in magnetic separation magnets are used to separate

what are the applications and types of magnets in industry? - industrial news - news - xiamen bearheart imp & exp co.,ltd

Magnets are not only used in toys, electronics, and motors. They also have many applications in industry and commerce. From medicine, manufacturing to heavy industry, magnets are used in a wide range of applications. Today, lets talk about the applications and types of magnets in industry.

Magnetic cleaners are used to remove potentially harmful metal objects from the work area, thereby helping to reduce maintenance costs. They are like a magnetic broom, preventing tires from being punctured on loading docks, driveways and airport runways. They can also help clean up employee work areas and remove metal that may be stepped on on the floor. .

Magnets can also be used to separate magnetic materials from non-magnetic materials. Magnets are used in the mining industry to separate metals and ores. Food manufacturers use magnets to prevent small iron particles from mixing with food. Similarly, vendors use magnets to combine coins with Separate other garbage. The food production and pharmaceutical industries also extensively use magnetic technology to remove excess iron, which would otherwise contaminate their products.

The types of magnets widely used in various industrial applications include neodymium iron boron, samarium cobalt, ferrite, electromagnet, funnel magnet, pot magnet (pot magnet), rubber magnet, sheet magnet, etc.

importance of magnetic separation | bunting magnetics co

What makes food safe to eat? How are recycling companies actually able to recycle? How are grains kept pure? How is processing equipment protected from damaging metals? How are millions of products kept safe for consumers all over the world? It has nothing to do with Superman leaping tall buildings. The answer to these important questions is simple its because of magnetic separation!

Magnetic separation has changed the world, and is responsible for product and food safety standards that we sometimes take for granted. Thanks to the innovations of magnet applications, we are able to eat food and use products that are free of dangerous materials. Magnetic separation also protects your equipment from serious damage by keeping the line clear of hazardous metal scraps. Whether youre in the Food, Dairy, Grain and Milling, Chemical, Plastics, Oil, Textile, Recycling, Powder and Bulk, Mining, or the Non-Woven industries, magnetic separation applications are crucial to the success of your business.

Through the use of magnets, you are able to separate hazardous metals from your product before its shipped to consumers. This is extremely important for a number of reasons. When tramp metals are found in product and food, it can result in potential lawsuits, product recall, negative press, and severe injury to customers. Fortunately, this can all be avoided by investing in the right magnetic separation applications. The magnet separator you choose will depend on the type of material being processed and the system you are running the material through. Each system and product is unique, which means there is no one size fits all solution when it comes to magnetic separation.

The type of magnet material you choose is determined by the density of the product, its flow rates, operating temperatures, and the types of ferrous contaminants you are trying to remove. Ceramic magnets are generally used for typical tramp iron separation, while alnico magnets are better suited for high operating temperatures.

Rare earth magnets are used when product densities and flow rates are high, and encounter weakly magnetic debris and grades of work-hardened steel. Types of rare earth magnets that are used for permanent magnetic separators include: Neodymium, Samarium Cobalt, and Ceramic Ferrite. Neodymium rare earth magnets are the strongest available, and are used to remove fine iron and stainless steel. Samarium cobalt magnets are smaller, slightly weaker, and can withstand higher temperatures. Ceramic ferrite magnets are lower strength, but produce deep magnetic fields. This makes them perfect for designs where the magnetic field needs to be projected at a distance.

There is a wide selection of magnetic separators that are used in the following industries: Recycling; Aggregate, Mining and Minerals; Grain and Milling; Food Production; Plastics; Non-Woven; and Powder and Bulk. Choosing the right magnetic separator will depend on the type of material being processed and the system you are running the material through.

Drawer Magnets are ideal for gravity flow applications and are used for easy-flowing, dry material. They are typically used in the Recycling, Food, Powder and Bulk, and Plastics industries to remove fine tramp metal contaminants. Drawer magnets are available in utility, food, and sanitary construction grades with multiple cleaning options and stainless steel housings.

