How to Choose a Magnetic Separating Solution for Your ...

Powder processing facilities have plenty of machinery with aggressively moving parts that have been known to shake loose fasteners or wear down surfaces to produce tiny metal particles or big metal pieces.

Check now

No machinery is immune to wear from blowers, pumps, feeder, belt conveyors or rotary valves.

But when metal debris isn&#;t captured it can cause costly downtime and machine repair, even going so far as to require the need to purchase new machinery. Most importantly, it can lead to contamination, which would cause a loss of product, revenue, and profit &#; or worse if that contaminated product makes its way to your customer or the consumer.

However, if your conveying system is equipped with the proper magnetic separator, you&#;ll be able to capture metal contaminants to deliver a final product that meets your industry&#;s sanitary standards.

To better understand which type of magnetic separator is right for your facility, we&#;ll explore magnet materials, examine process applications, then delve into magnetic separation equipment designed to meet the requirements of a multitude of applications.

Magnetic Separators: Knowing the Ideal Magnet Material & Circuit for Your Application

The field of magnetics (no pun intended) is vast. Many would have you believe that &#;Neo&#; magnets are the end-all-be-all when it comes to separating ferrous material from non-ferrous material. And while they are the most powerful permanent magnet, they have their shortcomings that all of their power cannot overcome.

Did you know that a magnetic field can be too strong? &#;Neo&#; magnets, which is slang for Neodymium Iron Boron magnets, are in a family of magnets that are referred to as &#;permanent magnets.&#; All of the magnets in the permanent magnet family, all provide something that their siblings cannot.

Application Considerations

Selecting the right magnetic separator for your application will depend on several factors. Temperature, flow rate, flow characteristics, and process issues should all be considered during the decision-making process. Let&#;s explore these in more detail:

Temperature

High temperatures can alter a magnet&#;s effectiveness. They start to lose strength at their maximum operating temperatures.

All magnets also have what is called a curie temperature. The curie temperature is the temperature at which a magnet completely loses all of its gauss. Gauss is the measurement by which a magnet&#;s strength is measured. Once a permanent magnet gets heated past its curie temperature, the magnets structure is altered and the magnet will lose it all of its strength as well as its ability to be re-magnetized.

Heating a magnet past its maximum operating temperature, but below its curie temperature, will cause the magnet to lose its strength over time. So, it&#;s important to design a filter within the magnet&#;s maximum temperature, or contaminants in your particle stream will pass right through the magnetic separator.

Flow Rate and Characteristics

The material moving past the magnet needs to be metered so that the magnetic field can capture any contaminants. How the material flows makes a difference, too. If a material clumps, for example, it may plug the separator&#;s opening, requiring the position of the magnetic rods to be adjusted to create more space for the product to flow freely.

Process Characteristics

The type of separator needed will depend on several process considerations. You&#;ll need to determine the level of product purity required.

• Is the material coming to the separator evenly or in surges?
• Can the system be stopped to clean the magnet or will you need a self-cleaning magnet?
• If the magnetic separator is manually cleaned, how will the magnetic separator element be handled? Are there any ferrous materials nearby that could pose a safety hazard?

Powder Type and Consistency

Perhaps one of the most important considerations is the type and consistency of your powder. Some of the categories that deserve consideration are:

• Dry and free-flowing powders
• Dry powders with bridging characteristics
• Moist or lumpy powders (i.e. flour or cornstarch)
• Liquids

Choosing the Right Design for Your Application

Once you&#;ve considered all your unique application requirements, it&#;s time to match them with a magnetic separator that meets your needs.

Grate Magnets are designed for small, dry, granular free-flowing powder. A grid of magnetic rods or bars is positioned in a cross-sectioned area of a pipe, discharge chute, or hopper. It may have a single layer of bars for use in a hopper or multiple rows for vertical chutes.

Rotary Magnets are used for powder flows that will clog stationary grates, like flour. The magnetic rods rotate through the powder stream, increasing magnetic contact, while preventing bridging and lumping.

Inline Plate Magnets work well for a conveyed powder stream in pressurized or vacuum systems. They can be configured in single or dual plate designs for increased separation performance. Furthermore, dry product that builds up or bridges can clog a grate magnetic separator. A plate design, positioned beneath a sloped chute is an option. Rotary magnets, which are mentioned above, also are a good solution.

Inline Magnets are often used for railcar unloading transfer systems, bulk truck transfer systems, bulk bag feeding pneumatic transfers, pressure or vacuum dilute paste conveying.

