US2025223759A1PendingUtilityA1
Long lived synthetic rope for powered blocks
Est. expiryMay 17, 2036(~9.8 yrs left)· nominal 20-yr term from priority
Inventors:Hjortur Erlendsson
D07B 1/162D07B 2401/205D07B 2501/2015D07B 2207/4054D07B 2501/2061D07B 2501/2038D07B 1/16D07B 5/00D07B 2205/2071D07B 2205/205D07B 2205/2014D07B 2205/2003D07B 2201/209D07B 2201/2089D07B 2201/2068D07B 2201/2066D07B 2201/2055D07B 2201/2049D07B 2201/1096D07B 5/12D07B 1/165D07B 1/025D07B 2201/102D07B 2201/2095D07B 2401/206D07B 2401/207D07B 2207/4059D07B 2201/2052D07B 2201/2041D07B 2201/2036D07B 1/04
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Claims
Abstract
Disclosed is a method for producing a high strength synthetic strength member containing rope and a resultant rope that has greater resilience to high heat temperatures resultant of use with powered blocks and/or sheaves and has a longer service life in comparison to known synthetic rope constructions. The rope of the present disclosure has multiple distinct synthetic substances each forming distinct components that work together to, surprisingly, increase tolerance to bending fatigue of the rope and especially to high heat temperatures resultant of use with powered blocks and/or sheaves in comparison to known synthetic ropes.
Claims
exact text as granted — not AI-modified1 . A method for forming a synthetic rope ( 1 ), the method comprising steps of:
a) providing a core ( 3 ) formed of at least a first synthetic substance, wherein the first synthetic substance is a thermoplastic substance; b) enclosing the core within at least a flow shield capable of retaining within the flow shield at least most of the first synthetic substance when the first synthetic substance is in a semi-liquid phase; c) providing a plurality of individual primary strands ( 19 ) formed of fibers formed of at least a second synthetic substance, wherein the second synthetic substance is an Aramid; d) forming from a third synthetic substance a plurality of inner individual sheaths ( 21 ), wherein each inner individual sheath ( 21 ) is formed as an individual braided sheath, wherein at least one inner individual sheath ( 21 ) formed as an individual braided sheath is formed about and encloses one of the individual primary stands ( 19 ) formed of the second synthetic substance, so that at least some of the individual primary strands ( 19 ) formed of the second synthetic substance are each enclosed by a respective one of the inner individual sheaths ( 21 ) formed of the third synthetic substance, wherein the third synthetic substance has a decomposition temperature that is lower than a decomposition temperature of the second synthetic substance; e) next, forming a hollow braided strength member ( 7 ) around the core ( 3 ) from a plurality of the individual primary strands ( 19 ), wherein at least some of the individual primary strands ( 19 ) used in forming the hollow braided strength member ( 7 ) have at least one inner individual sheath ( 21 ); f) subjecting the strength member ( 7 ) to tension and heat so as to cause the core to experience a non-solid phase and so as to cause the strength member ( 7 ) and the core ( 3 ) to become compacted and elongated;
followed by cooling both at least the strength member ( 7 ) and the core ( 3 ) under tension so as to cause the strength member ( 7 ) and the core ( 3 ) to become permanently compacted and permanently elongated; and
g) enclosing the strength member ( 7 ) within an outer sheath ( 8 ), wherein the synthetic rope ( 1 ) is permanently compacted and permanently elongated; and wherein the method further comprises the step of adhering the outer sheath ( 8 ) to the strength member ( 7 ) via a fourth synthetic substance.
2 . The method of claim 1 , wherein the third synthetic substance is less bristle than the second synthetic substance.
3 . The method of claim 2 , further comprising stranding the primary strands ( 19 ) directly from fibers and/or filaments.
4 . The method of claim 1 , further comprising stranding the primary strands ( 19 ) directly from fibers and/or filaments.
5 . The method of claim 1 , wherein at least one inner individual sheath ( 21 ) formed as an individual braided sheath is formed from fibers.
6 . The method of claim 5 , wherein the fibers forming each fiber-formed inner individual braided sheath ( 21 ) are HMPE fibers.
