Topic:Low Cost Carbon Fiber and Composites Technology
Outlines:
UTSI Pitch (Green) Fibers
• High Speed, Melt Blown Spinning Process
• Continuous Mesophase Pitch Fibers abundant and cheap natural material very high carbon yield UTSI Fiber spinning apparatus
UTSI Carbon Fibers
• Relatively fast thermal stabilization in air
• Low-temperature carbonization at 1050oC
Carbon Fiber
Green Fiber
Stabilized Fiber
Carbon Fiber
UTSI Carbon Fibers Form
• UTSI carbon fiber is produced in tape or non-woven fabric (mat) with ~10 cm in width and ~ 0.5-1 cm thick.
• Fiber filaments are continuous but are almost randomly oriented.
• The carbon fiber can be easily fabricated into non-woven mat (or paper) with polymer binders.
Typical UTSI carbon fiber form Continuous carbon fiber mat (paper) and chopped carbon fiber mat made from the UTSI carbon fiber and a polymeric binder
The pitch fibers have a high carbon yield for making carbon fibers.
• The carbon yield is also depending on the level of stabilization of the green fibers Yields of fibers after stabilization and carbonization at lower (600oC) and higher (1050oC) temperatures
The diameter of pitch fibers and resulting carbon fibers decreased with increasing blowing flow rates.
• The carbon fiber diameter could be reduced to 7 to 20 m, if fibers were processed for higher level of stabilization. Diameter of carbon fibers vs blowing flow rate
Tensile strength and young's modulus increased with increasing the level of stabilization. However, too much higher level of stabilization will decrease strength and modulus.
• At 1050oC, tensile strength and modulus of the fiber (20 -10 m) can reach 500-1100 Mpa and 70-110 Gpa, respectively. When the carbonization temperature is up to 1500oC, the strength and modulus can be up to ~2.5 Gpa and ~200 Gpa
respectively
Polymer resins tested :
Epoxy resin
Vinyl ester
Phenolic resin
Hot Press :
Using pressure to control the fiber volume
Using temperatures to control resin infusion and curing
SEM images of carbon fiber composite plate showing that the fibers were almost randomly aligned in the composites
Features:
• Relatively high strength (mesophase CF as reinforcement is hard to be activated)
• Higher surface area (from phenolic– based carbon matrix after activation)
• Various shapes and formation as a whole material
• Contact efficiency is superior to fibrous and granular activated carbons.
• Relatively high electrical conductivity (from long mesophase pitch-based carbon fibers)
• Flexibility in engineering design
UTSI
Mesophase
Pitch-based
Carbon Fiber
Carbonized Composites
UTSI Activated Carbon
Composites
Carbonization
Activation
Phenolic
Resin
Solution
CF / phenolic Composites
(can be molded to different form) [Page]
Fabrication
Potential Applications:
• Used as adsorbents/carbon membranes for water and air purification
• Catalyst and catalyst supporter
• Electrode materials for battery
• Combination of structural and functional Materials
Summary
• Pitch is produced from petroleum or coal
• Melt-blow spun, solvated mesophase pitch-based carbon fibers have ~ 75 wt% carbon yield at 1050oC.
• The tensile properties of carbon fibers are strongly influenced by stabilization level and carbonization temperatures.
• The form of the carbon fiber is different from that of typical commercial products and is as non-woven fabric. All fiber filaments are continuous with controlled orientation.
• Using such carbon fibers as reinforcement, the flexural properties of the composite did not display much difference at 0o and 90o of fiber mat direction
• Surface activation results in excellent filtration materials.
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