Dynamic rope
A dynamic rope is a kernmantel climbing rope engineered with a core and sheath construction to provide controlled elasticity, absorbing the energy of falls to reduce impact forces on climbers during rock climbing, ice climbing, and mountaineering.[1] These ropes are certified under international standards such as EN 892 and UIAA 101, which mandate specific performance criteria including a maximum static elongation of 10% under an 80 kg static load, and a dynamic elongation not exceeding 40% during the first standardized fall test.[2] Dynamic ropes are categorized into three types: single ropes, marked with a "1" and used individually through protection points; half ropes, marked with "1/2" and used in pairs for redundancy and reduced drag; and twin ropes, marked with a "∞" symbol and clipped together in pairs at each point for simplicity in certain routes.[2] To ensure safety, EN 892 requires single ropes to withstand at least five UIAA falls (an 80 kg mass dropped from a factor 1.77 height) with a maximum impact force of 12 kN, half ropes to withstand at least five UIAA falls (a 55 kg mass dropped from a factor 1.77 height) with a maximum impact force of 8 kN, while twin ropes must endure at least 12 falls (an 80 kg load on both strands dropped from a factor 1.77 height) with a maximum impact force of 12 kN.[2][3] Typically available in diameters from 8.5 mm to 11 mm and lengths of 30 to 80 meters, dynamic ropes prioritize durability against abrasion and UV exposure, with optional water-repellent treatments to maintain performance in wet conditions.[4][2]Definition and Characteristics
Overview
A dynamic rope is an elastic climbing rope specifically engineered to stretch under dynamic loads, thereby absorbing energy from falls and reducing the impact forces transmitted to climbers and their anchoring gear.[2] This design makes it essential for lead climbing, ice climbing, and mountaineering, where unpredictable falls are a primary risk.[5] In contrast, static ropes feature minimal elongation, typically less than 5% under load, and are suited for applications like hauling equipment, rappelling, or rescue operations that do not involve fall arrest.[2] Unlike dynamic ropes, static variants prioritize dimensional stability over energy absorption to maintain precise control in non-impact scenarios.[6] The evolution of dynamic ropes began with a mid-20th-century shift from natural fibers such as hemp and manila, which offered limited elasticity, to synthetic materials like nylon, introduced in 1935 and widely adopted in climbing by the 1950s for its superior stretch and durability.[7] Fundamentally, this stretch—known as dynamic elongation, typically ranging from 30% to 40% under fall loads—converts kinetic energy from a climber's descent into potential energy stored in the rope, mitigating injury risk.[8] Most dynamic ropes utilize kernmantle construction, with a braided core providing the elasticity and an outer sheath offering protection.[9]Key Properties
Dynamic ropes are engineered to exhibit controlled elongation under varying loads, which is crucial for their role in fall arrest. Under static loading, such as a climber's body weight (approximately 80 kg), elongation typically ranges from 6% to 10% of the rope's length, minimizing unwanted stretch and system sag during normal use.[10][11] In dynamic conditions, such as during a fall, elongation can increase to up to 40% of the rope's length, enabling the rope to stretch elastically and dissipate kinetic energy through viscoelastic properties of the nylon fibers, thereby reducing injury risk to the climber.[12][3] Impact force represents the peak load transmitted to the climber and anchoring system during a standardized fall test, with typical values for single ropes falling between 5 kN and 12 kN.[8][13] This force is calculated as the maximum tension recorded on an 80 kg mass dropped from approximately 5 m onto 2.8 m of rope (fall factor 1.77), ensuring the rope limits deceleration to safe levels without exceeding UIAA/EN 892 thresholds of 12 kN for single ropes or 8 kN for half ropes.[14] The energy absorption capacity of dynamic ropes is assessed by their ability to withstand repeated falls in controlled tests, with single ropes required to hold at least 5 UIAA falls (each a factor 1.77 drop with an 80 kg mass) and often rated for 8-20 or more, depending on rope length, diameter, and construction.[15][14] Half ropes must hold at least 5 falls (55 kg mass each), while twin ropes, tested in pairs, must endure a minimum of 12 falls under an 80 kg load on both strands, reflecting their design for multi-strand use in alpine environments where fall factors and lengths vary.[16] This rating indicates the rope's fatigue resistance, as each fall progressively degrades the core fibers until failure. Beyond these core performance metrics, dynamic ropes maintain a low weight-to-strength ratio, often around 60 g/m for a 10 mm diameter rope with a static tensile strength exceeding 20 kN, optimizing portability for extended climbs.[17][18] They also provide robust abrasion resistance through a durable sheath that protects the core during contact with rough rock surfaces, as verified in UIAA sheath slippage and wear tests. Additionally, their flexibility ensures ease in knot-tying and handling, with sheath percentages of 30-40% contributing to suppleness without compromising structural integrity.[3][19]History and Development