Drum Magnets are used for a wide range of free-flowing bulk and granular materials in high-volume applications. They provide continuous removal of ferrous contaminants, and are used in the Plastics, Recycling, Grain and Milling, Powder and Bulk, and Aggregate, Mining and Minerals industries.

Plate Magnets remove hazardous materials from powdery, moist, lumpy and abrasive products, as well as from large debris that might choke, bridge, or cause rapid wear in cartridge-based separators. Ideal for gravity free-fall applications, plate magnets can be easily installed in chutes to remove ferrous fines and large pieces of tramp iron. Plate magnets can also be installed above or below conveyor drive pulleys to capture contaminants as materials drop from open belts. They are used for handling more abrasive products, and are often used in the Plastics, Recycling, Food, Grain and Milling, and Powder and Bulk industries.

In-Line Magnets are designed for unobstructed product flow. They are usually equipped with rare earth magnets and are best used for products with slightly clumpy flow. In-line magnets are typically used in the Plastics, Recycling, Food, Grain and Milling, and Powder and Bulk industries.

Magnetic Liquid Traps remove ferrous tramp metals from liquid processing and conveying lines. They are often used in the Food, Grain and Milling, and Powder and Bulk industries, and provide protection against product contamination. Magnetic liquid traps can handle acidic food products, and remove the smallest ferrous particles from liquids with a higher viscosity.

Hump Magnets are used for high-volume product flow in the Food, Grain and Milling, Powder and Bulk, and Non-Woven industries. They increase protection against entrapped ferrous materials, while helping prevent build-up and bridging of larger products.

Grate Magnets are used in applications for the Plastics, Food, Grain and Milling, and Powder and Bulk industries. They can be installed in hoppers, pits, chutes, housings, and bins to remove tramp metals from larger flowing materials.

Wedge Magnets are installed in narrow, vertical, or steeply inclined chutes in gravity flow applications. They protect pellet mills and other equipment from damage caused by tramp metals. Wedge magnets are used in the Grain and Milling industry to process particulate or semi-solid materials.

For more information about which magnetic separators are best for your application, please contact Bunting to speak with a sales representative. We look forward to hearing from you and discussing how our magnetic separation products can help your business succeed!

magnetic separation of particles and cells in ferrofluid flow through a straight microchannel using two offset magnets - sciencedirect

We develop a simple diamagnetic particle and cell separation technique in ferrofluids.Two offset magnets are used to achieve a sheath-free continuous separation in a straight microchannel.The technique is demonstrated through the magnetic separation of polystyrene particles and yeast cells.The effects of ferrofluid speed and magnet-channel distance are examined on particle separation.The predictions from an analytical model agree with the experimental data quantitatively.

The separation of particles and cells is critical in many chemical and biological applications. This work presents a simple idea for utilizing a pair of permanent magnets to continuously separate diamagnetic particles and cells in ferrofluid flow through a straight microchannel. The first magnet is placed close to the microchannel for focusing the particle mixture to a single stream without the use of a sheath flow. The second magnet, which is offset from the first magnet and placed farther from the channel, is to displace the aligned particles to dissimilar flow paths for a continuous sorting. This idea is first demonstrated through the separation of 3m- and 10m-diameter polystyrene particles, where the effects of flow speed and magnet distance are both examined. The experimental data are found to fit well with the predictions of an analytical model. Furthermore, a continuous separation of live yeast cells from 10m polystyrene particles is implemented in the same device.

magnetic separation technology for a recycling industry

Magnetic Separation is the process, in which the magnetically caused material is detached easily by using a magnetic force. From last many years, magnetic separators are used for various separation process in recycling industry like Glass recycling, Scrap material, Pet flakes, Plastic recycling, Rubber recycling, Municipal solid waste (MSW), e-waste recycling etc.

Magnetic Separator is the most trusted machine used to recover metal from the waste materials. It is known for the easy separation process to detach fine particles which have poor magnetic properties. Magnetic separator provides the excellent separating effect, as it uses dynamic magnetic system design. Recycling industries are using magnetic separator because of its various advantages like large handling capacity, low maintenance rate, simple structure and adjustable magnetic field intensity.

