onto a parallel yarn rope, it should be apparent that the method and apparatus may be employed satisfactorily in applying fairings onto other elongated structures such as braided ropes and steel cables. For example, there is illustrated in FIG. 15 a modified embodiment of the present invention wherein fairings 215 are applied onto a steel cable 211. In this embodiment, the jacket is provided by a tape 214a which is wrapped helically about the cable 211 as it advances lengthwise through a tape server. The tape 214a may have an adhesive on its inner side capable of bending to the steel cable with the application of heat; or an uncured neoprene tape which is cured in the dryer 30 could be utilized. Of course, the jacket could be applied by a braider, as in the embodiment of FIGS. 1 and 2; however, in such event, it would be desirable for the cable 211 to be wrapped with neoprene or other resilient tape prior to braiding in order to ensure secure mounting of the fairings to the cable.

In accordance with another object of the present invention, a length of rope having a series of hangers spaced apart along its length is provided. As best seen in FIG. 16 (Sheet 5) a length 310 having a series of spaced loops 315',315' extending laterally therefrom is manufactured similarly to the way in which the length of rope 10 illustrated in FIG. 4 is manufactured. In this embodiment, however, the loops 315',315' are not severed by the knife 26, so that the loops 315',315' provide a strong and convenient hanger means affording the connection to the rope 310 at spaced intervals of things such as fish nets, etc.

In order to produce the rope 310, the apparatus illustrated in FIG. 4 need be modified only slightly. For instance, as best seen in FIG. 17, the tip 321a of the needle 321 is inverted, so that the guideway therein faces away from the path of movement of the rope 310. In addition, the hook 332 is disposed so that its end 332a depends below its mounting frame 325 and extends toward the rope 310 so as to be engaged periodically by the needle 321 as it reciprocates. With this structure, the loops 315',315' disengage the hook 322 automatically as the rope 310 advances forwardly.

According to a further object of the present invention, the apparatus of FIG. 4 also may be utilized to produce a faired article having a relatively small diameter, such as the faired cord 410 illustrated in FIG. 18. Unlike the embodiment of FIG. 1, however, this embodiment of the present invention does not have a separate core element; rather the elongated braided jacket 414 alone mounts the plurality of fairings 415,415 which extend therefrom at spaced intervals along the length of the cord 410. As best seen in FIG. 19, each fairing 415 has an axially-extending base portion 415b and a pair of streamer portions 415a, 415a which extend outwardly between braid yarns 414a,414a of the braided jacket 414 and which are bunched together at the surface of the jacket 414. The section of the jacket 414 between the streamers 415a,415a surrounds and tightly grips the axially-extending base portion 415b to secure the fairing to the cord. Of course, as tension on the cord 410 increases, the braid yarns 414a,414a cooperate to increase their gripping action on the streamers 415,415.

The faired cord 410 is produced by the apparatus illustrated in FIG. 4 which, of course, is modified slightly to produce the smaller diameter article and to compensate for the absence of a core. For instance, as best seen in FIG. 20, the apparatus has drive roll means engaging the jacket 414 to advance the same forwardly away from the braider as it advances braid yarns 414a,414a in a circular path about the longitudinal path of movement of the cord to braid the jacket in a well known manner. As contrasted with the method and apparatus of FIG. 4, the jacket 414 is not braided around a separate core element. Rather, the fairing yarn Y is simply manipulated by the needle and gripping assembly 21 and 25 in the manner already described with reference to FIG. 4 to produce the cord-like article 410. Note the absence of a separate axially-advancing core element upstream of the braid zone. Of course, if desired, a separate core of a low-temperature thermosetting adhesive may be supplied as in FIG. 4 to augment the gripping action provided by the braid yarns 414a,414a and to provide additional means to securely mount the fairings.

In view of the foregoing, it should be apparent that the present invention now provides an improved method and apparatus for manufacturing a novel faired rope or cable. The fairings are securely fastened to the ropes, they resist wrapping about the ropes, and the faired ropes are manufactured economically in a continuous process.

Thus, while preferred embodiments of faired ropes and a preferred method and apparatus for manufacturing such ropes have been described in detail, various modifications, alterations or changes may be made without departing from the spirit and scope of the present invention as defined in the appended claims.

Claims

1. A faired structure, comprising: an elongated core, a jacket around said core, and a series of fairings spaced apart along the length of the core, each of said fairings including a plurality of strands having base portions disposed along the core and gripped tightly by the jacket and having flexible streamer portions splaying laterally outward from the core and terminating in free ends so that said streamer portions can flex freely relative to the jacket in response to fluid flow across the structure.

2. A faired structure according to claim 1 wherein each fairing includes a pair of fairing yarns each having said plurality of strands, and wherein said fairing yarns have base portions extending axially in opposite directions from a common location where said pair of fairing yarns are bunched together by said jacket at the periphery of the core.

3. A faired structure according to claim 2 wherein said fairings are provided by a continuous length of fairing yarn cut to a predetermined length to provide said free ends.

4. A faired structure according to claim 1 wherein said fairings are disposed in at least one row extending lengthwise of said core.

5. A faired structure according to claim 4 wherein said fairings are disposed in at least two rows extending lengthwise of said core with said rows being offset angularly with respect to one another.

6. A faired structure according to claim 4 wherein the streamer portions of said fairings are spaced axially from one another a distance in a range of between about .5 to about 3 rope diameters, and said streamer portions have substantially uniform lengths in a range of between about 5 to 12 rope diameters.

7. A faired structure according to claim 1 wherein said core includes a metallic cable and said jacket includes a tape wrapped helically about said cable and around the base portions of the fairing strands.

8. A faired structure according to claim 1 wherein said core includes a plurality of yarns surrounded by a layer of resilient material and said jacket is braided around said core over said fairing strand base portions and tightly grips the fairing strands.

9. A faired structure, comprising: an elongated braided jacket and a plurality of fairings extending away from the jacket in spaced relation along its length, each of said fairings having an axially-extending base portion surrounded by a section of said jacket and a streamer portion composed of a series of strands extending outwardly between braids of said jacket, said strands in said streamer portion splaying apart from one another and terminating in free ends so that the strands can flex freely relative to the jacket while the gripping action provided by the jacket on the base portions of the fairings increases as tension on the jacket increases.

10. A faired structure according to claim 9 wherein each streamer portion includes a pair of fairing yarns each having said plurality of strands and bunched together by said jacket braids at a common location intermediate axially-adjacent base portions of the fairing strands.

11. A faired structure according to claim 1 wherein each fairing strand has longitudinally-extending frangible weakened portions enabling the streamer portion of the strand to separate lengthwise inwardly from the free ends of the strand.

12. A faired structure according to claim 1 wherein each strand is of polypropylene material.

13. A load-carrying structure, comprising: an elongated core, a braided jacket surrounding the core, and a series of loops extending laterally of the core in spaced relation along its length, said loops being provided by a continuous length of flexible yarn having axially-extending base portions engaged between the braided jacket and the core, each loop having laterally-protruding leg portions extending through the braided jacket at a common location, whereby the loops are fastened securely to the core.

14. A load carrier according to claim 13 including a layer of resilient material surrounding the core beneath the base portions of the loop yarn for cooperating with the braided jacket to grip the loops securely.