The best quality and customer satisfaction are our first priority.
Size: 30x4.4x8mm
Grade: GMEsmco30
Magnetized through 4.4mm
Standard tolerance
Work temperature: 300-350 degree
About SmCo magnet:
SmCo magnet are made of samarium and cobalt and other rare earth elements.
Constitution: 35% Sm, 60% Co and 5% Fe and Cu
Production chart: Raw material---Mixing---Vacuum melting---Powder production---Molding---
Vacuum sintering---Testing---Cutting and Grinding---Surface coating---Inspection---Packing---Shipping
Grade: GMEsmco21:5(GMEsmco16, GMEsmco18, GMEsmco20, GMEsmco22,GMEsmco24),
(GMEsmco2:17 GMEsmco24, GMEsmco26, GMEsmco28, GMEsmco30,GMEsmco32)
Share: Disc, Ring,
Block, segment, Cylinder, Trapezoid, Customized design(Design proper
magnets for clients specific requirements)
Characteristics: High performance,high working temperature 350 degree ,
It doesn’t need to be coated because it is difficult to be eroded and oxidized.
Application: Motors, Aviation and spaceflight, National defense and military affairs, Microwave appliance,
Medical apparatus, Auto industry, Machine gearings, sensors, meters and instruments.
strong rare earth smco magnet R30xr8x4mm
Corrosion Resistance of Samarium Cobalt Magnets (SmCo)
Samarium Cobalt Magnets (SmCo) are very resistant to corrosion and do not normally require any
surface treatment, like neodymium magnet, .
surface treatment, like neodymium magnet, .
For most applications a coating or plating
is not required though,
is not required though,
but it should be considered when operating in
environments that are acidic, have high moisture, or are in a vacuum.
environments that are acidic, have high moisture, or are in a vacuum.
Coatings and metal platings will increase
the ability to clean the magnet and metal plating allow for greater cleanliness
for vacuum and medical applications.
the ability to clean the magnet and metal plating allow for greater cleanliness
for vacuum and medical applications.
Nickel plating fasciculate soldering
the magnet and this is especially used for adhesion to a printed circuit board.
the magnet and this is especially used for adhesion to a printed circuit board.
Samarium Cobalt magnets (SmCo) with parylene
coating is a good choice for Medical and Aerospace applications, because of low
environmental reactivity.
coating is a good choice for Medical and Aerospace applications, because of low
environmental reactivity.
Material |
Grade |
Remanence |
Coercivity |
Intrinsic Coercivity |
Max Energy Product |
Density |
Temp Coefficient (Near Br) |
Temp Coefficient |
Curie Temp |
Max Operating Temp (TW) |
||||
(Br) |
(Hcj) |
(Hcb) |
(BHmax) |
(D) |
(Near Hcj) |
(TC) |
||||||||
mT |
Gs |
KA/m |
Oe |
KA/n |
Oe |
KJ/m3 |
MGOe |
g/cm3 |
%/K |
%/K |
°C |
°C |
||
SmCo1:5 |
SmCo18 |
840 |
8400 |
605 |
7600 |
1432 |
18000 |
143 |
18 |
8.1 |
-0.04 |
-0.3 |
750 |
250 |
(SmPr)CO5 |
SmCo20 |
890 |
8900 |
637 |
8000 |
1432 |
18000 |
159 |
20 |
8.2 |
-0.04 |
-0.3 |
750 |
250 |
SmCo22 |
930 |
9300 |
637 |
8000 |
1432 |
18000 |
175 |
22 |
8.2 |
-0.04 |
-0.3 |
750 |
250 |
|
LTc(HM-10) |
590 |
630 |
493 |
6200 |
1430 |
1830 |
80 |
10 |
8.2 |
Temp Range |
Br T.C. %°C |
700 |
250 |
|
1:05 |
20-100°C |
-0.004 |
||||||||||||
(SmGd)CO5 |
100-200°C |
-0.021 |
||||||||||||
200-300°C |
-0.042 |
|||||||||||||
SmCo24 |
980 |
9800 |
676 |
8500 |
1432 |
18000 |
191 |
24 |
8.3 |
-0.03 |
-0.2 |
800 |
280 |
|
SmCo24H |
980 |
9800 |
676 |
8500 |
1989 |
25000 |
191 |
24 |
8.3 |
-0.03 |
-0.2 |
800 |
280 |
|
SmCo26L |
1030 |
10300 |
398 |
5000 |
438 |
5500 |
207 |
26 |
8.3 |
-0.03 |
-0.2 |
800 |
300 |
|
SmCo26 |
1030 |
10300 |
716 |
9000 |
1194 |
15000 |
207 |
26 |
8.3 |
-0.03 |
-0.2 |
800 |
300 |
|
SmCo 2:17Sm2 |
SmCo26M |
1030 |
10300 |
716 |
9000 |
1592 |
20000 |
207 |
26 |
8.3 |
-0.03 |
-0.2 |
800 |
300 |
(CoFeCUZr)17 |
SmCo26H |
1030 |
10300 |
716 |
9000 |
1989 |
25000 |
207 |
26 |
8.3 |
-0.03 |
-0.2 |
