3. Advanced Composites
• Long (continuous) fibers
• Very high performance reinforcements
– Carbon and aramid
• Resins are also very high performance
• Typically aerospace applications
5. Matrix Materials
• Resins
– Both thermosets and thermoplastics can be
used
– Short fibers are generally used in
thermoplastics
– Long fibers are generally used with
thermosets
6. Matrix Materials
• Short fiber composites
– Less than 0.2 inches (whiskers)
– Processed through standard thermoplastic
processes
• Must pass through gates, runners, and gap
between processing screw and barrel walls
– Thermoplastics generally benefit greatly from
even the short reinforcement materials
7. Matrix Materials – FRP
• Intermediate length fiber reinforcement
– The longer the fibers, the more difficult it is to
coat the fibers enough to reap strength
benefits
– Low viscosity thermosets “wet-out” the
materials better than high viscosity
thermoplastics
– Generally use unsaturated polyester and
vinylester resins for FRP
8. Matrix Materials – Advanced
• Very long fibers or continuous fibers
– Typically used with thermosets, also for “wet-
out” reasons
– Used generally in advanced composite parts
and have greater material property
requirements
– Generally use epoxy resins
9. Reinforcements
• Three main types of fibers
– Fiberglass
– Carbon fiber or Graphite
– Organic fibers, aramids (kevlar)
10. Fiberglass
• Spin molten glass
• Different types of glass can be made
– E-glass (improved electrical resistance)
– S-glass (high strength)
– C-glass (high chemical resistance)
11. Carbon or Graphite Fiber
• Originally some distinction was made—
now the two refer to the same material
• Made from PAN fibers, pitch or rayon
fibers
• Through heating, raw material looses most
non-carbon atoms in the chain
• Processing also aligns carbon chains
• Carbon fibers have very high modulus
(stiffness)
12. Organic Reinforcement Fibers
• Aramid fibers have greatest strength and
modulus properties of organic fibers
• Kevlar is the most commonly used aramid
fiber
• Aramids are strong and stiff but their
greatest value is in impact applications
– Front of airplane wings
– Armor applications
13. Reinforcement Forms
• Fiber manufacturers package the fibers on
spools called tows
• Fibers are generally converted to other
forms after manufacturing
– Chopped fibers (including whiskers)
– Mat (random)
– Woven fibers
– Tapes
– Prepregs
14. Manufacturing Methods
• Thermoplastic processes using short
fibers
– Injection molding
– Extrusion
– Minor changes are made to accommodate the
fiber reinforcements
• All gaps in flow path should be increased
• A resin viscosity decrease may be necessary
15. Manufacturing Methods
• Matched die or Compression molding
– Reduced flow path over injection or extrusion
– SMC compression molding allows for
continuous fibers, mats or weaves
– These processes offer parts that are finished
on both sides where most other composite
processes do not
16. Manufacturing Methods
• Resin transfer molding
– Fiber preform is placed in the mold cavity
– Preform doesn’t move—resin is pulled/pushed
in
19. Fiber Orientations
• Isometric materials have equal strength in
all directions
• Composites can be lighter weight by not
having strength in the directions that it is
not needed
• Lay-up still has to have some balance and
symmetry
21. Manufacturing Methods
• Filament winding and fiber placement
– Fiber placement has greater accuracy
– Fiber placement can wind on less symmetrical
and even partially concave mandrels
• Tubes, tanks, wind turbine blades and
rockets
23. Manufacturing Methods
• Pultrusion
– High volume production
– Comparable to extrusion but the main
processing force is tension
– Profile is pulled from the machine
24. Plant Concepts
• Many of the processes require
considerable space
• Curing equipment for large parts can be
very large (and expensive)
• Controlling volatiles (solvents and resins)
must be taken care of
• Molds can be both expensive and fragile