7 . The method of claim 6 , wherein the outer sheath ( 8 ) is formed with a hollow braided construction, and wherein the step of adhering the outer sheath ( 8 ) to the strength member ( 7 ) via the fourth synthetic substance comprises the steps of:
h) situating at least the fourth synthetic substance in a flowable phase onto an exterior surface of a plurality of the inner individual braided sheaths ( 21 ) formed of the third synthetic substance, wherein said fourth synthetic substance is, when in a set and/or solid state, an elastic and adhesive substance; and i) followed by forming the hollow braided outer sheath ( 8 ) about the hollow braided strength member ( 7 ), wherein the hollow braided outer sheath ( 8 ) compresses against the exterior surfaces of at least portions of the plurality of the inner individual braided sheaths ( 21 ) formed of the third synthetic substance.
8 . The method of claim 7 , further comprising applying a constrictive force by a plurality of the inner individual braided sheaths ( 21 ) to a plurality of the primary strands ( 19 ) that is a constrictive force that is sufficiently low so that a plurality the primary strands ( 19 ) are deformed during manufacturing of the rope and adopt a non-circular cross section in a finished product of the rope when viewed in a plane that is perpendicular to the long dimension of the rope.
9 . The method of claim 8 , further comprising forming a plurality of the inner individual braided sheaths ( 21 ) from flattened fibers.
10 . The method of claim 9 , further comprising braiding the sheaths ( 21 ) from the flattened fibers in such fashion that at least some of the flattened fibers are untwisted about their long axis along a section of the finished product of the rope.
11 . The method of claim 10 , further comprising stranding the primary strands ( 19 ) directly from fibers and/or filaments.
12 . The method claim 9 , further comprising stranding the primary strands ( 19 ) directly from fibers and/or filaments.
13 . The method of claim 8 , further comprising stranding the primary strands ( 19 ) directly from fibers and/or filaments.
14 . The method of claim 5 , wherein the fibers forming each fiber-formed inner individual braided sheath ( 21 ) are PTFE fibers.
15 . The method of claim 14 , wherein the outer sheath ( 8 ) is formed with a hollow braided construction, and wherein the step of adhering the outer sheath ( 8 ) to the strength member ( 7 ) via the fourth synthetic substance comprises the steps of:
h) situating at least the fourth synthetic substance in a flowable phase onto an exterior surface of a plurality of the inner individual braided sheaths ( 21 ) formed of the third synthetic substance, wherein said fourth synthetic substance is, when in a set and/or solid state, an elastic and adhesive substance; and i) followed by forming the hollow braided outer sheath ( 8 ) about the hollow braided strength member ( 7 ), and wherein the hollow braided outer sheath compresses against the exterior surfaces of at least portions of a plurality of the inner individual braided sheaths ( 21 ) of the third synthetic substance.
16 . The method of claim 15 , further comprising applying a constrictive force by a plurality of the inner individual braided sheaths ( 21 ) to a plurality of the primary strands ( 19 ) that is a constrictive force that is sufficiently low so that a plurality of the primary strands ( 19 ) are deformed during manufacturing of the rope and adopt a non-circular cross section in a finished product of the rope when viewed in a plane that is perpendicular to the long dimension of the rope.
17 . The method of claim 16 , further comprising forming a plurality of the inner individual braided sheaths ( 21 ) from flattened fiber.
18 . The method of claim 17 , further comprising stranding the primary strands ( 19 ) directly from fibers and/or filaments.
19 . The method of claim 17 , further comprising braiding the sheaths ( 21 ) from the flattened fibers in such fashion that at least some of the flattened fibers are untwisted about their long axis along a section of the finished product of the rope.
20 . The method of claim 19 , further comprising stranding the primary strands ( 19 ) directly from fibers and/or filaments.
21 . The method of 16 , further comprising stranding the primary strands ( 19 ) directly from fibers and/or filaments.
22 . The method of claim 1 , wherein the step of adhering the outer sheath ( 8 ) to the strength member ( 7 ) via the fourth synthetic substance comprises the step of:
h) prior to enclosing the strength member ( 7 ) within the outer sheath ( 8 ), situating at least the fourth synthetic substance in a flowable phase onto an exterior surface of the strength member ( 7 ) so that the outer sheath ( 8 ) is adhered to the strength member ( 7 ) via the fourth synthetic substance when the outer sheath ( 8 ) encloses the strength member ( 7 ), wherein the fourth synthetic substance is, when in a set and/or solid state, an elastic and adhesive substance.Cited by (0)
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