Eddy Current Separator is the most trusted separator, used to segregate valuable non-ferrous metals like aluminium, brass, copper, lead etc. It has an advantage of high frequency and high separation capability. Eddy Current Separator is robustly constructed with anti-vibration pads and its powerful quality of magnets provides the best and smooth separation for the recycling industry.

It has a capacity from 2MT/hr to 15MT/hr. Eddy Current provides its best separation service in various fields of recycling industry like plastic, rubber, glass, municipal solid waste, e-waste, pet etc. And the industries can take a huge advantage of using eddy current separator for their current application.

Overband Magnetic Separator is known for providing the excellent service of separating tramp iron from the material that is being processed on the conveyor belt or a vibratory feeder. Overband magnetic separator is used to protect machines like crushers, shredders by removing ferrous particles and it easily removes the heavy dust particles. It is used in many industries like food, sponge iron, charcoal, glass etc.

Specially designed Magnetic Head Pulley to detach tramp metals like steel, bucket teeth, bore crowns, bar scrap, chains, and tools. Recycling industries are using Magnetic Head Pulleys to segregate steel, municipal waste and many other ferrous contaminations like cans, nuts, nails etc.

From last many decades, Manufacturing industries are playing a most crucial role in our global economy. They are trying to develop high capacity and high-frequency pumps for the recycling industry, because theyre facing an issue of sorting recyclable material by removing various tramp metals like steel, bucket teeth, bore crowns etc.

Machines are not able to provide the best separation solution in the various field of recycling industry like plastic, rubber, glass, municipal solid waste, e-waste, pet etc. After facing these all issues regularly they are looking for high capacity which is having high-intensity magnets to remove impurities easily.

Jaykrishna magnetic Pvt. Ltd. understands all problems that the industries are facing now!!! We design a machine which is of high capacity that easily recovers metal from the waste materials. Our machines are evolved by using the latest technology that can be easily operated and to provide best separation results in various fields of the recycling industry.

We are famous for manufacturing and supplying magnetic separators which is of high capacity that easily provides the perfect separation solution. Jaykrishna Magnetic Pvt. Ltd. has 38+ years of experience in developing machines which are highly efficient and easy to handle.

Our magnetic separators are designed by the team of experts who have a great knowledge of designing and developing various types of magnetic separators and vibratory equipment. Our experts take care of clients need, before supplying any machine to them.

Our machines are installed in various fields of recycling industry like plastic, rubber, glass, municipal solid waste, e-waste, pet etc. We also design different types of magnetic separators like Eddy current separators, Overband Magnetic Separator and Magnetic Head Pulley as per the clients requirement to deliver them a best product.

If you are facing a problem of extracting tramp metals steel, bucket teeth, bore crowns etc. then feel free to contact us. Our team will get back to you with the best and effective solution that solves your problem.

Jaykrishna Magnetics Pvt. Ltd. is the leading manufacturer and exporter of Magnetic and Vibratory Equipments in India. We are established since 1978. The unique and premium structural design imparts quality and elegance to our products. Our focus is on continuously improving our process, service and products to exceed the benchmarks set by our competitors and offer better products to you.

on magnetophoretic separation of blood cells using halbach array of magnets | springerlink

Magnetophoretic separation has gained much attention in recent years due to its easy application and low-cost fabrication compared to other active particle separation techniques. Due to the different properties of white blood cells (WBCs) and red blood cells (RBCs), it is possible to manipulate and separate them using a magnetic field. In this paper, a simple microfluidic device is proposed to fractionate WBCs and RBCs from whole blood using magnetophoretic force applied by Halbach array of three permanent magnets. Plasma streams containing WBCs and RBCs enter a simple microchip fabricated by PDMS. Permanent magnets apply positive and negative magnetophoretic forces to the RBCs and WBCs, respectively. Two cladding streams containing blood plasma are used to concentrate the cells in the magnetophoretic area. A wide range of inlet velocities and different distances of magnets from the channel (d) are investigated. It is demonstrated that the volume flow rate of core, and cladding streams, total flow rate and the distance between magnets and microchannel affect the separation efficiency individually. The results reveal that d=0.1, 0.2, 0.3, 0.4, and 0.5mm may lead to complete separation when core and cladding flow rates are 1 and 7l/h, respectively.

