Process Description:

Ferrites are fed into a gravity-ramp using a standard bowl feeder. The gravity ramp ensures a constant back pressure on the feed stack, and provides immediate replenishment at the pick point, maintaining cycle rate.

The ferrite is picked using a electromagnetic gripper, which holds the ferrite in a shallow cavity. The AFAG pneumatic pick-and-place executes a simple up-over-down cycle, pressing the ferrite onto the retention boss. The AFAG device allows independent precise setting of the pick and place points. When the ferrite is properly nested, the electromagnetic gripper is released, and the cycle is repeated.

Technical Challenge:

Creation of a custom electromagnetic gripper that could fit within the assembly cavity was a challenge. The ferrite was essentially installed at the bottom of a long dark hole. The electromagnet had to fit within that hole, and initial attempts failed to create sufficient holding force to keep the magnet in the gripper. Ultimately, the magnetic strength of the gripper was improved with the use of thicker wire, more current, an iron core and a substantial increase in length.

Features:

• Pneumatic pick-and-place;
• Bowl feeding;
• PLC control
• Pallet transfer.

Control System: PLC control

User Interface: Push button

Production Rate: 1000 assemblies per hour

Transfer System: Bosch TS-1

Format: In-line cell with pass through conveyor

Ceramic magnet material (Ferrite) is Strontium Ferrite. This material is one of the most cost effective magnetic materials manufactured in industry. The low cost is due to the cheap, abundant, and non-strategic raw materials used in manufacturing this alloy. The permanent magnets made with this material lend themselves to large production runs. This magnet material has a fair to good resistance to corrosion and it can operate in moderate heat. The majority of the world's Ceramic magnetic material comes from China because of the alloy's commodity nature and the high tooling costs found in the west. Ceramic magnets have a low Energy Product and they are usually used in an assembly containing mild steel.

Ceramic Magnets offer the best value when comparing cost. They are inexpensive, moderate in magnetic strength, and they are easily magnetized in a variety of formats. Ceramic magnets offer good corrosion resistance and generally do not require a coating or plating. Consideration should be given to the grade of alloy when exposing Ceramic magnets to temperature extremes. Ceramic magnets have good resistance to external demagnetization fields because of its high Intrinsic Coercive Force (Hci) . This resistance and low cost makes Ceramic magnets a popular choice for electromechanical applications.

Ceramic magnets are very hard and brittle. Like all magnetic materials, ceramic should not be used as a structural element in a design. Ceramic magnets are particularly prone to cracking when the application involves impacts or flexing. As with most ceramic, the ferrite magnets should not be exposed to heating or cooling rates greater than 200°F per hour.

Ceramic Magnets Manufacturing Process

Ceramic Magnets are produced by calcining a mixture of iron oxide and strontium carbonate to form a metallic oxide. A multiple stage milling operation reduces the calcined material to a small particle size. The powder is then compacted in a die by one of two methods. In the first method, the powder is compacted dry which develops an isotropic magnet with weaker magnetic properties, but with better dimensional tolerances. Often times a dry pressed magnet does not require finish grinding. In the second method, the powder is mixed with water to form slurry. The slurry is compacted in a die in the presence of a magnetic field. The applied field creates an anisotropic magnet which exhibits superior magnetic properties, but usually requires finish grinding.

The compacted parts which approximate the finished geometry are then sintered at high temperatures to achieve the final fusion of the individual particles. Final shaping is achieved by diamond abrasives. Usually the pole faces will be ground and the remaining surfaces will exhibit "as sintered" tolerances and physical characteristics.

Magnets in today's electric motors are almost exclusively assembled using adhesives, which produce higher quality joints at lower costs than mechanical fasteners. To make magnet bonding faster, stronger and more reliable, Henkel has introduced three new Loctite® adhesives ideal for bonding ferrite, neodymium/iron, and alnico magnets used in electric motors, speakers, small engines, computer storage devices, power hand tools and other devices.

All three new products offer faster fixturing, higher temperature resistance, greater impact and shear strength, improved moisture resistance, easier processing, and extended shelf lives. All formulations are acid-free and non-corrosive.

Loctite® 331™ Structural Adhesive is a toughened, acid-free, two-step acrylic that fixtures in just 20 seconds and develops full strength in 30 minutes. This high temperature formulation is activator cured and ideal for bonding close-fitting magnets and metals of all sizes. Capable of filling small to medium gaps, this product can be used in a range of production volumes.

Loctite® 3060™ Structural Adhesive is a toughened, acid-free, two-component, external-mix acrylic that is ideal for filling large gaps. Two cascading adhesive streams automatically mix together, eliminating the need for static mixers or activators. Loctite® 3060™ Structural Adhesive offers fast fixture speeds with high temperature resistance, is ideal for use on medium to large magnets, and works well in medium to high volume production environments.

Loctite® E-220IC™ Hysol® Epoxy Adhesive is a toughened, acid-free, one-component epoxy designed for induction cure operations. Loctite® E-220IC™ Hysol® Epoxy Adhesive offers ultra-fast fixture speeds, high gap-filling capability, exceptional strengths, and excellent temperature resistance. The product is ideal for use on medium to large magnets and works well in any production volume.

For more information on the new Loctite® magnet bonding adhesives, call 1-800-284-0874, visit www.gluemymagnet.com, or email marketing@loctite.com.

MCH-Series magnet is one of Sugatsune's strong heavy duty magnet catch which can hold up to 6.6-30.6 lbs of force depending on its size. It is composed of zinc alloy housing with a nickel finish and magnets that is made up of ferrite. The yoke and counter plate of the magnet is made up of steel and has a yellow zinc chromate finish.

Technical CAD drawings, PDF files and data sheets detailing the measurements and specifications for this product or any other product are available online at www.sugatsune.net or by contacting our customer service toll free (888) 557-5267.

Features

1.High density packaging with a pitch of 2.54 mm（0.1 inch）max. is possible. This series requires less space and has greater EMI suppression effects.
��2. Different types with the same shape are available.
�� 3.Excellent in physical properties, such as terminal strength, flexure strength, soldering resistance and solderability.
�� 4.Applicable to both flow and reflow soldering.
�� 5.High impedance cover wide frequency ranges.
�� 6.L material type can minimize attenuation of the signal waveform due to its sharp impedance

Applications

�� 1.Computers and peripheral devices, personal computers, VCR and cameras.
�� 2.Noise suppression in digital equipments, car stereo, car engines controllers and OA electronic instruments.
�� 3.Communication equipment

Materials Available :

• Alnico / Alcomax

• Neodymium iron Boron(NdFeB)

• Ferrite

• Bare magnets

• Cased magnets