800 |
350 |
SmCo28 |
1070 |
10700 |
756 |
9500 |
1194 |
15000 |
223 |
28 |
8.3 |
-0.03 |
-0.2 |
800 |
350 |
|
SmCo28M |
1070 |
10700 |
756 |
9500 |
1592 |
20000 |
223 |
28 |
8.3 |
-0.03 |
-0.2 |
800 |
350 |
|
SmCo30 |
1100 |
11000 |
772 |
9700 |
1194 |
15000 |
239 |
30 |
8.3 |
-0.03 |
-0.2 |
800 |
350 |
|
SmCo30M |
1100 |
11000 |
772 |
9700 |
1592 |
20000 |
239 |
30 |
8.3 |
-0.03 |
-0.2 |
800 |
350 |
|
LTc(HMG-22) |
980 |
9800 |
715 |
9000 |
1500 |
20000 |
230 |
23 |
8.3 |
Temp Range |
Br T.C. %°C |
840 |
300 |
|
-50-25°C |
0.005 |
|||||||||||||
2:17 |
20-100°C |
0.012 |
||||||||||||
(SmEr)2(CoTM)17 |
100-200°C |
0.006 |
||||||||||||
200-300°C |
-0.025 |
|||||||||||||
*The effective Maximum Operating Temperature for a Samarium Cobalt Magnet is a function of the magnet’s magnetic characteristics and the geometry of the system (the magnet and the circuit). The listing maximum operating temperature is a recommendation and infers and ideal geometry and no external demagnetizing fields. |
||||||||||||||
Temperature Effects on Samarium Cobalt Magnets (SmCo)
Sintered Samarium Cobalt
rare earth magnets operate at temperatures up to 500F (260C), with extremely high
resistant to demagnetization.
rare earth magnets operate at temperatures up to 500F (260C), with extremely high
resistant to demagnetization.
Though there are many
Samarium Cobalt grades withstand higher temperatures,
Samarium Cobalt grades withstand higher temperatures,
several factors will
dictate the overall performance of the Samarium Cobalt rare earth magnet.
dictate the overall performance of the Samarium Cobalt rare earth magnet.
One of the most pertinent
variables is the geometry of the magnet or magnetic circuit.
variables is the geometry of the magnet or magnetic circuit.
Samarium Cobalt magnets (SmCo) will
demagnetize easier than Samarium Cobalt magnets which are thick.
demagnetize easier than Samarium Cobalt magnets which are thick.
Magnetic geometries
utilizing backing plates, yokes, or return path structures will respond better
to increased temperatures.
utilizing backing plates, yokes, or return path structures will respond better
to increased temperatures.
The max recommended operating temperatures listed on
the Samarium Cobalt magnetic characteristics list above do not take into
account all geometry conditions.
the Samarium Cobalt magnetic characteristics list above do not take into
account all geometry conditions.
Most useful commercial magnets are
anisotropic which means that they have an “Easy” or preferred direction of
magnetization
anisotropic which means that they have an “Easy” or preferred direction of
magnetization
and that an orientation field was applied during the compaction
stage of the manufacturing process.
stage of the manufacturing process.
It is essentially impossible to magnetize
the resulting anisotropic magnet alloy other than in the Direction of
Orientation;
the resulting anisotropic magnet alloy other than in the Direction of
Orientation;
however, various pole configurations can be achieved without
conflicting with the magnet material’s orientation.
conflicting with the magnet material’s orientation.
Below are conventional and standard industry
options for the MAGNETIZATION directions of SmCo Rare Earth / Samarium
Cobalt Magnets (SmCO).
options for the MAGNETIZATION directions of SmCo Rare Earth / Samarium
Cobalt Magnets (SmCO).
Disc Geometry/shape
1. axially
2. diametrically
Polarity
Nomenclature: Typically the arrowhead indicates the North pole of
the magnet.
Nomenclature: Typically the arrowhead indicates the North pole of
the magnet.
For symmetric geometries indicating the location of a particular
pole is unnecessary, but for non-symmetric geometries identifying a particular
pole location is very important.
pole is unnecessary, but for non-symmetric geometries identifying a particular
pole location is very important.