Early Innovations
Prior to the 20th century, mountaineers relied on natural fiber ropes made from materials such as hemp and manila, which were commonly used in early alpine climbing expeditions starting in the 1800s. These ropes, typically 8-11 mm in diameter and 18-36 m in length, offered tensile strengths around 10 kN but were notably inelastic, transmitting high shock loads during falls that often resulted in climber injuries or catastrophic rope failure, as demonstrated in 1864 tests where they snapped after an 8-foot drop. Their stiffness limited use primarily to abseiling, short traverses, or lassoing, with strength degrading up to 50% after exposure to moisture or winter conditions, necessitating frequent replacement.[20] The introduction of nylon marked a pivotal innovation in the 1930s and 1940s, with DuPont patenting the synthetic polyamide in 1935 for its superior strength and elasticity compared to natural fibers. During World War II, nylon's durability made it ideal for military parachutes, where it absorbed impacts effectively, inspiring its adaptation for climbing ropes; the first nylon climbing ropes appeared in the United States in the early 1940s, providing greater stretch to mitigate fall forces. By 1945, post-war prototypes in Europe further refined this elasticity, allowing ropes to elongate up to 30-40% under load while retaining core integrity, a significant leap from the rigid natural alternatives. Nylon's chemical structure, a long-chain polymer, contributed to this resilience by distributing stress evenly across fibers.[7][21] The German Alpine Club (DAV) played a crucial role in early testing of these nylon prototypes, collaborating with companies like Edelrid to evaluate performance in simulated falls and alpine conditions during the late 1940s. This testing facilitated the ropes' adoption in landmark ascents, such as the 1950 French expedition to Annapurna, where nylon ropes were fixed across difficult passages to support loads and ensure safer progress on the 8,091 m peak.[22] A key design shift occurred from traditional laid (twisted) ropes, which were prone to kinking and uneven wear, to braided constructions that enhanced elasticity and handling. By the early 1950s, braided nylon prototypes demonstrated improved energy absorption, reducing peak forces in falls by up to 50% compared to laid versions, setting the stage for safer dynamic performance in mountaineering.[21][7]Modern Advancements
In the 1960s, the Union Internationale des Associations d'Alpinisme (UIAA), founded in 1932, initiated the development of safety standards for climbing equipment through its Safety Commission, beginning with rope testing in 1960 and leading to the first formal standards for dynamic ropes that emphasized energy absorption and fall arrest capabilities.[23] These early standards, codified in UIAA 101, required dynamic ropes to withstand multiple falls while limiting impact forces, marking a shift toward regulated performance metrics for climber safety. Concurrently, the kernmantle construction—introduced by Edelrid in 1953 with a braided nylon sheath over a synthetic core—gained widespread adoption by the 1970s, replacing laid nylon ropes and enabling greater elasticity and durability in dynamic applications.[24] This design became the foundation for modern dynamic ropes, as its core provided strength and the sheath offered protection against abrasion. During the 1980s and 2000s, advancements focused on refining rope performance for specialized climbing scenarios, including the evolution toward thinner diameters to reduce weight and drag on multi-pitch routes. Half ropes slimmed to around 8.5–9 mm, while twin ropes approached 7–8 mm, allowing climbers to carry lighter systems without compromising safety margins under UIAA testing.[8] Dry treatments emerged as a key innovation for water resistance, with Edelrid pioneering the first dry rope in 1966 and manufacturers like Maxim introducing advanced processes such as Endura Dry in 1990, which impregnated both core and sheath to minimize absorption in wet conditions like alpine or ice climbing.[25] These treatments reduced water uptake to under 50% of untreated ropes' capacity, enhancing handling and longevity. Additionally, triple-rated ropes—certified for use as single, half, or twin configurations—gained prominence in the 2000s, offering versatility for mixed trad, sport, and alpine ascents by meeting EN 892 requirements across systems.