The subject matter of the foregoing related applications are incorporated herein by reference.
The present invention relates to rope systems and methods and, in particular, to ropes that are coated to improve the resistance of the rope to bending fatigue.
The characteristics of a given type of rope determine whether that type of rope is suitable for a specific intended use. Rope characteristics include breaking strength, elongation, flexibility, weight, bending fatigue resistance and surface characteristics such as abrasion resistance and coefficient of friction. The intended use of a rope will determine the acceptable range for each characteristic of the rope. The term “failure” as applied to rope will be used herein to refer to a rope being subjected to conditions beyond the acceptable range associated with at least one rope characteristic.
The present invention relates to ropes that are commonly referred to in the industry as “lift lines”. Lift lines are used to deploy (lower) or lift (raise) submersible equipment used for deep water exploration. Bending fatigue and abrasion resistance characteristics are highly important in the context of lift lines.
In particular, a length of lift line is connected at a first end to an on-board winch or capstan and at a second end to the submersible equipment. Between the winch and the submersible equipment, the lift line passes over or is wrapped around one or more intermediate structural members such as a closed chock, roller chock, bollard or bit, staple, bullnose, cleat, a heave compensating device, or a constant tensioning device.
When loads are applied to the lifting line, the lifting line wraps around such intermediate structural members and is thus subjected to bending fatigue and abrasion at the intermediate structural members. Abrasion and heat generated by friction at the point of contact between the lifting line and the intermediate structural members can create wear on the lifting line that can affect the performance of the lifting line and possibly lead to failure thereof.
The need thus exists for improved ropes for use as lifting lines that have improved bending fatigue and abrasion resistance characteristics.
The present invention may be embodied as a rope structure adapted to engage an external structure comprising a primary strength component and a coating. The primary strength component comprises a plurality of fibers. The coating comprises a lubricant portion and a binder portion that fixes the lubricant portion relative to at least some of the fibers. The coating is applied to the primary strength component such that the lubricant portion reduces friction between adjacent fibers and reduces friction between fibers and the external structure.
The present invention may also be embodied as a method of forming a rope structure adapted to engage an external structure comprising the following steps. A plurality of fibers is provided. The plurality of fibers is combined to form a primary strength component. A coating material comprising a lubricant portion and a binder portion is provided in liquid form. The coating material is applied in liquid form to the primary strength component. The coating material in liquid form is allowed to dry on the primary strength member to form a coating such that the lubricant portion is adhered to at least some of the fibers to reduce friction between adjacent fibers and to reduce friction between fibers and the external structure.
Referring initially to
In addition, the example rope structures 20a and 20b each comprises a coating 30 that is applied either to the entire rope structure (
The fibers 26 are combined to form the primary strength component of the rope structures 20a and 20b. The lubricant portion 34 of the coating 30 is supported by the binder portion to reduce friction between adjacent fibers 26 as well as between the fibers 26 and any external structural members in contact with the rope structure 20a or 20b. The lubricant portion 34 of the coating 30 thus reduces fatigue on the fibers 26 when the rope structures 20a or 20b are bent around external structures. Without the lubricant portion 34 of the coating 30, the fibers 26 would abrade each other, increasing bending fatigue on the entire rope structure 20. The lubricant portion 34 of the coating 30 further reduces friction between the fibers 26 and any external structural members, thereby increasing abrasion resistance of the rope structures 20a and 20b.
With the foregoing understanding of the basic construction and characteristics of the rope structure 20 of the present invention in mind, the details of construction and composition of the blended yarn 20 will now be described.
In the liquid form, the coating material comprises at least a carrier portion, the binder portion, and the lubricant portion. The carrier portion maintains the liquid form of the coating material in a flowable state. However, the carrier portion evaporates when the wet coating material is exposed to the air, leaving the binder portion and the lubricant portion to form the coating 30. When the coating material has dried to form the coating 30, the binder portion 32 adheres to the surfaces of at least some of the fibers 26, and the lubricant portion 34 is held in place by the binder portion 32. The coating material is solid but not rigid when dried as the coating 30.
In the example rope structures 20a and 20b, the coating material is formed by a mixture comprising a base forming the carrier portion and binder portion and PolyTetraFluoroEthylene (PTFE) forming the lubricant portion. The base of the coating material is available from s.a. GOVI n.v. of Belgium under the tradename LAGO 45 and is commonly used as a coating material for rope structures. Alternative products that may be used as the base material include polyurethane dispersions; in any event, the base material should have the following properties: good adhesion to fiber, stickiness, soft, flexible. The base of the coating material is or may be conventional and will not be described herein in further detail.
The example lubricant portion 34 of the coating material is a solid material generically known as PTFE but is commonly referred to by the tradename Teflon. The PTFE used in the coating material of the example rope structures 20a and 20b is in powder form, although other forms may be used if available. The particle size of the PTFE should be within a first preferred range of approximately 0.10 to 0.50 microns on average but in any event should be within a second preferred range of 0.01 to 2.00 microns on average. The example rope structures 20a and 20b are formed by a PTFE available in the marketplace under the tradename PFTE30, which has an average particle size of approximately 0.22 microns.
