Reduce Dysprosium (Dy) percentages from Neodymium magnets (Nd2Fe14B)

About reduction Dysprosium (Dy) percentages from Neodymium Magnets (Nd2Fe14B)

Couple of days ago, i got a question for hot topic referring to what are the best relatively possible ways to reduce dysprosium (Dy) percentages from Neodymium magnets (Nd2Fe14B), actually for this question there were researches and practices for a long time and seems will last further and further as it is a moving target. From Quora I see an engineer who replied this question very professionally so i'd like to recommend it for your consideration. 

There are a number of different methods to reduce Dy use in rare earth magnets:

• Reduce grain size. Dy is added to increase coercivity (it’s naturally higher in that quality than Nd). But NdFeB depends on the domains at the grain wall for its coercivity (known as “pinning”) so if you just reduce the grain size the alloy will naturally increase in coercivity. But “just” reducing the grain size while keeping the other qualities that make the alloy useful is a highly non-trivial challenge. This method will save Dy but not necessarily cost.
• Grain boundary diffusion. Rather than adding Dy to the melt at the beginning of the manufacturing process, you can add it at the end by exposing the finished magnet to Dy in a bath or atmosphere. This works but the size and shape of the magnet are limited and it’s an extra step that so far can produce variable results.
• Terbium. Use Tb instead of Dy. Tb has even higher coercivity than Dy. But it’s even more expensive.
• Redesign the magnet to have a higher permeance coefficient. Then it won’t need as high a coercivity. This can save both cost and Dy, but it’s not always possible.

These are just examples from current technology. There are other methods. Dy reduction is an active area of research and thus a moving target.
From https://www.quora.com/What-is-the-best-possible-way-to-reduce-Dysprosium-Dy-percentage-from-the-Neodymium-Nd2Fe14B-magnets  

Magnetic water conditioner/Halbach Array

Regularly we see a magnetic water conditioner including two magnets with opposite magnetic poles face-to-face cliped together, just simply clip them together onto the water pipes will get a magnetized water resulting from flowing water cutting the magnetic filed. The advantages are low cost and simple operation but the only disadvantage is weak magnetic field due to attraction by those two magnets. When using this device, we have to pay attention that better clip it to the plastic pipes or stainless steel or copper pipes but not on iron pipes.

               

The magnetic water conditioner with single magnetic pole technology is of higher effecient and bigger room of application. While as we all know it is rather hard to achieve single side magnetism, for all magnets are with two oppisite magnetic poles, so we have to achieve it by some special design and structure. The structure is based on some particular magnetic array to achieve concentration of magnetic force, it will get better penetration in compare with normal two poles magnets. As follows is a Halbach array that will help us to get single side magnetism by concentrating magnetic force on one side. According to actual application, we can range magnets in a line and in a circle.

           
                                                  (bar halbach array)                                             (circle halbach array)

For Bar halbach array and circle halbach array we can findout the magnetic field distribution respectively as follows:

      

From the above photos we can findout that if we use circle halbach array, 90% magnetic force can be concentrated inside the circle, this will get better water magnetization. The magnetic water conditioner with this technology has much higher efficient and powerful cleaning ability, especially in agriculture, it has much bigger room than regular magnetic water conditioner.

MaximMAG is able to make every kind of Halbach Array in straight line or circle forms, welcome your inquiries to SALES.

Ther pictures are from google. 

Neodymium magnets for Wheel-hub motors

You may come to know nowadays China is no longer a country of bicycles but a country of electric-scooters or electric motor-cycles, because no matter you're in 1st tier cities such as Beijing/Shanghai/Guangzhou or 6/7/8 tier cities, you can find yourself envolved in a mass crowd of electric-sceeters and hardly find enough space for automobiles to squeeze into. 

   

（from blog.sina.com.cn)

Just because of such kind of savage growth of electric-scooters, the requirments of Neodymium Magnets from this industry boomed, however, as every other new innovative and propective industry of low entry threshold in China, manufacturer of electric bicycles enter a fierce competition of price period of times, so now you can easily find piled of non-coated small block magnet blanks in small factories of NdFeB magnets ready to deliver to assembly lines of those manufacturers of electric bicycles. "Why non-coated" you may ask "they must be corrode without any coating to protect it", yes, it's because of the cost.

 (Direct drive electric wheel-hub motors from google.com)

MaximMAG makes Neodymium block magnets/arc shape magnets for high end electric-scooters/electric racing motors, as follows is Neodymium magnets we made for wheel-hub motor of a top-brand racing project.

  

MaximMAG is willing to be of good help to your project in electric motors, any further inquiries welcome contacting SALES.