Yan S, Tan SH, Li Y, Tang S, Teo AJ, Zhang J, Zhao Q, Yuan D, Sluyter R, Nguyen N-T (2018) A portable, hand-powered microfluidic device for sorting of biological particles. Microfluid Nanofluid 22(1):8

Dincau BM, Aghilinejad A, Hammersley T, Chen X, Kim J-H (2018) Deterministic lateral displacement (DLD) in the high Reynolds number regime: high-throughput and dynamic separation characteristics. Microfluid Nanofluid 22(6):59

Mizuno M, Yamada M, Mitamura R, Ike K, Toyama K, Seki M (2013) Magnetophoresis-integrated hydrodynamic filtration system for size-and surface marker-based two-dimensional cell sorting. Anal Chem 85(16):76667673

Zhou Y, Kumar DT, Lu X, Kale A, DuBose J, Song Y, Wang J, Li D, Xuan X (2015) Simultaneous diamagnetic and magnetic particle trapping in ferrofluid microflows via a single permanent magnet. Biomicrofluidics 9(4):044102

Zhang J, Yan S, Yuan D, Zhao Q, Tan SH, Nguyen N-T, Li W (2016) A novel viscoelastic-based ferrofluid for continuous sheathless microfluidic separation of nonmagnetic microparticles. Lab Chip 16(20):39473956

Zhao W, Cheng R, Jenkins BD, Zhu T, Okonkwo NE, Jones CE, Davis MB, Kavuri SK, Hao Z, Schroeder C (2017) Label-free ferrohydrodynamic cell separation of circulating tumor cells. Lab Chip 17(18):30973111

Zhao W, Cheng R, Lim SH, Miller JR, Zhang W, Tang W, Xie J, Mao L (2017) Biocompatible and label-free separation of cancer cells from cell culture lines from white blood cells in ferrofluids. Lab Chip 17(13):22432255

magnetic grates

Learn more about how magnets are often assembled and used to make magnetic grates. These assemblies are often used to remove magnetic particles, steel parts, nuts and bolts, or other contaminants from other materials.

For many decades, powerful magnets have been used to separate unwanted matter from grain flowing through a tube or chute. Think of removing small nuts and bolts or bits of barbed wire while filling a silo with grain. This is very important for preventing sparks and possible explosions in a silo!

More recently, more and more researchers in biology are using magnetic particles and neodymium magnets to separate things in suspension. If you have a fluid that contains, say, some bacteria and other stuff, how can you separate the bacteria? Apparently, theres all sorts of tricks to get such enzymes to grab onto bits of magnetic material (think nano-sized iron dust). Put a strong magnet at the bottom of your test tube, and those magnetic bits with the interesting enzymes or whatnot are attracted to it. When you pour out the contents, the magnetic bits remain behind.

Most of the grates weve seen are made with tubes of non-magnetic stainless steel with an assembly of magnets inside. The stainless is sealed shut, usually with a weld, which keeps the magnets free from contamination.

The magnets inside the tube are usually arranged in a row, usually with ring magnets sitting on a shaft. The magnetization direction each successive magnet is assembled in the opposite direction, so that the direction alternates with each magnet.

This specific arrangement is used to create a powerful magnetic field around the assembly. It produces an extremely high magnetic field right at the steel pole pieces, and can exceed 10,000 gauss!

Tiny bits of iron and steel are attracted to the magnet, with the most force in the locations where the magnetic field strength changes the most. Near the pole pieces, this setup can exert a very strong hold onto even fairly small pieces of iron or steel.