[26] In the 2010s and 2020s, material innovations emphasized sustainability and resilience amid growing environmental concerns. Manufacturers adopted eco-friendly practices, such as bluesign-certified production and recycled nylon sheaths, reducing the carbon footprint of ropes while maintaining dynamic properties; for instance, Edelrid's Eco Dry lines use PFC-free coatings to limit water absorption without persistent chemicals, and in 2024, Edelrid launched the NEO 100 3R, the first dynamic climbing rope made from 100% recycled materials.[27][28] Post-2020 studies on rope aging confirmed modern polyamide constructions' strong UV resistance, with exposure tests showing minimal strength loss after months of weathering, addressing climate-driven demands for durable materials in extended high-altitude expeditions.[29] UIAA standards evolved to reflect these changes, with updates to UIAA 101 in the mid-2010s incorporating refined impact force limits for thinner ropes, ensuring lower forces (typically under 12 kN) in half-rope systems to mitigate injury risks on rugged terrain.[2]Construction and Materials
Kernmantle Design
The kernmantle design features a layered construction with an inner core, or kern, and an outer sheath, or mantle, that together provide the elasticity and durability required for dynamic ropes in climbing applications. The kern consists of multiple twisted nylon yarns bundled together, which bear 70-80% of the rope's total load and strength, enabling controlled elongation to absorb impact forces during falls.[30][31] The mantle, comprising a braided cover, handles the remaining 20-30% of the load while primarily shielding the core from external damage such as abrasion and ultraviolet exposure.[32][33] Both the kern and mantle are predominantly constructed from nylon, which contributes to the rope's overall flexibility.[34] Braiding techniques in kernmantle ropes are optimized for performance, with the sheath typically produced on machines using 32 to 48 carriers to create a tight, uniform weave that promotes smooth handling through devices and over edges.[31][32] The core's lay-up involves loosely twisted fiber bundles arranged to allow specific stretch characteristics, balancing energy absorption with minimal static elongation under normal loads.[32] These methods ensure the rope maintains structural integrity during repeated use. Design variations in the sheath enhance functionality for different climbing scenarios, such as bi-pattern weaves that alter the braiding midway to mark the rope's midpoint and provide better grip on rough surfaces.[35][36] In contrast, slick sheaths prioritize reduced friction for quicker rope flow in belay systems and rappels, often achieved through specialized coatings or tighter braids.[37] Some manufacturers apply supertreatments to further minimize friction, improving efficiency in high-speed maneuvers.[31] Key advantages of the kernmantle design include even load distribution across the core and sheath, which stabilizes the rope and prevents kinking during coiling or use.[38] Additionally, observable sheath slippage relative to the core acts as a practical indicator of wear from abrasion or repeated falls, prompting timely inspection or retirement of the rope.[39][2]Core and Sheath Materials
Dynamic ropes feature a core primarily composed of polyamide fibers, such as nylon 6 or nylon 66, which deliver essential dynamic elongation of 20-30% to absorb fall energy effectively.[40][41][11] These materials exhibit high tensile strength and elasticity, making them ideal for the load-bearing demands of climbing applications. In recent years, such as the 2020s, some specialized ropes have incorporated aramid (Kevlar) blends into the core or sheath for added strength and cut resistance.[42][43] The sheath, which protects the core and constitutes about 30-40% of the rope's structure, is also made from nylon, often enhanced with polyurethane coatings to boost abrasion resistance, UV protection, and color retention.[44] Dry treatments, including silicone impregnation of the core and sheath, repel water absorption—limiting it to under 5% per UIAA standards—and minimize drag during use, a practice that became critical with evolving rope standards in the 1990s to ensure performance in wet conditions like alpine or ice climbing.[45][46] Sustainability efforts in material sourcing have led to a shift toward recycled nylon, as seen in Mammut's 2023 product lines, which repurpose post-consumer waste to lower production impacts while maintaining performance.[47] Manufacturers increasingly avoid PVC in coatings due to its environmental persistence and toxicity concerns, favoring eco-friendly alternatives that reduce microplastic release and carbon footprints.[48] Material properties directly affect rope performance; nylon's density of approximately 1.14 g/cm³ contributes to manageable weight without excessive bulk.[49] Additionally, nylon withstands temperatures up to 150°C before degradation compromises its integrity, though prolonged exposure near this threshold can reduce elongation and strength.[50]Types and Classifications
