The present invention relates to a rope, in particular to a cut resistant synthetic rope, and a method for producing such a rope.
Synthetic ropes and more particularly ropes made from high modulus polymeric material are desirable for great length suspended use, such as hauling or hoisting ropes in mining, cranes and elevators, aerial ropes or ropes for deep sea installations or use in marine and commercial fishing applications, and off-shore mooring. During such applications, the weight of rope by itself already takes up a large part of its load-bearing capacity and winch load capacity; the payload is correspondingly limited. Steel ropes have a disadvantage of being exceedingly heavy in long lengths. Therefore, in these operations synthetic high strength ropes are applied as they provide appropriate strength and lower weight expanding the possibilities, e.g. mooring deeper in the water.
However, in the application environment of such synthetic ropes, there is a risk that sharp and hard objects may impact on the ropes. As a consequence, the synthetic rope is damaged due to limited cut resistance. In addition, synthetic ropes have a poor resistance against transversal forces.
It is an object of the present invention to provide a cut resistant rope having light weight and being able to against impact or cutting.
It is still an object of the present invention to provide a cut resistant fabric as a cut resistant layer for synthetic ropes against impact or cutting.
It is yet another object of the present invention to provide a cut resistant fabric having reasonable flexibility, in particular for synthetic ropes, which would not create additional resistance when the ropes are moving in the sea.
According to the first aspect of the present invention, there is provided a rope comprising a core for providing strength to said rope, wherein at least a metal or composite fabric comprising multiple substantially parallel elongated metal elements is provided around said core for protecting said core from impact and cutting and wherein said multiple substantially parallel elongated elements are in the warp direction and held by yarns. The metal or composite fabric can be a woven fabric or a warp knitted fabric. Herein, the term “metal fabric” refers to a metal based material made through weaving, knitting, spreading, crocheting, or bonding. The metal based material may have polymeric coatings. Moreover, “metal fabric” may also comprise non-metal elements next to the metal elements, e.g. metal wires are woven with polymeric yarns or metal wires are bound by knitted polymeric yarns. The term “composite fabric” refers to a metal based material together with a fiber or polymer based material made through weaving, knitting, spreading, crocheting, or bonding. The composite fabric may further comprise multiple substantially parallel elongated fiber or polymer elongated elements alternating with the multiple substantially parallel elongated metal elements. Herein, “warp direction” means the direction runs lengthwise and parallel to the selvage (i.e. the self-finished edges of fabric). The metal fabric as such has rigidity along the warp, i.e. the longitudinal direction of the elongated metal elements.
When the rope provided with metal or composite fabric suffers impact or cutting of sharp objects, the yarns may be first broken while the metal cords is strong enough to against the cutting and does not break. The advantage of warp knitted fabric over woven fabric is that if the yarns are cut or broken at certain locations, the rest of the stitches of yarns will not get loose and are still in place and function. The metal or composite fabric remains in function except the yarns are partially broken. The warp knitted fabric may be obtained by a technique selected from mono-axial warp knitting, bi-axial warp knitting, raschel knitting and crochet knitting and/or mixtures thereof.
The metal or composite fabric acting as a cut resistant layer of ropes can be any type of metal element based textile products. Some examples of applicable metal element based textile products can be found in another application of the applicant WO2009/062764A1.
As an example, said metal or composite fabric may be in a form of strip and said strip is helically wrapped around said core. Since the fabric is merely stiff in the uni-direction along the longitudinal direction of elongated metal elements, it allows the fabric to be wrapped or wound. Therefore, the metal or composite fabric can be wrapped or wound on the core of rope with an inclination angle between the warp direction of the metal or composite fabric (i.e. the longitudinal direction of the elongated metal elements) and longitudinal direction of the rope. The inclination angle may be varied between 20 to 60°.
As a preferred example, two layers metal or composite fabrics are wrapped around said core with an angle in the range of 20° to 60° for one metal or composite fabric layer and with an angle in the range of −60° to −20° for another metal or composite fabric layer. One layer of metal or composite fabric may be directly wrapped on top of the other layer of metal or composite fabric. This configuration on the one hand provides better cut resistance, and on the other hand has a torsion balance.
The rope, in particular the core, according to the present invention has a light weight and the core of rope provides strength for the rope. The core can be made from natural or synthetic fibers. Common natural fibers for rope are manila hemp, hemp, linen, cotton, coir, jute, straw, and sisal. Synthetic fibers in use for rope-making include polypropylene, nylon, polyesters (e.g. PET, LCP, HDPE, Vectran), polyethylene (e.g. Dyneema and Spectra), Aramids (e.g. Twaron, Technora and Kevlar) and acrylics (e.g. Dralon). Some ropes are constructed of mixtures of several fibers or use co-polymer fibers. Preferably, said core is made from or high modulus polymeric material, such as High-density polyethylene (HDPE).