Thats a good question. Weve seen so many made with this sort of arrangement, its wide use is taken for granted. While were not experts on the subject, we can think of two primary reasons why this arrangement prevails:

One reason is that you want to extend a strong magnetic field as far out as possible from the tube, to catch ferromagnetic particles from as far away as possible. This setup uses common, axially magnetized ring magnets to produce a magnetic field in a region around the cylinder. It is also strong all the way around the circumference of the cylinder, unlike a diamagnetic magnet, which is strongest at two points (the poles located 180 apart).

The second, and perhaps more compelling reason, has to do with holding onto the bits of iron or steel to the magnet after they are caught. The force exerted on a tiny bit of iron depends on both the field strength and the field strength gradient at given location near the magnet. The gradient is how much the field strength is changing with distance from the magnet.

In this setup, we get both. Extremely high field strength in the region of the pole pieces, combined with a huge gradient in that location (its only high in a small area), make it very hard to pull stuff off the magnet once it is caught. For applications where we have a flow of non-magnetic stuff running over it, a strong hold is important. This helps captured material stay stuck to the grate, rather than being brushed away by passing material.

We put some of the details of this analysis here, in PDF format for our more technical readers (see update below). We describe some of the ways we used the formula shown at right, in a few different situations. We used it in a simple configuration to verify the formula's accuracy. We later used it with our study of magnetic grate assemblies.

In the end, we found it a useful tool for estimating force on a steel particle in a given magnetic field. At the end of that PDF, though, we pose a question that has us stumped. Though the results of plugging numbers into the formula gave us answers that related to what we measured through our own experimentation, the units don't seem to work out. Maybe you can help! UPDATE: Thanks to everyone who emailed us with corrections. We had the B (T/m) as B (T). We updated it here, but left the old PDF as is for posterity. The numbers still don't quite match, but at least the units are correct.

Whats the executive summary of all that analysis? Ferromagnetic materials are most attracted when you have both a strong magnetic field and a strong magnetic field gradient (its strength changes quickly across a distance). Ignoring all the other bits, which might be considered constant, that's the B and the delta-B in that formula.

The force on a bit of steel near the magnet assembly depends on the field strength and field gradient near our magnets. We used the formula from that PDF to estimate the force in various situations.

That shows why the concentrated field strength at the steel spacers works so well for this sort of magnetic assembly. It provides a much stronger hold on the steel particles that it is catching. This makes the captured material much less likely to be bumped off by other non-magnetic material flowing over the grate.

The remainder of this article talks about how to assemble magnetic grates like this. For our earlier demonstration, we used some 5/8" diameter ring magnets and steel washers. Note that the steel washers, often called "pole pieces," are NOT made of stainless steel. They should be made out of ferromagnetic steel -- they stick to magnets!

You could construct similar assemblies with different diameters. Below, we mention a few magnet and steel washer combinations that make sense to us. Of course, you don't have to use our steel washers -- you might use different steel pieces.

Here is a video showing us assembling one of these magnetic grates that we used in the earlier demonstration. It is a 5/8" diameter grate made with six RA24 ring magnets and seven NSW82 steel washers.

magnetic separation magnetense

Contact us to find out how Magnetense can help you solve system and productivity challenges. We offer complimentary video, telephone and chat conversations to help you clarify your needs so we can offer cost-efficient solutions.

Project ManagerMr. Giuseppe Zuccon 1. Our drum jacket was wearing too quickly and we also wanted a magnetic separated that would remove small ferrous parts during the production process.. 2. What product did you purchase? Ferrite magnetic drum. 3. What result did you get? We achieved the . removal distance related the test is 170mm which is good. We also noticed the quality of drum is excellent.. 4. Would you recommend us? Yes, we would recommend you.

Manager Head of Technical DepartmentMr. Valter Garbi 1. We had no specific problems; we just needed to reduce our maintenance and supply costs. 2. What product did you purchase? Magnetic rod for our chargers. 3. What result did you get? We conducted a comparative test on our previous and new magnetic separators and found the Magnatense product has far greater magnetic separation efficiency. 4. Would you recommend us? Yes, we would recommend you.

