martes, junio 10, 2014

inteligencia y estupidez humanas / Madera màs fuerte que el acero


The Coca-Cola Bio cooler from Leo Burnett Colombia on Vimeo.

nevera ecològica con el sol y las plantas.

aprende hijo !

Prueba de un Drone de la Marina Portuguesa


Pillado por hacerse un selfie mientras roba y compartirlo con los amigos de la víctima
Está Pasando - 23/03/2014 - 11:50

CÁDIZDIREC TO.- Entra en casa ajena, roba y no tiene nada mejor que hacer que compartir una foto que se hizo en la casa con los amigos de la víctima. La cantidad saqueada ascendía a 27.000 dólares, cantidad que se ha conseguido recuperara cuando los amigos de la víctima dieron a la policía la voz de alarma.

Ashley Keast, de 25 años, hizo todo lo posible para ser cazado. Después de irrumpir en un domicilio de Rotherham (Inglaterra) del que robó 27.000 dólares, tomó un selfie utilizando un teléfono con una tarjeta SIM robada y envió a los amigos de la víctima la imagen. Los amigos avisaron de inmediato a la policía y el ladrón fue detenido en su casa al día siguiente.

Esta semana ha sido encarcelado después de que el juez le condenara a dos años y ocho meses de cárcel tras admitir el robo. Keast contaba con un cómplice, Anthony Hunt de 27 años, que fue encarcelado durante 18 meses por el mismo delito.


Biodegradable fibers as strong as steel made from wood cellulose

By Colin Jeffrey June 9, 2014

Fiber made from cellulose claimed to be as strong as steel

A team of researchers working at Stockholm's KTH Royal Institute of Technology claim to have developed a way to make cellulose fibers stronger than steel on a strength-to-weight basis. In what is touted as a world first, the team from the institute's Wallenberg Wood Science Center claim that the new fiber could be used as a biodegradable replacement for many filament materials made today from imperishable substances such as fiberglass, plastic, and metal. And all this from a substance that requires only water, wood cellulose, and common table salt to create it.

To produce the new material, the team took individual cellulose fibers and broke them down into their component strands or "fibrils." They then separated and re-bound these fibrils in a technique that results in filaments much stronger than the original fiber. While fibrils have been separated in other studies – and even used in strengthening composite materials – it is the recombining of these fibrils into a super-strong filament that has never been achieved before and is asserted to be a considerable breakthrough in this type of research.

"We have taken out fibrils from natural cellulose fibers, then we have assembled fibrils again into very strong filament," said Fredrik Lundell, one of the researchers. "It is about 10 to 20 microns thick, much like a strand of hair."

The team constructed a "flow-focusing" device (similar to a small-scale extruder) to reassemble the fibrils after they had been mixed with water and sodium chloride. Controlling their reassembly by carefully adjusting the pressure at which they were injected, the researchers were able to produce continuous, consistent strands of fiber from the fibrils.

In this process, the way that they manipulate the angle at which the fibrils are brought together then determines the strength and stiffness of that fiber. For example, if the fibrils are aligned alongside each other, the material is rigid and inflexible, whereas if the fibrils are combined at angles to each other, the resulting material is more elastic and flexible.

The useful upshot of this is that the fibrils can be used to produce not only strong, steel-like fibers, but more fibrous ones as well. As a result, wood cellulose could be made to replace cotton in textiles, or even be used as a substitute for the glass filaments used in fiberglass used to construct boats and cars. And, as the new material retains its original cellulose, it is still biodegradable just like the wood it came from.

"Our research may lead to a new construction material that can be used anywhere where you have components based on glass fibers, and there are quite a few places," said Lundell. "The challenge we face now is to scale up the production process. We must be able to make long strands, many threads in parallel – and all this much faster than today. Nevertheless, we have demonstrated that we know how this should be done, so we've come a long way."

The work was carried out in cooperation with Deutsches Elektronen-Synchrotron elektronsynkrotronen (DESY) in Hamburg, Germany, with the research findings published in the scientific journal Nature Communications.

Photos: KTH

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