Carbon Nanotube Will Light Up Your Garage

In the car of the future will not be made of steel or aluminum, and even there are so many high-tech plastic Laden. Originally, CNTs Oil Dispersion, when it comes to steel, 50 times of carbon nanotubes are lighter and stronger. Interestingly, they also for power generation, which means it will change as the object, it illuminates not to use too much energy easily. Well, let us be on carbon nanotubes body future conversation.

Although it is not scheduled for discussion at the “Strategies in Light 2013” symposium it appears to me that many of the top automotive innovators are missing some of the future competition in material science. Right now, many cars are being outfitted with LED headlights, and I’m sure you’ve seen how bright they are, or how bright the taillights are when they light up as you’re driving. Some of the younger generation now, put LED lights on the bottom of their cars which looks very cool, merely for affect.

Still, imagine your car is in a parking lot and you can’t find it. Rather than hitting the car alarm and listening for that chirp, chirp – you can have your car light up the parking lot, and even glow-in-the-dark. This might also be good in your garage. You will not need to replace that light bulb on your Geenie garage door opener when it goes out. All you need to do is hit the alarm disarm button, and the car itself, that is to say the car body will light up your garage for you. Best of all, it will hardly take anything away from your battery, as far as energy is concerned.

Some might say; that’s crazy – but that’s only because they do not understand all the characteristics of these new materials. In fact, the hood over your engine, or your trunk may go opaque while driving, but when you hit a button it becomes transparent so you can see in. In fact, the whole body of the vehicle can be created that way as well. Border crossings for trucks may require that trailers in the future are built of carbon nanotube not only so the trucks get better fuel mileage, but also so that border patrol inspections become very easy to conduct.

If you want to discuss all of this in a higher level, you can contact us think-tank, or shoot me an email. As our car carbon nanotube and cross-country truck will be a reality over the next 5 to 10 years. This will improve fuel mileage, and allow us to many other benefits including I just discussed today. I beg you to consider it.

Tungsten Carbide Cobalt Nanopowder Insert Recycling

Tungsten carbide cobalt nanopowder, also known as cemented carbide, is a relatively precious material which is critical to many manufacturing processes. Metal machining process must use tungsten carbide insert tool tip AS, AS hard alloy hardness and wear resistance of a hot ideal shaping, boring, and the metal workpiece. Face Mills the most modern, tool and cutter old lathe used for cutting tools.

The only downside of using carbide inserts for such a wide range of machining processes is that the tungsten material used in creating tungsten carbide alloys is both scarce and expensive. With most tungsten reserves in the US and other Western countries exhausted, China supplies over 80% of the tungsten used worldwide. In 2005, the International Tungsten Industry Association estimated that at the current rate of global consumption, all tungsten reserves will be used up within 140 years. Tungsten carbide inserts are typically treated as disposable materials, even though only the cutting edges of the inserts are worn when they’re disposed.

Rather than disposing of inserts, many manufacturers are turning to recycling companies which purchase used tools.

Why Recycle Carbide Inserts?

Financial Benefits

Tungsten carbide is an expensive material, and most recycling companies are willing to pay for used scrap. By turning used inserts over to recycling facilities, manufacturers can recoup at least a portion of their expenses, lowering their overall material costs. Rates for scrap tungsten carbide fluctuate widely, depending on current market values.

Environmental Benefits

Because carbide inserts contain heavy metals, disposing of them in traditional ways can be quite harmful to the environment. Heavy metals may leech into the soil over time, contaminating ground water. By recycling these, these harmful effects can be largely avoided and global tungsten reserves can be preserved for future generations.

How to Find a Tungsten Carbide Insert Recycling Facility

As more manufacturers are becoming aware of the financial and environmental benefits of recycling inserts, more and more carbide scrap recycling facilities are becoming available around the world. Major worldwide toolmaking companies, including Sandvik Coromant, Kennametal and ATI Stellram, offer their own recycling services for customers. While these companies typically offer recycling services to their own customers, they generally offer a reimbursement for the carbide scrap.

Independent tungsten carbide insert and scrap recycling facilities offer an alternative which in many cases may be more financially beneficial to manufacturers. Carbide recycling providers such as Carbide Recycling Company and Machine Tool Recyclers, Inc. tend to offer the highest and most recent going rate for tungsten carbide, so manufacturers may get more in return for their scrap carbide.

Another option is to require manufacturers and their suppliers to help find the best hard alloy recyclers. Some manufacturers may provide internal circulation, or may have some other use of the waste. Turning with carbide blade back to their interests of suppliers, manufacturers can get a credit for future procurement suppliers.

Conductive Silver Powder Common Sense

Conductive Silver Powders are the production of electronic paste, conductive silver paste, LED epoxy conductive adhesive, the main raw material of electromagnetic shielding coatings, conductive coating, conductive ink, conductive rubber, conductive plastics, conductive ceramics etc..

 

According to the use conditions of selection of different silver products, ultrafine silver powder is mainly used in high temperature, conductive paste and electrode paste, silver conductive paste is widely used in capacitors, resistors, potentiometers, thick film hybrid lumped circuit, each field sensitive element and the surface mount technology such as the electronics industry. Flake silver powders are mainly used for low temperature polymer paste, conductive ink, conductive coating.

 

Sheet / spherical silver plated copper powder as a can with the traditional pure silver performance equivalent model of high conductive material, add it to the coating (paint), glue (adhesive), ink, plastic, rubber polymer slurry, etc., can be made of a variety of electrical conductivity, electromagnetic shielding products, widely used in electronics, electrical, communication, printing, aerospace, weapons and other various industrial sectors, electromagnetic shielding conductive fields. Such as computer, mobile phone, electronic medical equipment, electronic instruments and other electronic, electrical, communications products, electromagnetic shielding conductive.

 

Conductive Silver Powder is the T3-T30 powder Market representative, has good conductivity, 3M test off powder, resistance is less than 0.5 /10cm/15 m silver content of 3%5%10%15%20% powder delicate, silver copper powder particle size according to customer requirements of some high silver content of ultrafine silver copper powder can be added according to a certain proportion of conductive paint made in sterling silver powder, conductive silver paste, conductive adhesive, conductive printing ink, cost advantages, the use of non cyanide electroless plating process, developed a good electrical conductivity of silver plated copper powder, the powder volume resistivity of less than 2 x 10-3 Omega cm, conductive coating made from the powder as filler, high conductivity (conductive filler and resin weight the ratio of 75 to 25, the volume resistivity is 5 * 10-3 Omega cm) anti migration ability (increased nearly 100 times than the ordinary silver conductive coating (60 DEG C) conducting stability by relative humidity 100% damp heat test for 1000 hours, the volume resistivity increased less than 20%)