The trendsetter among the 16-strand climbing ropes
The Braided Safety Blue from TEUFELBERGER combines features that ensure unparalleled safety, ergonomics and durability during climbing.
Standards: EN 1891A, ANSI Z133-201
Plait number: 16
The Braided Safety Blue from TEUFELBERGER is the trendsetter among 16-strand climbing ropes. This rope for tree care is certified to the standards EN 1891A and ANSI Z133-2012.
Braided Safety Blue is equipped with a blue safety core of polyamide. This core is exposed only when the rope is seriously damaged or has worn down to the point where it must be discarded. The visibility of the blue core indicates that you should exchange the climbing rope.
Being 12.7mm in diameter, this climbing rope feels good in your hand, which will help you to work efficiently with the rope and to avoid hand fatigue.
Our arborist rope Braided Safety Blue is characterized by:
- Proprietary ‘blue’ safety core
- Plied strand yarns for improved abrasion resistance
- Protective coating improving durability and grip
- Great ease of splicing
||Min. breaking strength, free length [daN]
||Min. breaking strength, free length [lbf]
||1 × 1 × 1 cm
No, Yes – Both Ends (+£50.00), Yes – One End (+25.00)
[slaice] - a combination of stitching and splicing
One of the latest assets in TEUFELBERGER's product portfolio is its patented [slaice] rope termination. This unique combination of splicing and stitching is available for the Tachyon, Braided Safety Blue, Arbor Elite, and Fly climbing ropes. [slaice] offers its users several significant advantages over conventional splices or stitchings:
- Flexible: The end of [slaice] is about as flexible as a rope. Hence, it facilitates its installation in a cambium saver. The termination adapts perfectly to the rings and thus defines the direction of the pull. The lower pulling force makes the installation easier, as there will be no leverage effect caused by a stiffer splice.
- Slim: In the case of [slaice] , a thickened portion which normally occurs on spliced ropes is practically non-existent. The design of this innovative termination hardly exceeds the rope's diameter. The seam is made using TEUFELBERGER's standard [tnt] resin-based seam protector technology. The result of all these components is an easier handling of the termination.
- Doubled safety for thinner rope types (Tachyon und Fly):
The design of [slaice] makes it possible to carry a Dyneema strap along in the eye. This way, the load is not only carried by the sheath, but also by the inner Dyneema strap. The [slaice] termination complies with the requirements of EN 1891:1998 for Type A ropes.
- Compact: The seam of [slaice] is only 42 mm long, however, it still meets the requirements of EN 1891:1998 A. The length from the loop to the seam is approx. 100 mm. This results in a total length of approx. 142 mm. Compared to a conventional splice, this termination is several times shorter.
- Light-weight: The [slaice] technology helps achieve a weight reduction, as the amount of material is reduced compared to a conventional splice. This, in turn, contributes toward enhancing the safety for the work in trees.
Very little degradation from sunlight. Can be used outside over long term if inspected regularly.
Nylon will degrade with h3 oxidizing agents, mineral acids, and 90% formic acid. May discolor when exposed to high levels of carbon dioxide. Polyester has good resistance to most chemicals, except 95% sulfuric acid and h3 alkalines at boil. Polypropylene has excellent resistance to most acids and alkalines, except chlorosulphonic, concentrated sulfuric acids, and chlorinated hydrocarbons at 160 F. Additionally polypropylene withstands most diluted bleaching solutions.
Nylon melts at 460 F with progressive strength loss above 300 F. Polyester melts at 480 F with progressive strength loss above 300 F. Polypropylene melts at 300 F with progressive strength loss above 200 F.
Good resistance to the passage of electrical current. However, dirt, surface contaminants, water entrapment, and the like can significantly affect dielectric properties. Extreme caution should be exercised any time a rope is in the proximity of live circuits.
No blanket safe working load (SWL) recommendations can be made for any line because SWL's must be calculated based on application, conditions of use, and potential danger to personnel among other considerations. It is recommended that the end user establish working loads and safety factors based on best practices established by the end user's industry; by professional judgment and personal experience; and after thorough assessment of all risks. The SWL is a guideline for the use of a rope in good condition for non-critical applications and should be reduced where life, limb, or valuable property is involved, or in cases of exceptional service such as shock loading, sustained loading, severe vibration, etc. The Cordage Institute specifies that the SWL of a rope shall be determined by dividing the Minimum Tensile Strength of the rope by a safety factor. The safety factor ranges from 5 to 12 for non-critical uses and is typically set at 15 for life lines.
