The new Velcro: Metaklett
Over 60 years ago, when the Swiss engineer and inventor George de Mestral painstakingly removed burrs from his dog’s coat after a hunting excursion, he stumbled on an ingenious idea. Based on the model he observed in nature, he constructed a fastener from numerous small hooks and loops, which he subsequently named Velcro.
“The unbeatable advantage of a hook and loop fastener is that it is easy to close and open again,” said Josef Mair, a scientist from the Institute of Metal Forming and Casting (utg) at Technische Universitaet Muenchen. Because of this, the hook and loop principle is put to a very wide range of uses, e.g. as an alternative to shoe laces, to secure medical bandages and prostheses, and for the cable boots used in automotive and aviation electronics.
A steely hook and loop fastener can hold up to 35 metric tons per square meter.
Unfortunately, standard synthetic hook and loop fasteners are not very resistant to heat and aggressive chemicals.
“Things can get very hot, for example, in the automotive sector,” Mair said. “A car parked in direct sunlight can reach temperatures of 80°C, and temperatures of several hundred degrees centigrade can arise around the exhaust manifold. Aggressive disinfectants are used for cleaning purposes in hospitals, and traditional hook and loop fasteners are too weak for use in the construction of building façades.”
Under the leadership of Professor Hartmut Hoffmann and as part of a joint project launched in 2005 with the German Federal Ministry of Education and Research in close cooperation with partners from industry, the utg developed a solution: Metaklett, the hook and loop fastener made of steel.
Temperatures in excess of 800°C and aggressive chemical solutions do not pose any problem for Metaklett, which also offers adhesive strength of up to 35 metric tons per square meter when applying tensile force parallel to the fastener surface. When applied perpendicular to the fastener surface, Metaklett can still withstand a force of seven metric tons per square meter. Moreover, like a standard Velcro fastener on a child’s shoe, you can open it and close it again without the help of any tools.
Researchers used spring steel, which unites high ductility with high strength, as the material for their fastener. They created various 3-D models for the optimum interlocking of the fastener elements on the computer. They then built the most promising candidates as prototypes and subjected them to comprehensive tests. They tested on the computer 40 variations of the geometry referred to as “Flamingo.” Researchers studied its adhesive strength and reaction to extreme temperatures to establish the limits of its resilience.
Two of the tested models ultimately made the grade: a spring lock, the Flamingo, and a hook and loop system known as the “Entenknopf” (“duck’s head”). Both consist of 0.2-mm-thick hook tape and loop or perforated tape of the same thickness. The “duck’s head” model consists of the traditional synthetic hook and loop system. Numerous delicate steel hooks can attach at any angle to the loops in the perforated metal loop tape.
The second variant, the Flamingo, is even more stable. It consists of wider hook elements that snap into the openings in a perforated tape. They bend in such a way that they deform elastically under light pressure and glide into the holes like the synthetic buckles on backpack straps. Once inserted, they return immediately to their original form, and thanks to their sprung splaying arms, they resist back pull like an expanding rivet.
In order for the hooks to be able to snap into place, they must first, however, be at the correct angle, that is parallel or perpendicular to the perforated tape. Depending on the direction of the applied force, this fastener can withstand a load of 7 to 35 Newtons per square meter. Following an initial loss of around 20% during the first 10 tests, the adhesive strength remained constant in the numerous repetitions.
“The animal names arose as a way of differentiating between the multifaceted models. The hook forms of the two systems are vaguely reminiscent of a duck’s head and a flamingo standing on one leg,” Mair said. Scientists have also come up with a third alternative, the “hybrid” model, which combines a steel hook tape with a synthetic loop tape and is suitable for the secure and reversible fastening of textiles.
Metaklett is suitable for use in all areas that require easily opened but stable fasteners, for example air-conditioning and ventilation systems in building services engineering and automotive construction.
For related information, go to www.isa.org/manufacturing_automation.