Purchase ManagerIng. Luca Ceccarelli 1. What product did you purchase? Neodymium rods. 2. What result did you get? We found the magnetic performance in our machine significantly improved once we installed your rods. We were able to develop 13,500 Gauss in contact with the pipe and 14,250 on the outside. 3. Would you recommend us? Yes, we would recommend you because your solution offers outstanding magnetic performance compared to other available systems.

Technical ManagerMr. Luca Durante 1. What product did you purchase? We purchased magnetic plates with the neodymium magnet which we installed on a batch feeder for our hammer mill. 2. What was the problem? We needed to remove metal parts that could go into the mill. 3. What result did you get? We successfully removed all unwanted metallic parts. 4. Would you recommend us? Yes, we would recommend you as suppliers of magnetic systems.

Engineering DepartureMr. Vito Lomorno 1. What was the problem? We were using a system where we couldn't separate the iron from unwanted parts. 2. What product did you purchase? Magnetic pulleys and neodymium rings. 3. What result did you get? We achieved a substantial increment in magnetic separation and an improved customer satisfaction rate from our own customers. 4. Would you recommend us? Yes, we would recommend you for your technical expertise and customer service.

Technical ManagerMr. Giovanni Bianchi 1. What was the problem? We could not prevent ferrous parts from accidentally entering the hammer mill. 2. What product did you purchase? Ferritic magnetic plate. 3. What result did you get? The magnetic plate we purchased has prevented all ferrous objects from entering the upper part of the mill. 4. Would you recommend us? Yes, without any doubt we would recommend you and your product.

Chief ExecutiveSig. Giordano Luca 1. What was the problem? Intercepting iron particles flowing in a pipe used to pneumatically load flour from cisterns to silos. 2. What product did you purchase? Pressurised magnetic piping. 3. What result did you get? The pneumatically loaded flour is free from ferrous particles and it is now safe to move to the next process steps. The machinery is protected from ferrous contaminants. 4. Would you recommend us? Yes, we would definitely recommend you.

Purchase ManagerSig. Paolo Massano 1. What was the problem? Our existing magnetic system did not remove iron from the mill feeders at a satisfactory rate. 2. What product did you purchase? We purchased the Neodymium or ferrite sticks with a 32mm diameter and a 200mm length. 3. What result did you get? We achieved a significant improvement in the removal rate when compared with the previous system. 4. Would you recommend us? Yes, I would recommend you.

Purchase ManagerSig.ra Stefania Manelli 1. What was the problem?Compartment in enamel filters. 2. What product did you purchase?We purchased a magnetic bar with a 32 diameter and 70 mm length. 3. What result did you get?We obtained good results.. 4. Would you recommend us?Yes, I would recommend you.

Established in Italy in 2000 to meet the growing demand for reliable and robust magnetic systems, Magnetense today is a world leader in the efficient design, build and distribution of state-of-the-art magnets, magnetic systems and consultancy services.

Products provided by Magnetence include ferrite/neodymium magnets; manufacturing; and production of magnetic separators such as drums, rolls, plates, overbands, pipings, filters, rods, bars and textile rods.

The WHIMS separator is a magnetic separation machine used in wet separation processes to treat fine grain materials which are smaller than 1.2mm or 200 mesh. These fine grain materials include red mine hematite, limonite, manganese ore, and ilmenite. The WHIMS is also used to treat magnetic minerals including quartz, feldspar, nepheline ore, and kaolin. This system removes iron contaminants to concentrate the treated minerals.

The Balance 2 Drum Magnet features a maximum 10,000 Gauss magnetic power: among the most powerful available on the marketThis drum achieves an excellent wear resistance which is due to Magnetenses unique BL2 balancing system. The BL2 is designed to be easily assembled and tested.

The RO and FLY magnetic rods are newly reinvented rods that have been specifically designed and built by the team at Magnetense. The RO models have a magnetic power of between 6,500 and 12,000 Gauss and the FLY model achieves a maximum power of 14,000 Gauss. The RO and FLY rods are made from high grade neodymium with single section mechanical structures and no moving parts. All rods have exceptional wear resistance which is more than double industry standard and which contributes to long-lasting efficiency.