Example: An axially Magnetized disc magnet
does not require communication as to the NORTH pole’s position,
does not require communication as to the NORTH pole’s position,
but a radial
arc does. One must indicate if the NORTH pole is to reside on the Inner radius
or Outer Radius.
arc does. One must indicate if the NORTH pole is to reside on the Inner radius
or Outer Radius.
Block Magnet /shape
“Block Magnets” or Rectangular / Square magnets have three potential
orientation directions.
The block magnet can be polarized in any
direction.
direction.
Ring Geometry/ shape
1. axially for ring
2. diametrically for ring
Radial
Magnetization:
Magnetization:
True Radially Magnetized Ring
Radially oriented and magnetized rings are
available in Neodymium Iron Boron, but there are many limitations in alloy
grade,
available in Neodymium Iron Boron, but there are many limitations in alloy
grade,
Outside Diameter/Inside Diameter ratio, axial, length, etc.
Specialized
tooling must be created and there is an upfront capital investment which acts
as a cost inhibitor for most applications.
tooling must be created and there is an upfront capital investment which acts
as a cost inhibitor for most applications.
Radial Ring
Magnetization Approximation:
Magnetization Approximation:
Radially Approximated Ring Comprised of Approximated
Radial Arc Segments
Radial Arc Segments
Samarium Cobalt magnets can be
approximated by arcs segments;
approximated by arcs segments;
however, in most cases the magnets must be
assembled magnetized and there must be a large performance benefit to the
application to absorb this cost.
assembled magnetized and there must be a large performance benefit to the
application to absorb this cost.
As with “True” radial rings, true radial
Arc Segments are difficult to manufacture, but can be approximated themselves.
See Below.
Arc Segments are difficult to manufacture, but can be approximated themselves.
See Below.
Arc Segment
Geometry / shape
Geometry / shape
1. Axially for arc
2. diamterially magnetizing for arc or radial arc
An arc
segment can be polarized NORTH or SOUTH on the Outside Radius. (The
resulting opposite pole will reside on the Inside Radius.)
It is very difficult to achieve a 100% “radial” orientation during the pressing/alignment stage of manufacturing and therefore,
segment can be polarized NORTH or SOUTH on the Outside Radius. (The
resulting opposite pole will reside on the Inside Radius.)
It is very difficult to achieve a 100% “radial” orientation during the pressing/alignment stage of manufacturing and therefore,
100% radial Neodymium Iron Boron, Samarium Cobalt, and Ceramic magnet arcs are rare and specialized.
(An approximation of a true radial Orientated Radial Arc is widely utilized in industry.)
3. circumferential-arc / or span magnetizing
Circumferential Orientation and Magnetization is not available for Arc magnets comprised of Samarium Cobalt;
however, this magnetization geometry can be approximated.
The approximated radial arc utilizes linear orientation/magnetization along a straight axis.
The radial component diminishes on the leading and trailing edges of the approximated radial arc.
Radially IN /
Radially Out:
Radially Out:
True Radial Arc Segment
Manufacturing Methods of Samarium Cobalt Magnet:
Fully dense Samarium Cobalt rare earth
magnets are usually manufactured by a powdered metallurgical process.
magnets are usually manufactured by a powdered metallurgical process.
Micron
size Samarium Cobalt powder is produced and then compacted in a rigid steel
mold.
size Samarium Cobalt powder is produced and then compacted in a rigid steel
mold.
The steel molds produce shapes similar to the final product, but the
mechanical properties of the alloy usually inhibit complex features at this
stage of the manufacturing process.
mechanical properties of the alloy usually inhibit complex features at this
stage of the manufacturing process.
The various elements that compose a samarium
cobalt magnet – samarium, cobalt, copper, zinc, and iron.
cobalt magnet – samarium, cobalt, copper, zinc, and iron.
The Samarium Cobalt’ s magnetic
performance is optimized by applying a magnetic field during the pressing
operation.
performance is optimized by applying a magnetic field during the pressing
operation.
This applied field imparts a preferred direction of magnetization,
or orientation to the Samarium Cobalt magnet alloy.
or orientation to the Samarium Cobalt magnet alloy.
The alignment of
particles results in an anisotropic alloy and vastly improves
the residual induction (Br) and other magnetic characteristics of the
finished magnet.
particles results in an anisotropic alloy and vastly improves
the residual induction (Br) and other magnetic characteristics of the
finished magnet.
After pressing, the Samarium Cobalt
magnets are sintered and heat treated until they reach their fully dense
condition.
magnets are sintered and heat treated until they reach their fully dense
condition.
The rare earth magnet alloy is then machined to the final
dimensional requirements and cleaned.
dimensional requirements and cleaned.
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