This category of magnetic separator design Includes:

• Spherical pipeline magnets for sensitive food applications, such as diary. It&#;s design also is effective for capturing tramp iron as well as fine particles.
• Round pipeline separators, which are an inline pneumatic convey line magnets for horizontal, vertical, or sloping installations.
• Powder transfer magnets, which is similar to the round pipeline design but with two magnets oriented at 90 degrees from each other for vertical installations.
• Liquid Pressure Pipeline Magnetic Separators for viscous and non-viscous liquid food products. This design is used to protect product, as well as equipment like pumps, homogenizers, and highly sensitive equipment like extruders.
• Horizontal Magnetic Separators for blow lines and vacuum lines. This magnet can be used in both powder and liquid applications.

Comprehensive Solutions

Magnetic separators protect powders and bulk-processed materials from small and large ferrous contaminants, and many come in quick cleaning or self-cleaning models. To ensure your final product meets required standards, use the information outlined above to ensure you select the correct design for your application and flow characteristics. In the event you need help sizing or configuring the correct magnetic separator, we would be more than happy to help.

Powder Process-Solutions offers powerful magnetic separation equipment to capture ferrous materials from product lines and to ensure the safety of your final product. Magnetic separators can be customized to fit your requirements, including USDA dairy. Learn more about magnetic separators on our website. For questions or more information, contact us today.

Magnetic Separator Efficiency Criteria

Magnetic separator efficiency criteria depends on the task at hand.

• For iron separators it is important to achieve the maximum percentage of extraction of impurities of a certain size that can harm or damage crushing, grinding or other equipment. Taking into account the operating conditions (height of the product layer on the belt, conveyor speed), a separator model that can remove the required dimensions is selected.
• Separators recovering saleable magnetic fraction in the form of scrap metal, iron ore concentrates, dense medium solids, ferroalloys, etc., must ensure the required content of the valuable component in the separated product. It means that the quality of magnetic separator operation with removal of non-magnetic impurities, host rock, slag, will affect the quality and cost of the finished product.
• Another criterion for evaluating how effective this type operates is the loss of a valuable product with a nonmagnetic fraction (tailings). It is often impossible to avoid losses of magnetic material completely due to variability of conditions and material composition, but a properly selected separator will reduce this indicator to minimum values.

For example, if ERGA WetMag R wet magnetic separator for dense media recovery operates correctly, losses of dense medium solids will be only 0.5 g per liter of the processed suspension.

Properties, composition of the separated product and operating conditions

When choosing a magnetic separator, it is also necessary to take into account properties, composition of the separated product and its operating conditions:

1. Product size

The separator type of and its overall characteristics are selected considering the product size. Maximum product size can reach 400 mm, minimum size is 20-10 microns. For processing lumpy material separators with increased safety margin are selected (ERGA DrumMag C, ERGA DrumMag M).

2. Product temperature

You will get efficient and thoughtful service from Zoneding machine.

Magnetic system alloy is selected depending on the temperature of material. Standard permanent rare earth magnets have operating temperatures up to 60° C. For separation of material from 60° C to 200° C, Nd-Fe-B alloys with dysprosium and terbium are used. Magnet alloy based on Sm-Co is used for higher temperatures up to 300° C.

Fig.1 Selection of magnetic alloy depending on operating temperature.

3. Product moisture

For dry magnetic separation moisture content of the separated product is an important factor. This indicator for the product size less than 10 mm should not exceed 5%, for the product size less than 1 mm - 0.5%, for the product size less than 0.1 mm - 0.1%. At high moisture quality of separation decreases due to adhesion and sticking of particles to the separator surface; therefore, it is recommended to pre-dry the material.

4. Magnetic susceptibility of particles

Magnetic induction in the operating area is selected depending on magnetic susceptibility of the particles. For ferromagnets, separators with low intensity of magnetic field (up to 0.32 T) are installed, for paramagnets, depending on the task, separators with average (0.32-0.9 T) and high intensity of magnetic field (0.9-1.5 T) are installed.

5. Content of magnetic impurities

Percentage of magnetic impurities and inclusions will determine the type of separator cleaning. With low content (less than 0.5%) separators with manual cleaning can be installed. With an increased content of 0.5-5%, it is recommended to use mechanical cleaning - this will save operator's time on the process of preparing the equipment for separation. The content of magnetic impurities more than 5% in the product leads to rapid blockage of the operating area and requires continuous or periodic automatic cleaning.