In the context of the present invention, the substantially parallel elongated metal element is to be understood as a metal wire, a bundle of metal wires, a metal strand or a metal cord. Herein, “substantially parallel” means that the elongated metal elements are parallel to each other (i.e. the inclination angle of longitudinal directions is close to zero) as well as the elongated elements have an inclination angle of longitudinal directions less than 30°, preferably less than 10°, and more preferably less than 5°. The elongated elements are preferably straight. However, they may have certain curvature or deformation especially at certain locations or parts. Optionally, the elements may have a diameter between about 0.2 and about 5 mm, preferably between about 0.3 and about 3 mm, more preferably between about 0.5 and about 3 mm and most preferably between about 1.5 and about 2 mm.
The elongated metal elements according to the invention are preferably of a type which can absorb relatively high amounts of impact energy but also other metal cords may be used. Examples here are:
multi-strand metal cords e.g. of the m×n type, i.e. metal cords, comprising m strands with each n wires, such as 7×3×0.15, 3×7×0.15 or 7×4×0.12, wherein the number with decimal point designates the diameter of each wire, expressed in mm.
compact cords or Seale strand, e.g. of the 1×n type, i.e. metal cords comprising n metal wires, n being greater than 8, twisted in only one direction with one single step to a compact cross-section, such as 12×0.22 wherein the number with decimal point is the diameter of each wire expressed in mm. The advantage to use compact cords or Seale strand is to provide better cut resistance.
layered metal cords e. g. of the I+m (+n) type, i. e. metal cords with a core of I wires, surrounded by a layer of m wires, and possibly also surrounded by another layer of n wires, such as 3×0.2+6×0.35, 3×0.265+9×0.245, 3+9×0.22, or 1×0.25+18×0.22, wherein the number with decimal point is the diameter of each wire expressed in mm.
single strand metal cords e.g. of the 1×m type, i. e. metal cords comprising m metal wires, m ranging from two to six, twisted in one single step, such as 3×0.48, 1×4×0.25; wherein the number with decimal point is the diameter of each wire expressed in mm .
metal cords e. g. of the m+n type, i.e. metal cords with m parallel metal wires surrounded by n metal wires, such as 2+2×0.38, 3+2×0.37, 3×0.48 or 3+4×0.35, wherein the number with decimal point is the diameter of each wire expressed in mm.
A metal element used in the context of the present invention may be a metal cord with a high elongation at fracture, i.e. an elongation exceeding 4%. High elongation metal cord has more capacity to absorb energy. Such a metal cord is:
either a high-elongation or elongation metal cord (HE-cords), i.e. a multi-strand or single strand metal cord with a high degree of twisting (in case of multi-strand metal cords: the direction of twisting in the strand is equal to the direction of twisting of the strands in the cord: SS or ZZ, this is the so-called Lang's Lay) in order to obtain an elastic cord with the required degree of springy potential; an example is 3×7×0.22 High Elongation metal cord with lay lengths 4.5 mm on the 7×0.22 strand and 8 mm for the strands in the steel cord in SS direction;
or a metal cord which has been subjected to a stress-relieving treatment such as disclosed in EP0790349A1; an example is a 4×7×0.25 SS cord.
The elongated metal elements are preferably steel cords. The tensile strength of the steel cords can range from 500 N/mm2 to 2000 N/mm2 and even more, and is mainly dependent upon the composition of the steel, the diameter of the cords and degree of cold deformation. The steel cords should on the one hand have sufficient strength to act against impact and should on the other hand have sufficient flexibility making it possible to be wrapped or wound on the core. The steel cords can be made from carbon steel. Such a steel generally may comprise a carbon content of at most 0.80 wt % C or at most 0.70 wt % C, but most preferably at most 0.50 wt % C, a manganese content ranging from 0.10 to 0.90 wt %, a sulfur and phosphorus content which are each preferably kept below 0.030 wt %, and additional micro-alloying elements such as chromium (up to 0.20 to 0.4 wt %), boron, cobalt, nickel, or vanadium. Also stainless steels are applicable. Stainless steels contain a minimum of 12 wt % Cr and a substantial amount of nickel. The possible compositions are known in the art as AISI (American Iron and Steel Institute) 25 302, AISI 301, AISI 304 and AISI 316.
The elongated metal elements can additionally be coated with adhesion promoters and/or corrosion protective layers. Preferably, the elongated metal elements are galvanized or have a zinc alloy coating, e.g. zinc aluminum coating. More preferably, on top of the zinc or zinc alloy coating, said elongated metal elements are individually coated with a polymer to further protect the metal elements against corrosion and abrasion. The thickness of the coated polymer on the elongated metal elements is in the range of 0.05 to 1 mm, preferably of 0.2 to 0.5 mm and more preferably of 0.3 to 0.4 mm. The coated polymer is any one selected from polyamide (PA), polyethylene (PE), polyethylene terephthalate (PET), polypropylene (PP), polyurethane (PU), polysulfone (PES), ethylene tetrafluoroethylene (ETFE), or their combination. Any traditionally available coating method can be applied and extrusion is preferred.