The Overband Shark and Ova magnetic belts have been uniquely designed to include a combination of ferrite and neodymium magnets. Older generation conveyor belts were generally only fitted with ferrite magnets. This new belt design enables producers to reach more than 5507 Gauss along with a 10 per cent lighter structure when compared to other industry-standard overbelts.

The HMF electromagnetic filters are used in wet process separation of para-magnetic minerals found in quartz, feldspar,silicates, calcium carbonate and kaolin. The flow-rates are engineered in accordance with customer requirements.

The MAG Dry Magnetic Separators include the 1.10/15 and the MAG 3.10/15. Both machines have been designed and manufactured to de-iron a range of sand materials. This includes paramagnetic minerals such as hematite, biotite, ilmenite which are easily captured by Tiger Pulleys powerful magnets. The MAG 1.10/15 and the MAG 3.10/15 magnetic separators are specifically calibrated to remove fine iron particle sizes ranging from 0.1 to 1.8 mm.

The Gravity Feed, Pneumatic Pipe and Electric Pipe magnets comprise a specialist mechanical structure that guarantees higher than industry standard wear resistance. The structure is made from high grade neodymium which allows users to achieve 20% per cent more power than our older generation pipe magnets.

The Tiger Magnetic Pulleys have a diameter of 300mm and a working height of 1500 mm which gives these pulleys a much higher capacity than lower height and diameter machines. These features are combined with an exceptional magnetic power of 12,310+ Gauss that is in contact with the surface and which allows the magnetic rollers to practically catch any magnetic particle or paramagnetic mineral.

The ROL Magnetic Pulley is manufactured with double cross poles which helps the system to reach much higher magnetic power than standard industry separators. The ROL is fixed with Magnetenses Track fixing system which guarantees close to unlimited efficiency and resistance.

The PLV1 Magnetic Plates add an entire new dimension to plate design and use. The aesthetically pleasing PLV1 has exceptional wear resistance and separation efficiency of between 15 and 20 per cent more than our older generation systems. The PLV1 is also equipped with magnetic shielding to help mitigate workplace accidents.

The PLV2 Magnetic Plates add an entire new dimension to plate design and use. The aesthetically pleasing PLV2 has exceptional wear resistance and separation efficiency of between 15 and 20 per cent more than our older generation systems. The PLV2 is also equipped with magnetic shielding to help mitigate workplace accidents.

Our new Batex Magnetic Textile Bars achieve 25 per cent more magnetic field power than our older separation systems. This result was achieved following constant tests aimed at improving the performance of the magnetic system. The New Batex bar also achieves a better separation of iron, even with the same magnetic field.

Established in Italy in 2000 to meet the growing demand for reliable and robust magnetic systems, Magnetense today is a world leader in the efficient design, build and distribution of state-of-the-art magnets, magnetic systems and consultancy services.

Products provided by Magnetence include ferrite/neodymium magnets; manufacturing; and production of magnetic separators such as drums, rolls, plates, overbands, pipings, filters, rods, bars and textile rods.

Magnetense team of engineers are responsible for the entire process including research, design, manufacturinge and global distribution of all products and services. By controlling the entire process operating costs are reduced to the minimum so products are sold to end users competitive price.

Unfortunately there are many magnetic systems manufacturers that promise unreal results eventually not achievable: by conducting a magnetic field measurement created by their systems their claims can be debunked.

In some cases magnetic system manufacturers chose to demonstrate their magnetic performances based on calculations in a closed circuit or through the incorrect use of an instrument; by testing their system any false claim can be debunked.

Magnetic performances based on calculations in a closed circuit or through the incorrect use of an instrument Are often claimed by magnetic system manufactured, but, physics is not made of fairy tales their claims can be easily exposed.

Contact us to find out how Magnetense can help you overcoming system and productivity challenges. We offer complimentary video, telephone and chat conversations to help you clarifying your needs in order to present you with the most cost-efficient solutions.

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