Caution! Tricks of unscrupulous manufacturers

Due to availability of Chinese magnetic materials the number of manufacturers is increasing, unfortunately, unlike the quality of the produced separators. In pursuit of superprofits manufacturers who do not have proper experience in manufacture and design of magnetic equipment often neglect such necessary conditions as control of the production process, manufactured parts, magnetic characteristics. Below are the most common cases when such manufacturers save on the quality of equipment, and, therefore, on separation efficiency, for the sake of short lead time and low cost.

1. Use of separate magnets instead of magnetic systems

The most common case of reducing costs and shortening the equipment manufacturing time is installation of separately located magnets instead of a complex assembly of magnetic systems that requires special technology and equipment. Saving on magnetic material the conditions of technical specifications are observed, for example, induction on the separator surface, but the magnetic flux and long-range action are significantly lost. Installation of magnets without calculating the pole pitch, with large gaps, leads to distortions in the magnetic field in the direction of the product movement, which increases the possibility of magnetic fraction getting into pure product.

The photo below shows one of the examples of the consequences of equipment cost reduction, where the amount of extracted impurities without the magnetic system is clearly visible.

Fig.2 Use of primitive magnetic disks. The magnetic plate thickness is not more than 3 cm.

• ERGA not only assembles complex magnetic systems, but also calculates and selects magnetic characteristics individually, for almost every task and separation conditions.

Fig. 3 Use of a highly efficient magnetic system on the example of ERGA separator. The magnetic plate thickness is 8 cm.

2. Application of cheap alloys of magnetic materials

Special operating conditions, for example, high material temperature, require installation of expensive high-temperature alloys containing rare-earth alloying elements and a more complex manufacturing process.

Another important characteristic of a permanent magnet is its coercive force - this is the value of magnetic intensity required to completely demagnetize the magnetic material, which is especially important for high intensity separators. Cheaper low-coercivity alloys are easily demagnetized and have low service life.

Often, manufacturers neglect this factor and use cheaper permanent magnet alloys, which leads to gradual demagnetization and loss of magnetic characteristics, therefore, decrease of the separation quality.

• ERGA specialists select the magnetic system material according to technical specifications, install alloys with a temperature and coercive margin and give a 10-year guarantee for the retention of magnetic properties. Magnetic separators of our production, installed 20 years ago, are successfully operated today. Reviews and testimonials from our customers are objective evidence of this.

Fig.4 An old one but operational.

3. Neglect of construction safety margin, low-quality components

Almost all separators have wear parts that are usually in direct contact with the product. How long the equipment parts will serve depends on how competently and accurately the design calculation is carried out and the necessary safety margin is set. Saving on construction material leads to rapid wear (1-2 months) of the drum shells of separators, vibrating feeders, tubes of rod separators, etc.

Such cheaper components as geared motors, bearings, vibrators, frequency converters, help to reduce the cost of the separator, but have low service life.

The lack of a serious design study of the Customer's specifications can be a problem in the delivery of complex equipment, that&#;s why ERGA design bureau has a department for calculating strength, a department for calculating magnetic systems. This ensures accurate calculation of magnetic fields for non-standard, specific magnetic systems, as well as to design welded joints, pressure vessels, vibration equipment, etc. with greater reliability.

• ERGA uses only proven and high-quality components (bearings, gear motors, belts, non-magnetic materials), so the reliability of our equipment meets the level of leading German and American manufacturers.

4. Ignoring quality control of manufactured equipment

Saving on expensive measuring equipment, absence of test stands for testing characteristics leads to decrease in cost and reduction in the production time of magnetic separators, but contributes nothing to production of high-quality equipment.

• ERGA has such accepted measuring tools as hysteresisgraph, webermeter, teslameter, X-ray fluorescence analyzer to control magnetic characteristics of permanent magnets, magnetic systems and material composition. Our company also operates a testing laboratory for testing ready products. After manufacturing, each product is tested for compliance with the requirements of technical specifications, testing for strength, geometric, process parameters, visual control, separation quality is checked. The testing laboratory is equipped with its own test stands, equipment and tools that enable analyzing product quality. If there are any doubts about the product quality, improvement is made. Thus, high-quality operation of equipment with the Customer's material is ensured.

Fig.5 Extensively tested.

Often, even having all the information about magnetic separators, separation material, operating conditions, it is practically impossible to select a magnetic separator properly with reliable obtaining the result required for the Customer. Only tests on different types of equipment solve the problem of proper selection of the required magnetic separator, taking into account individual characteristics of the product. ERGA Innovation Centre, which presents both laboratory and industrial models of magnetic, electrostatic, gravity, air separators and metal detectors produced by the company, provides our Customers with the opportunity to evaluate the efficiency of the proposed equipment in practice.

For more information, please visit Dry Magnetic Separator.