Single Ropes
Single ropes represent the most common type of dynamic rope in climbing, designed for standalone use where the entire load is borne by a single strand. They are identified by a distinctive marking consisting of the number "1" inside a circle at both ends, indicating compliance with UIAA and EN 892 standards for individual operation. These ropes are threaded singly through belay devices and protection points during lead climbing or top-roping, providing a straightforward system for arresting falls without the need for paired configurations.[51][2][52] Typical single ropes feature diameters ranging from 8.5 mm (minimum per standards) to 11 mm, with common sizes 9.0-10.5 mm balancing durability and handling ease for various climbing scenarios. Under UIAA certification, these ropes must hold at least five factor-1.77 falls with an 80 kg mass and a maximum impact force of 12 kN, ensuring reliable performance in dynamic arrests.[12][2][12][2] The primary advantages of single ropes lie in their simplicity and reduced weight, making them ideal for single-pitch sport climbing and traditional routes where minimal drag and easy management are prioritized. This configuration streamlines belaying and clipping, allowing climbers to focus on progression without the complexity of alternating strands. For instance, Petzl's MAMBO 10.1 mm rope exemplifies versatility, offering a 65 g/m weight and 37% sheath percentage for efficient handling in both gym sessions and outdoor cragging.[53][12][54] However, single ropes provide less redundancy compared to paired systems, increasing vulnerability to sharp edges or rockfall in multi-pitch scenarios where a single point of failure could compromise safety. They are also not optimal for glacier travel, as the absence of a second strand complicates crevasse rescue maneuvers like prusiking and limits load-sharing during potential falls into voids.[55][56]Twin and Half Ropes
Half ropes, identified by the ½ marking on each end, have diameters from 7.7 mm (minimum per standards) to 9.5 mm, typically 8.0-9.0 mm, and are intended for use in pairs to enhance safety on multi-pitch routes.[14][2] These ropes are clipped alternately to protection points—one rope to alternate pieces—which minimizes rope drag on zigzagging or complex terrain, facilitates belay escape in emergencies, and directs falls away from the leader or protection.[12] This alternating clipping technique distributes forces across multiple points, reducing the peak load on any single piece of gear during a fall.[57] Under UIAA certification, each half rope must withstand at least five factor-1.77 falls with a 55 kg mass and a maximum impact force of 8 kN.[2] Twin ropes, denoted by the twin symbol (∞), are thinner, generally 7.7 mm (minimum) to 9 mm, and must always be used in pairs with both strands clipped together into every protection point as if they were a single unit.[14][2] Designed primarily for ice, mixed, and alpine climbing where weight savings are critical, twin ropes offer redundancy and allow for double-length rappels by tying the pair together.[58] Their paired use ensures that falls are caught on both strands simultaneously, providing consistent performance in environments with frequent rockfall or ice hazards.[52] Under UIAA certification, the pair must endure at least twelve factor-1.77 falls with an 80 kg mass and a maximum impact force of 12 kN.[2] A key advancement in rope design, triple-rated ropes—certified under UIAA standards for single, half, or twin configurations—emerged as an innovation after 2000, allowing climbers greater flexibility without needing multiple specialized ropes.[26] These versatile ropes meet the distinct testing requirements for each category, such as withstanding at least five falls with a 55 kg mass per rope for half-rope use or twelve falls with an 80 kg mass on the pair for twin-rope use.[59][2] The paired nature of twin and half ropes yields significant benefits, including reduced overall rope drag on traversing routes for half systems and lower impact forces per strand compared to single ropes, which bolsters protection integrity.[60] For instance, on demanding alpine big walls like El Capitan, climbers employ half or twin ropes to manage extended rappels and mitigate drag over expansive, varied terrain.[61] Pairs of these ropes typically adhere to standard lengths of 50 to 60 meters each, as detailed in physical specifications.[12]Physical Specifications
Lengths and Weights
