Plastics Reinforcement Alloys Achieve Maximum
Performance and Profit
Micro-cermetallic
alloys and nano-scale alloys are evolving in status as reinforcements
for plastics. The incorporated alloys have the potential to set
higher standards of performance in more-suitable plastic composites
that will produce long-lasting mechanical-parts for high-stress
applications.
Combining
the two alloys is a sure-fire means to exceptional strength
and maximum performance.
Plastics Reinforcement Alloys -- Achieve Maximum Performance and Profit
Maximum
Performance Features:
- Superior Abrasion-Wear Resistance
- Ultra-Low Coefficient of Friction
- Sliding Durability Under Pressure
- Solid Dimensional Stability
- High Creep and Flex Fatigue Resistance
Defending
mechanical-parts against the rigors of industrially tough and
mechanically demanding severe-service environments saves maintenance
costs, adding end-user profits from having longer part-life and
extended part-replacement intervals.
Plastics Reinforcement Alloys:
PPM-MaxAlloy™Series-A:
Micro-Cermetallic Particles
High loadings of the essential primary alloy and transition resin
pre-mixed for uniform dispersion into the particulate plastic matrix
range. A fluoro-reactive diffusion-bonded nano-layer is tacked
onto the slick, ball bearing-like particulate primary alloy to ensure
strong coupling [interfacial interaction] between the alloy and matrix.
PPM-MaxAlloy™Series-B:
Micro-Pellet Mixtures or Blended Particulates
Variable loadings of Series-A with suitable load-ings of nano-scale
alloys plus PPM-produced ceramic or metal, oxide or nitride, or carbide
and a gas-reacted transition-resin combined for melt compounding
pellets and isostatic pressurization of composite machinable
billets.
PPM-MaxAlloy™Series-C:
Encapsulated Standard Pellets
A metallurgically-processed “sheath” of PPM-produced
particulate
ceramic or metal, oxide or nitride, or carbide is deposited onto
plastic pellets. They are used for compounding and for isostatic
pressurization into tough, abrasion-resistant materials molded or
machined into ceramic-like mechanical-parts with “cool” near-net
frictionless properties in rotational and sliding function.
Essential Primary Alloy Properties:
Vickers Hardness Number: 3400VHN
Melting Point: 5680°F [3200°C]
Chemistry: CHF2[TiO]n
Thermal Conductivity: 17 W/mK [9.9BTU/ft-hr°F]
Thermal Expansion: 0.02% at 600°F [316°C]
Modulus: 67 X 106 psi
Bend Strength: 60,000 psi at 600°F[316°C]
Particle Size: <1.2µ[1200nm]
Microfrictional Property: ~0.008
Density: 4.7 gm/cc[0.172 pci]
Specific Surface Area: 3.5 m2/g
Particle Shape: Spheroidal Ball Bearing-like
Contact PPM
Phone Number: 1-604-937-5530
