Factory supplied Strong magnet to Kuwait Factory
Customized any size 15 years experience Quality & Reputation concerned Coating : NiCuNi , Zn , NiCuNi+Sn ,NiCuNi+Cr ,NiCuNi+ Au By air ( magnet power shelding package ); By sea ( plastic sack package )
Factory supplied Strong magnet to Kuwait Factory Detail:
Customized any size
15 years experience
Quality & Reputation concerned
Coating : NiCuNi , Zn , NiCuNi+Sn ,NiCuNi+Cr ,NiCuNi+ Au
By air ( magnet power shelding package ); By sea ( plastic sack package )
Product detail pictures:
We are convinced that with joint endeavours, the small business between us will bring us mutual benefits. We could assure you products quality and competitive selling price for Factory supplied Strong magnet to Kuwait Factory, The product will supply to all over the world, such as: Germany , Niger , Mombasa , Since our establishment, we keep on improving our products and customer service. We are able to provide you with a wide range of high quality hair products at competitive prices. Also we can produce different hair products according to your samples. We insist on high quality and reasonable price. Except this, we provide best OEM service. We warmly welcome OEM orders and customers all over the world to cooperate with us for mutual development in the future.
Give your car a great custom look with custom length braided hose lines. Al shows you the basics of how to cut braided hose lines and place AN fittings on the ends. Just remember, before you start your project to gather all of the tools necessary:
Braided Stainless Steel Hose Cutter- http://www.summitracing.com/redirect?banner=SocialYT4518
Bench Vise AN Fitting Jaw Clamps- http://www.summitracing.com/redirect?banner=SocialYT4519
Braided Hose Line- http://www.summitracing.com/redirect?banner=SocialYT4520
AN Hose End Fittings- http://www.summitracing.com/redirect?banner=SocialYT4521
Read how it works here: http://muonray.blogspot.ie/2014/06/tractor-beam-laser-maglev-using-30m.html
Here we demonstrate an effect which looks like the classic “tractor beam” seen in science fiction films and tv shows. We have made pieces of thin graphene which can levitate over a bed of 1.2T rare earth permanent magnets and can be ‘pushed’ around or made to spin using a handheld, focusable 5mW 390-405nm laser beam.
The phenomenon demonstrates visibly how it is possible to convert light, either from a laser beam or focused sunlight, to kinetic and hence mechanical energy.
This demonstrates simple principles of transferring energy, as well as how motors and engines can operate on the principle of the magnetic spin degrees of freedom to create reversible heat cycles where no atoms or molecules are moved, offering a possible alternative way to harness solar energy.
It also demonstrates the principles of a maglev, how in certain materials diamagnetism can be used to levitate objects off a track of magnets.
Considering that this principle works at room temperature, unlike current high temperature superconductors, it could be useful as an easy demonstration kit in schools as no cooling liquid, such as liquid nitrogen, is needed.
By depositing ferromagnetic nanoparticles on the graphene thin films it was also found that the films could bend in exposure to the UV light and return to their original position when the exposure stopped, demonstrating a weak hysteresis in the material for potential use as a optical memory material.
The fact that a low-powered laser can move the graphene from a reasonable distance in a vacuum could mean it could become a practical tool for movement of thin films of grapheme for manufacturing purposes in the not too distant future should graphene become useful in industrial and consumer electronics, replacing silicon as a transistor material in the not-too-distant future.
Although the band gap in graphene cannot be controlled as easily as it can be in silicon, hence the universality of silicon in transistor and memory technology, researchers are working on ways to create a stable bandgap in graphene via doping and structuring of deformations in thin films of the material. Due to the thin nature of the films, robotic tweezers used for holding silicon wafers are relativtive clumsy devices for holding thin films. Hence, using lasers to transport the films at least on assembly lines fitted with magnets could be an attractive way to avoid damaging fragile circuitry etched on the graphene paper. Other functions, such as frictionless motors guided by lasers, may also be applicable from this technology.