Neodymium Block magnets

Do you want any block magnets for your applications, welcome your visiting to our company website for more information referring to our neodymium block magnets.

http://www.maxim-magnet.com/en/products.php?tid=38 

Penn Research Simplifies Recycling of Rare-earth Magnets

Despite their ubiquity in consumer electronics, rare-earth metals are, as their name suggests, hard to come by. Mining and purifying them is an expensive, labor-intensive and ecologically devastating process.

Researchers at the University of Pennsylvania have now pioneered a process that could enable the efficient recycling of two of these metals, neodymium and dysprosium. These elements comprise the small, powerful magnets that are found in many high-tech devices.

In contrast to the massive and energy-intensive industrial process currently used to separate rare earths, the Penn team’s method works nearly instantaneously at room temperature and uses standard laboratory equipment.

Sourcing neodymium and dysprosium from used electronics rather than the ground would increase their supply at a fraction of the financial, human and environment cost.

The research was lead by Eric J. Schelter, assistant professor in the Department of Chemistry in Penn’s School of Arts & Sciences, and graduate student Justin Bogart. Connor A. Lippincott, an undergraduate student in the Vagelos Integrated Program in Energy Research, and Patrick J. Carroll, director of the University of Pennsylvania X-Ray Crystallography Facility, also contributed to the study.

It was published in Angewandte Chemie, International Edition.

“Neodymium magnets can’t be beat in terms of their properties,” Schelter said. “They give you the strongest amount of magnetism for the smallest amount of stuff and can perform at a range of temperatures.”

These thermal qualities are achieved by mixing neodymium with other elements, including the rare-earth metal dysprosium, in different ratios. Because those ratios differ based on the application the magnet is being used for, the two metals need to be separated and remixed before they can be reused.

“It’s, in principle, easier to get the neodymium and dysprosium out of technology than it is to go back and mine more of the minerals they are originally found in,” Schelter said. “Those minerals have five elements to separate, whereas the neodymium magnet in a wind turbine generator only has two.”

Currently, whether purifying the neodymium and dysprosium out of minerals or out of an old power tool motor, the same costly and energy-intensive process is used. The technique, known as liquid-liquid extraction, involves dissolving the composite material and chemically filtering the elements apart. The process is repeated thousands of times to get useful purities of the rare-earth metals, and so it must be conducted on an industrial scale.  

Rather than this liquid-liquid method, Schelter’s team has devised a way to separate the two metals. 

"When we started," Bogart said, "our goal was to make rare earth separations simpler and more efficient and we have made strides towards just that. We have designed a way to separate the two metals by selectively dissolving the neodymium in a solution and leaving behind the dysprosium as a solid. This quick and easy method has allowed us to separate equal mixtures of the metals into samples that are 95 percent pure."

Their method can, in a matter of minutes, separate an equal mixture of the two elements into samples that are 95 percent pure.  

Starting with the two elements as a mixed powder, a metal-binding molecule known as a ligand is applied. The type of ligand the research team designed has three branches, which converge on the metal atoms and hold them in the aperture between their tips. Because of neodymium’s slightly larger size, the tips don’t get as close together as they do around dysprosium atoms.    

“The difference in size between the two ions is not that significant, which is why this separation problem is difficult,” Schelter said, “But it’s enough to cause that aperture to open up more for neodymium. And, because it is more open, one ligand-neodymium complex can combine with another, and that really changes its solubility."

The combination of the two neodymium complexes, known as a dimer, encapsulates the neodymium ions, enabling them to dissolve in solvents like benzene or toluene. The dysprosium complexes do not dissolve, enabling the two metals to be easily separated. Once apart, an acid bath can strip the ligand off both metals, enabling it to be recycled as well. 

"If you have the right ligand, you can do this separation in five minutes, whereas the liquid-liquid extraction method takes weeks,” Schelter said. “A potential magnet recycler probably doesn’t have the capital to invest in an entire liquid-liquid separations plant, so having a chemical technology that can instantaneously separate these elements enables smaller scale recyclers to get value out of their materials."

Future work will involve improving the stability of the ligand so it is less likely to fall off before the metals are separated.

"These results are encouraging," Bogart said. "We feel that through slight adjustments to the system, the purity level could be increased even further."

Further modification of the ligand could enable other rare earths in technology products, such as compact fluorescent light bulbs, to be recycled this way.

The research was supported by the Early Career Research Program of the U.S. Department of Energy’s Office of Science and the Research Corporation for Science Advancement.

From http://www.upenn.edu/pennnews/news/penn-research-simplifies-recycling-rare-earth-magnets Media contact: Evan Lerner

Pot Magnets in different caps may to your satisfactory.

You can find Pot magnets with/without hooks, with inner thread or male thread, with countersunk hole magnets/straight hole magnets etc. in MaximMAG certainly.

Do you want any magnetic darts together with magnetic dart board for playing

MaximMAG got a new hot selling playing product: Magnetic darts and magnetic dart board, eco-friendly, toy easy for children to play with.