All elongated metal elements as described above can be equipped with one or more spiral wrapped wires to increase the mechanical bond of the elongated metal elements in the polymer coating, and/or to bundle the n single parallel crimped or non- crimped but plastically deformed wires if the cord is provided using such parallel wires.
The material of multiple substantially parallel elongated elements used for composite fabric may contain fibers or polymers of polyolefin, polyamide, thermoplastic polyester, polycarbonate, polyacetal, polysulfone, polyether ketone, polyimide or polyether fibers.
The multiple substantially parallel elongated elements are held by yarns. In the context of the present invention, the material used for yarns may be fibers or yarns of any suitable type of which the following are examples: glass, poly-aramide, poly(p-phenylene-2,6-benzobisoxazole), carbon, mineral such as basalt, synthetic and natural rubber or natural yarns such as viscose, flax, cotton or hemp. It may also be metal yarn. It may be mixed with fibers or yarns of polymers like polyolefin, polyamide (PA), polyethylene (PE), polypropylene (PP), thermoplastic polyester, polycarbonate, polyacetal, polysulfone, polyether ketone, polyimide or polyether fibers. Preferably, said yarns are made from a same material as the coating on said elongated metal elements. When they are made from the same polymer, the yarns and the coating of the elongated metal elements are compatible and would not create undesired interaction. The yarns may have a diameter in the range from 0.05 to 1 mm, e.g. from 0.05 to 0.5 mm, from 0.1 to 0.3 mm, assuming round yarn shape. The yarns can be knitted or can be woven along the weft direction which is normal to the warp direction.
According to the present invention, the metal or composite fabric around the core is preferably an open fabric, and more preferably having a cover factor in the range of 0.5 to 0.9 and preferably in the range of 0.7 to 0.9. The cover factor defines the fraction of the surface area that is covered by metal or composite elements and yarns over the whole fabric area. The cover factor for closed fabric equals 1. The rope according to the present invention can be used as a mooring line or a submarine rope. When said rope is used for mooring lines or other submarine applications, great resistance can occur if the rope is not permeable to water and thus the rope is difficult to move. The rope wrapped with an open structure metal or composite fabric has sufficient water permeability. Therefore, the metal fabric can protect the rope from mechanical damage during handling and service, meanwhile and importantly be permeable for water to flood the rope core. The application of the metal or composite fabric would not create much additional resistance when the ropes as mooring lines are moving in the sea.
The ropes according to the present invention may have a cover of filter fabric incorporated between the rope core and the metal or composite fabric to block e.g. harmful soil particles. Preferably, the filter fabric is a non-woven fabric. More preferably, the metal or composite fabric is braided or stitched on said non-woven filter fabric. If the metal or composite fabric can be integrated with the non-woven filter fabric, the metal fabric and the filter layer can be applied by one winding process to the ropes and the compactness is even better.
A commonly used type of fiber rope for offshore moorings has a braided jacket to hold inner sub-ropes and provide protection. According to the present invention, the metal or composite fabric provides a same and better function of a traditional jacket, i.e. hold the inner part and provide protection. Therefore, a jacket may be omitted by applying the metal or composite fabric according to the present invention. However, preferably a jacket and more preferably a braided jacket, e.g. polyester or Nylon jacket, is applied on top of the metal fabric to prevent a possible early failure of the yarns. The braided jacket will provide a better flexibility compared with the extruded jacket and allows water permeability.
The jacket can have visible marking such as colored strands or brightly colored longitudinal elements/stripes incorporated in the rope for monitoring rope twist during installation.
The invention will be better understood with reference to the detailed description when considered in conjunction with the non-limiting examples and the accompanying drawings, in which:
Preferably, the rope 10 has a filter fabric 14 around the core as a barrier for ingress of particles. The filter fabric 14 may be a non-woven cloth. As an example, a metal fabric 16 in a form of strip is wrapped or wound around the core 12 covered with a filter fabric 14.
As an example shown in
The steel cords are extruded with polypropylene and preferably the thickness of coating is 1.5 mm. The yarns are preferably polypropylene and have a diameter of 0.2 mm assuming round yarn shape.
As another example, a composite fabric in a form of strip is wrapped or wound around the core 12 covered with a filter fabric 14. Instead of the half of the steel cords 22 in the example shown in
As an alternative solution, the metal or composite fabric is first braided or knitted on the non-woven filter fabric 14. In such a case, the metal or composite fabric and the filter fabric 14 are preferably both in the form of strip and have a similar width, e.g. 50 cm. Then the metal or composite fabric and the filter fabric 14 can be applied in one wrapping step.
As a last step, a braided jacket is preferably applied on top of the metal or composite fabric to further protect the rope. The braided jacket can be made from polyester although other jacket materials are possible.
As yet another example, two metal fabric layers are applied on the top of the filter fabric 14. One metal fabric layer is formed by warping a strip, e.g. as shown in
Number | Date | Country | Kind |
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14168095 | May 2014 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2015/060147 | 5/8/2015 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2015/173129 | 11/19/2015 | WO | A |
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Number | Date | Country | |
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20170145631 A1 | May 2017 | US |