Home » Polyvinylidene Fluoride Pellets ((C2H2F2)n, Purity: 99.5%)
|Product||Polyvinylidene Fluoride Pellets|
|Melt volume-flow rate, MVR||20 cm³/10min||Confirm|
|Molding shrinkage, parallel||2%||Confirm|
|Molding shrinkage, normal||2%||Confirm|
|Nominal strain at break||>50%||Confirm|
|Charpy impact strength, +23°C||192kj/m2||Confirm|
|Charpy impact strength, -30°C||208kj/m2||Confirm|
|Charpy notched impact strength, +23°C||8kj/m2||Confirm|
|Charpy notched impact strength, -30°C||5kj/m2||Confirm|
|Melting temperature, 10°C/min||168 ˚C||Confirm|
|Glass transition temperature, 10°C/min||-40 ˚C||Confirm|
|Temp. of deflection under load, 1.80 MPa||110 ˚C||Confirm|
|Temp. of deflection under load, 0.45 MPa||130 ˚C||Confirm|
|Vicat softening temperature, 50°C/h 50N||140 ˚C||Confirm|
|Coeff. of linear therm. expansion, parallel||150 E-6/K||Confirm|
|Burning Behav. at 1.5 mm nom. thickn.||V-0 Class||Confirm|
|Yellow Card available||Yes||Confirm|
|Burning Behav. at thickness h||V-0||Confirm|
|Relative permittivity, 100Hz||9||Confirm|
|Relative permittivity, 1MHz||6||Confirm|
|Dissipation factor, 100Hz||350 E-4||Confirm|
|Dissipation factor, 1MHz||2060 E-4||Confirm|
|Volume resistivity||2E12 Ohm||Confirm|
|Test specimen production||.|
|Injection Molding, melt temperature||200 ˚C||Confirm|
|Injection Molding, mold temperature||90 ˚C||Confirm|
|Injection Molding, injection velocity||10 mm/s||Confirm|
|Injection Molding, pressure at hold||13 MPa||Confirm|
|Quality Control||Each lot of Polyvinylidene Fluoride Pellets was tested successfully.|
|Main Inspect Verifier||Manager QC|
Polymer nanocomposites consist of polymer or copolymer having nanoparticles or nanofillers dispersed in polymer matrix. These may be of different shapes (fibers, platelets, spheroids) but atleast one dimension must be in range 1-50nm.Polymers are light weight and corrosion resistant materials.
Furthermore, polymers are versatile materials for nanotechnology due to their processability, flexibility, diverse functionalities, low cost and tunable properties.. They have high thermal, electrical and mechanical properties characteristics.
Polymer Nanomaterials has revealed the property advantages that nanomaterial additives can provide in comparison to both their conventional filler counterparts and base polymer. Properties which have been shown to undergo substantial improvements include: (1) Mechanicals e.g. strength, modulus and dimensional stability (2) Improved solvent and heat resistance (3) Decreased permeability to gases, water and hydrocarbons (4)Thermal stability and heat distortion temperature (5) Flame retardancy (6) Chemical resistance (7) Surface appearance (8) Electrical conductivity (9) Optical clarity in comparison to conventionally filled polymers.
The utility of polymer-based nanomaterials in these areas is quite diverse involving many potential applications and have been proposed for their use in various applications. They are used inmemory devices, bio-imaging, drug delivery, chemical sensors, electroluminescent devices, electro catalysis, batteries,smart windows, electromagneticinterference shielding, transparent conductive coating, electrostatic dissipation, photovoltaic, gas sensors, optical displays, superconductor devices etc.
Conjugation of polymers with various nanoscale filler inclusions have been used for sensor applications including gas sensors, biosensors and chemical sensors. The nanofillers employed include metal oxide nanowires, carbon nanotubes, nanoscale gold, silver, nickel, copper, platinum and palladium particles. Polymer-based solar cells have the capability of being used to make cheap large flexible panels.
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