The coating material used by the example rope structures 20a and 20b comprises PTFE within a first preferred range of approximately 32 to 37% by weight but in any event should be within a second preferred range of 5 to 40% by weight, with the balance being formed by the base. The example rope structures are formed by a coating material formed by approximately 35% by weight of the PTFE.
As an alternative to PTFE, the lubricant portion 34 may be formed by solids of other materials and/or by a liquid such as silicon oil. Other example materials that may form the lubricant portion 34 include graphite, silicon, molybdenum disulfide, tungsten disulfide, and other natural or synthetic oils. In any case, enough of the lubricant portion 34 should be used to yield an effect generally similar to that of the PTFE as described above.
The coating 26 is applied by dipping the entire rope structure 20a and/or individual strands 22 into or spraying the structure 20a and/or strands 22 with the liquid form of the coating material. The coating material is then allowed to dry on the strands 22 and/or rope structure 20a. If the coating 26 is applied to the entire rope structure 20a, the strands are braided or twisted before the coating material is applied. If the coating 26 is applied to the individual strands 22, the strands are braided or twisted to form the rope structure 20b after the coating material has dried.
In either case, one or more voids 36 in the coating 30 may be formed by absences of coating material. Both dipping and spraying are typically done in a relatively high speed, continuous process that does not allow complete penetration of the coating material into the rope structures 20a and 20b. In the example rope structure 20a, a single void 36 is shown in
In the example rope structures 20a and 20b, the matrix formed by the coating 30 does not extend through the entire volume defined by the rope structures 20a or 20b. In the example structures 20a and 20b, the coating 30 extends a first preferred range of approximately ¼ to ½ of the diameter of the rope structure 20a or the strands of the rope structure 20b but in any event should be within a second preferred range of approximately ⅛ to ¾ of the diameter of the rope structure 20a or the strands of the rope structure 20b. In the example rope structures 20a and 20b, the coating matrix extends through approximately ⅓ of the diameter of the rope structure 20a or the strands of the rope structure 20b.
In other embodiments, the matrix formed by the coating 30 may extend entirely through the entire diameter of rope structure 20a or through the entire diameter of the strands of the rope structure 20b. In these cases, the rope structure 20a or strands of the rope structure 20b may be soaked for a longer period of time in the liquid coating material. Alternatively, the liquid coating material may be forced into the rope structure 20a or strands of the rope structure 20b by applying a mechanical or fluid pressure.
The following discussion will describe several particular example ropes constructed in accordance with the principles of the present invention as generally discussed above.
Referring now to
The exemplary rope core 42 and rope jacket 44 are formed from the strands 46 and 48 using a braiding process. The example rope 40 is thus the type of rope referred to in the industry as a double-braided rope. The strands 46 and 48 may be substantially identical in size and composition. Similarly, the yarns 40 and 42 may also be substantially identical in size and composition. However, strands and yarns of different sizes and compositions may be combined to form the rope core 42 and rope jacket 44. Additionally, the fibers 44 and 46 forming at least one of the yarns 40 and 42 may be of different types.
Referring now to
The strands 62 are formed by combining the yarns 64 using any one of a number of processes. The exemplary rope 60 is formed from the strands 62 using a braiding process. The example rope 60 is thus the type of rope referred to in the industry as a braided rope.
The strands 62 and yarns 64 forming the rope 60 may be substantially identical in size and composition. However, strands and yarns of different sizes and compositions may be combined to form the rope 60. In the example rope 60, the strands 62 (and thus the rope 60) may be 100% HMPE or a blend of 40-60% by weight of HMPE with the balance being Vectran.
Referring now to
The strands 72 are formed by combining the yarns 74 using any one of a number of processes. The exemplary rope 70 is formed from the strands 72 using a twisting process. The example rope 70 is thus the type of rope referred to in the industry as a twisted rope.
The strands 72 and yarns 74 forming the rope 70 may be substantially identical in size and composition. However, strands and yarns of different sizes and compositions may be combined to form the rope 70.
Referring now to
The strands 82 are formed by combining the yarns 84 using any one of a number of processes. The exemplary rope 80 is formed from the strands 82 using a braiding process. The example rope 80 is thus the type of rope commonly referred to in the industry as a braided rope.
The strands 82 and yarns 84 forming the rope 80 may be substantially identical in size and composition. However, strands and yarns of different sizes and compositions may be combined to form the rope 80. The first and second types of fibers are combined to form at least some of the yarns 84 are different as described above with reference to the fibers 24 and 28. In the example rope 80, the strands 82 (and thus the rope 80) may be 100% HMPE or a blend of 40-60% by weight of HMPE with the balance being Vectran.
Given the foregoing, it should be clear to one of ordinary skill in the art that the present invention may be embodied in other forms that fall within the scope of the present invention.
This application, U.S. patent application Ser. No. 12/776,958, is a continuation-in-part of U.S. patent application Ser. No. 11/522,236 filed Sep. 14, 2006, now U.S. Pat. No. 7,739,863, which issued on Jun. 22, 2010. U.S. patent application Ser. No. 11/522,236 claims benefit of U.S. Provisional Patent Application Ser. No. 60/717,627 filed Sep. 15, 2005.
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Number | Date | Country | |
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Parent | 11522236 | Sep 2006 | US |
Child | 12776958 | US |