Dynamic ropes are typically available in lengths ranging from 30 meters to 80 meters, with 60 meters serving as the standard length for most rock climbing applications. Shorter 40- to 50-meter ropes are commonly used for indoor gym climbing or short outdoor routes, while 70-meter and longer variants, up to 100 meters, accommodate multi-pitch routes and big walls. Half ropes, employed in pairs for enhanced safety on trad or alpine climbs, are generally sold in 50- to 60-meter lengths each.[12][62][63] Weight is a critical factor in rope selection, as it influences climber mobility and pack weight during ascents. Single dynamic ropes typically weigh between 50 and 70 grams per meter, depending on diameter and construction, with a 60-meter rope thus ranging from about 3 to 4.2 kilograms total. Twin and half ropes are lighter, often 40 to 50 grams per meter, allowing pairs to provide redundancy without excessive burden— for instance, two 50-meter half ropes might total under 5 kilograms combined. These metrics ensure compliance with UIAA and EN 892 standards, which emphasize overall performance rather than fixed weights.[64][2][65] Variations in length and weight cater to specialized needs, such as extendable ropes reaching 100 meters for expedition-length rappels or multi-day traverses. Post-2020 innovations have introduced ultralight dynamic ropes under 45 grams per meter, optimized for speed climbing and alpine pursuits where minimizing carry weight enhances efficiency.[63][66] When selecting a dynamic rope, climbers should consider the route's pitch length plus twice the height for safe rappels, ensuring the rope can double back without shortfall. Opting for thinner profiles can yield 20-30% weight savings compared to standard diameters, though this may subtly affect long-term durability as explored in related specifications.[62][12]Diameters and Durability
Dynamic ropes are categorized by diameter into thin, standard, and thick variants, each offering distinct performance characteristics influenced by their radial thickness. Typical diameters vary by type: single ropes from 8.5 mm to 11 mm, half ropes from 8 mm to 9.5 mm, and twin ropes from 7.5 mm to 9 mm. Thin dynamic ropes, typically ranging from 8 mm to 9 mm, prioritize lightweight construction for reduced drag and easier handling on extended routes, but they exhibit higher susceptibility to wear due to a thinner sheath that provides less protection against abrasion. Standard diameters, between 9.5 mm and 10.5 mm, strike a balance suitable for versatile applications like sport and trad climbing, offering adequate durability without excessive bulk. Thick ropes, exceeding 10.5 mm up to 11.5 mm, are favored for high-abrasion environments such as gym sessions or top-roping, where their robust sheath enhances longevity for beginners and frequent users.[67][12][68][69] Durability in dynamic ropes is closely tied to diameter, with thicker constructions demonstrating superior sheath abrasion resistance; thicker ropes can withstand more exposure to rough surfaces before weakening compared to thinner counterparts. These metrics underscore the trade-off where thicker ropes prioritize endurance over minimalism, extending usable life in demanding conditions.[3][67][70] Handling characteristics vary markedly with diameter, as thinner ropes (below 9.5 mm) generate less friction in belay devices, necessitating models specifically rated for slim profiles—such as tube-style devices with a minimum compatibility of 8.5 mm—to ensure reliable braking and prevent slippage. Post-2022 advancements in belay technology, including updated assisted-braking systems like the Edelrid Pinch, have expanded compatibility to ropes as thin as 8.5 mm, accommodating the rise in lightweight dynamic options without compromising safety. Overall trade-offs include thinner ropes being 20-30% lighter per meter (e.g., 48 g/m versus 60+ g/m for thick variants), which aids efficiency on long pitches, though thinner ropes typically transmit lower peak impact forces due to greater elongation, providing softer catches while all complying with EN 892 maximums of 12 kN for single and twin ropes or 8 kN for half ropes.[71][72][67][4]Standards and Testing
Certification Bodies
The primary certification body for dynamic ropes is the Union Internationale des Associations d'Alpinisme (UIAA), the International Climbing and Mountaineering Federation, founded in 1932 and responsible for developing global safety standards for climbing equipment since 1960.[23] The UIAA's standard UIAA 101 specifically governs dynamic mountaineering ropes, ensuring they meet requirements for energy absorption, static and dynamic elongation, and sheath slippage, among others; it aligns closely with European norms while adding supplementary criteria like enhanced water repellency testing.[2] UIAA certification is voluntary but widely adopted worldwide, with the organization's logo serving as a mark of compliance on approved ropes. In Europe, dynamic ropes must comply with EN 892, the European Standard for dynamic mountaineering ropes, first published in 1996 and updated to EN 892:2012+A3:2023, harmonized with UIAA 101 to facilitate mutual recognition.