New England Ropes takes great pride in manufacturing the highest quality rope available. Below are a few guidelines regarding general care and usage practices which will help to extend the life of the rope while achieving the best possible performance.
Abrasion and Sharp Edges
Abrasion and sharp edges are a ropes worst enemies. Check all equipment prior to use to ensure there are no burrs or sharp edges. Always inspect ropes after climbing in abrasive environments to assess damage related to wear.
Dirt and Cleaning
Dirt on a rope can penetrate the cover strands resulting in abrasion in the core as well as the cover. Water facilitates the introduction of dirt particles into the rope.
After a climb, wash rope with fresh water and allow to air dry out of direct sunlight. For a more thorough cleaning, soak your rope in warm water mixed with a mild detergent. Add a small amount of fabric softener to soften the rope. When possible, use a front loading washing machine; wash your rope in a mesh bag or pillowcase to avoid tangling. Rinse thoroughly and hang to dry in indirect sunlight.
Twist increases the likelihood of kinking and jamming in equipment. Severe twist can cause the rope to get out of round, resulting in higher wear rates and reduced strength. Eliminating twist from a rope will make the rope easier to handle and extend its life. Eliminate twist by either laying the rope straight and coiling it into a figure eight hank, or by feeding it into a bag while the loose end remains free.
Snapback: An extremely hazardous situation can result if a rope parts under a heavy load. Rope can recoil at a high rate of speed and a person positioned in the path of a parted rope can be seriously injured. It is the responsibility of the user to know and understand the proper techniques for particular application and to take all necessary safety precautions.
Chemicals: Synthetic fibers have good chemical resistance. However, exposure to harsh chemicals such as acids and alkalis should be avoided. Damage: Inspect all ropes frequently for signs of wear or damage. Retire any rope that has been cut or abraded. Sunlight: Over time, all synthetic fibers will undergo degradation when exposed to sunlight. Polypropylene is more susceptible to UV degradation than other fibers.
Tensile strength is the load at which a new rope, tested under laboratory conditions, can be expected to break. Rope strength (as shown in our literature) is the approximate average for new rope tested under ASTM test method D-6268. To estimate the minimum tensile strength of a new rope, reduce the approximate average by 20%. Age, usage and the type of termination used will significantly lower tensile strengths.
The Cordage Institute specifies that the safe working load of a rope is determined by dividing the minimum tensile strength by the ropes safety factor. Safety factors range from 5 to 12 for non-critical uses. The working load is a guideline for rope in good condition used in non-critical applications and should be reduced where life, limb or valuable property are involved, or where exceptional shock, sustained loading, severe vibration, etc. may be experienced.
Strength in Every Strand: The Importance of Fiber and Construction
New England Ropes combines the highest quality fibers with the most advanced construction technology. Every rope we manufacture acts as an integral component of a complex system, each with different performance requirements.
for example, is recognized for its outstanding strength, elasticity and abrasion resistance. It is an ideal fiber for dynamic climbing ropes due to its ability to arrest a potential fall.
on the other hand, has high strength and low stretch characteristics which are well suited for static applications where bounce and stretch are not desirable.
Continual innovation of our extensive designs ensures we manufacture the appropriate products to support all of your climbing applications.
A flexible, supple construction that absorbs twist and resists kinking. Construction used in MFP Throwline and Treeline.
A braided cover surrounds a braided core, producing a rope designed for strength, durability, shape and easy handling. Construction used in static and specialty ropes, including Water Rescue Rope, Polyester Double Braid and NFPA Throwline.
A patented unidirectional fiber core with a braided cover, for a rope with lower stretch higher strength line than a double braid rope of equal size. Construction used in Tech Cord and PCRU.
Four-stage, balanced construction leveraged with an advanced stabilization process produces a durable, long lasting and flexible rope that wont harden with age. 3-strand rope is ideal for applications where grip, abrasion resistance and stretch are critical factors. Construction used in 3-Strand Safety Blue, 3-Strand Safety Blue Hi-Vee, 3 Strand Polyester, Filament Nylon and Multiline II and many of NE Ropes factory-spliced lanyards.
A braided jacket covers bundles of twisted, spring-like fibers. Designed to absorb energies generated by a fall, this rope is ideal for dynamic and static ropes that must remain firm and round, yet run freely through mechanical devices. Construction used in all of NE Ropes dynamic climbing ropes, specifically KM III, KMIII Max, Braided Safety Blue, Braided Safety Blue Hi Vee and Nylon Accessory Cords.