[73] [74] EN 892 outlines safety requirements and test methods for single, half, and twin ropes in kernmantle construction, making it a legal requirement under the EU's Personal Protective Equipment (PPE) Regulation (EU) 2016/425 for ropes sold in the European Economic Area. Compliance with EN 892 enables the CE marking, a mandatory conformity mark indicating that the product meets EU health, safety, and environmental standards, verified through third-party testing by notified bodies. Other regional bodies provide variations or specific applications. In the United States, the American Society for Testing and Materials (ASTM International) develops standards such as ASTM F2116 for low-stretch kernmantle ropes used in rescue and related activities, offering adaptations for North American contexts where UIAA/EN standards are often referenced but not always mandatory.[75] For sport climbing competitions, the International Federation of Sport Climbing (IFSC) mandates that ropes used in events conform to EN 892 to ensure consistency and safety across international disciplines.[76] The certification process for dynamic ropes typically involves rigorous laboratory testing by accredited facilities to verify compliance with the relevant standards, followed by manufacturer declarations or third-party certifications. For CE-marked products, this includes an initial EC type-examination by a notified body and ongoing surveillance, such as annual factory production control audits, to maintain quality assurance. Approved ropes bear permanent labels with certification logos (e.g., UIAA safety label or CE mark), along with details like rope type, diameter range, and length to indicate adherence.[77]Impact and Elongation Tests
The impact force test evaluates a dynamic rope's ability to absorb energy during a fall, limiting the maximum force transmitted to the climber. In this procedure, a mass is dropped from 4.8 m onto a 2.8 m length of rope, resulting in a fall factor of approximately 1.71. For single ropes, the mass is 80 kg; for half ropes, 55 kg; for twin ropes, 80 kg on both strands. The peak force measured during the first drop must not exceed 12 kN for single ropes, 8 kN for half ropes, and 12 kN for twin ropes (when tested in pairs). This test, conducted using a standardized drop tower apparatus, ensures the rope dissipates fall energy without excessive shock loading on the system.[23] Elongation tests assess both static and dynamic stretch characteristics, which influence rope handling and energy absorption. For static elongation, an 80 kg load is applied to a reference length of rope (often 2 m), measuring the percentage increase in length; limits are 10% maximum for single and twin ropes, and 12% for half ropes, with typical values ranging from 3-10% under initial loading and up to 5-12% under sustained or repeated loading. Dynamic elongation is measured during the first fall of the impact test, where the rope's stretch must not exceed 40% for all types to prevent excessive pendulum motion or reduced stopping distance. These metrics are recorded using strain gauges and high-speed imaging in controlled laboratory conditions.[23][3] The fall rating determines the rope's durability by quantifying the number of standardized falls it can withstand before failure. Using the same setup as the impact test (4.8 m drop, fall factor ~1.71), with 80 kg for single and twin (paired) ropes and 55 kg for half ropes, the rope undergoes repeated drops until breakage; single and half ropes must endure at least 5 falls, while twin ropes (paired) require a minimum of 12. Post-2020 updates in testing protocols, including dynamic lifetime tracking, monitor degradation over multiple falls to better predict real-world performance beyond initial certification. This UIAA-specified test uses the DODERO apparatus for consistency.[23][15] Additional tests verify practical integrity under environmental and usage stresses. Knotability is assessed by tying standard knots like the figure-eight and ensuring they hold under load without excessive slippage or difficulty in formation. Aging tests expose the rope to ultraviolet light and heat, followed by re-testing for impact force and elongation to confirm retention of performance. Water absorption testing is optional for water-repellent ("dry") ropes; under UIAA criteria, mass gain must not exceed 5% after a 15-minute exposure to flowing water at 2 L/min. Sheath slippage is checked post-fall tests, limited to 1.5% relative movement between core and sheath. These procedures, overseen by UIAA and EN 892 standards, ensure comprehensive safety validation.[23][3]| Test Type | Key Metric | Single Rope Limit | Half Rope Limit | Twin Rope Limit (Paired) |
|---|---|---|---|---|
| Impact Force | Max peak force (first fall) | ≤12 kN | ≤8 kN | ≤12 kN |
| Static Elongation | % stretch under 80 kg | ≤10% | ≤12% | ≤10% |
| Dynamic Elongation | % stretch (first fall) | ≤40% | ≤40% | ≤40% |
| Fall Rating | Min. number of falls | ≥5 | ≥5 | ≥12 |
| Water Absorption (dry ropes, optional) | % mass gain after test | ≤5% | ≤5% | ≤5% |