DAY 22: OVERVIEW OF ADVANTAGES OF CERAMICS temperature resistance  high hardness  low density  corrosion resistance 

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Transcript DAY 22: OVERVIEW OF ADVANTAGES OF CERAMICS temperature resistance  high hardness  low density  corrosion resistance  

DAY 22: OVERVIEW OF
ADVANTAGES OF CERAMICS
temperature resistance
 high hardness
 low density
 corrosion resistance

SPECIAL DESIGN
CONSIDERATIONS FOR CERAMICS
brittleness
 difficulty of manufacture.

Material
Melting
Temperature
Melting
Temperature, C
NaCl
801
Iron, Fe
1535
Aluminum
Ni based
superalloy
1260-1335
W
3300
Al2O3
2045
SiC
2500*
Si3N4
1900*
ZrO2
2700
Thermal Expansion
Material
Linear Thermal Exp. Coef.
(cm/cm C x 106)
NaCl
40
Nylon 6,6
144
Polycarbonate
122
Fe alloys
12
Al alloys
21-24
Ni based superalloy
12-17
W
4.5
Al2O3
7-8
SiC
4.1-4.6
Si3N4
2.7-3.1
ZrO2
9-10
Modulus of Elasticity
Material
NaCl
Nylon 6,6
Polycarbonate
Elastic Modulus
(psi x 106)
6.4
1.6-3.8
1.9-3
Fe alloys
30
Al alloys
10
Ni based
superalloy
W
30.4
58
Al2O3
40-55
SiC
30-70
Si3N4
44
ZrO2
20
Electrical Conductivity
Material
Resistivity
(ohm-m)
Nylon 6,6
1012
Polycarbonate
1014
Fe alloys
10-7
Al alloys
10-8
Ni based
superalloy
10-7
W
10-8
Al2O3
1014
SiC
109
Si3N4
1014
ZrO2
1010
Thermal Conductivity
Material
Thermal
Conductivity
W/m-K
Nylon 6,6
0.24
Polycarbonate
0.20
Fe alloys
52
Al alloys
130-220
Ni based
superalloy
W
10-20
155
Al2O3
16-40
SiC
70-80
Si3N4
10-30
ZrO2
2-3
Graphite
100-190
Diamond
1500-4700
http://americas.kyocera.com/kicc/pdf/Kyocera_Material_Characteristics.pdf
Ductility
Material
Nylon 6,6
Polycarbonate
Fracture
Toughness
MPam
2.5-3
2.2
Ni based
superalloy
60-75
Al alloys
20-60
Fe metal
20-100
ZrO2
7-12
SiC
5-6
Si3N4
4-6
Al2O3
4-6
Strength
Richerson, 1992
Richerson, 1992
COMMON STRUCTURAL CERAMICS
silicon carbide (SiC)
 silicon nitride (Si3N4)
 zirconia (ZrO2)
 alumina (Al2O3)

Property
Ceralloy 147-31E
Ceralloy 147-31N
Ceralloy 147-1E
Ceralloy 147-1
Process
Sinter
Sinter
Hot Press
Reaction Bonded
Density (g/cc)
3.25
3.21
3.1
2.4
Density (% Theoretical)
>99.3
>99.5
>98.5
75
Flexural Strength (MPa)
@ RT
700
800
700
240
Weibull Modulus
10-15
15-30
18
10
Elastic Modulus (GPa)
310
310
310
175
Poisson's Ratio
0.27
0.27
0.27
0.22
Hardness HV(0.3)
Kg/mm2
1800
1800
1800
800
Fracture Toughness (MPa
m1/2)
6.0
5.8
5.0
2.5
Abrasive Wear
Resistance Parameter ***
1130
1110
1120
360
Thermal Exp Coeff. 106/C;
3.1
3.1
3.2
3.2
Thermal Cond (W/mK) @
25 C
26
26
42
14
Thermal Shock
Parameter (C)**
530
610
540
330
Elecrical Resistivity (ohmcm)
10^14
10^14
10^14
10^14
Applications
Cutting Tools, Wear
Components
Automotive Components,
Bearings, Wear
Components
Semiconductor
Components, Wear
Components
Electrical Insulators, Sputtering
Targets, Semiconductor
Components
Key Features
Impact Strength, Net
Shape Fabrication
Strength, Hertzian
Contact Strength,
Structural Reliability, Net
Shape Fabrication
High Purity, Excellent
Mechanical Properties
High Purity, Net Shape
Fabrication
MANUFACTURING CERAMICS

The following methods are used to shape the
ceramics. Please not that (wetted) powder is key.
SINTERING

This is a process in which the small chunks of
powder loose their identity, as the whole (porous)
part is bonded. Temperature and often pressure
are needed. Shrinkage has to be understood.
DIE PRESSING (UNIAXIAL PRESSING)
Most common and rapid for small ceramic
components where speed of manufacture means
more than strength and uniformity.
 Pressure, and densification is variable through
the mold. The object will have varying
properties, and maybe differential shrinkage on
sintering.
 Hot pressing is a combination of sintering and
die-pressing happening at once.

ISOTACTIC PRESSING
Pressure transmitted to
the powder from a
compressed fluid.
 More uniformity, less
porosity
 An elastomer (rubber
mold) serves as the
interface.
 Slower rate of
production.
 Best for cylindrical
shapes, eg. Spark plug.

Hot isotact pressing (HIP)
combines sintering and isotactic
pressing.
EXTRUSION

We add a plasticizing agent, which is later cooked
away during sintering.
SLIP CASTING
Make a slurry by adding liquid to the powder.
 Pour into a porous mold.
 Fluid is absorbed by the mold leaving a drier
layer of powder along the walls.
 Pour off remaining slurry, slip. Opening the
mold reveals the thin-walled object.
 Ready to be sintered.

INJECTION MOLDING

This method holds the most promise for mass
production of complex shapes as evidenced by its
use in producing ceramic turbocharger rotors. A
combination of 60-70% powder mixed with an
organic binder to provide flow is injected into a
mold. Prior to sintering, burnout of the binder
must be done. Current restrictions include small
wall thickness. Because of the cost of equipment,
this is only cost-effective for large volumes, and
for simple shapes, the dry pressing methods are
more cost-effective.
REACTION BONDING
A solid powder and a gas or liquid react during
sintering to densify and bond.
 In Reaction Bonded Silicon Nitride, silicon
powder is fired in the presence of high pressure
nitrogen gas, and the reaction forms Si3N4.
 Advantage: very low shrinkage.
 Disadvantage: high porosity and lower strengths.

MORE REACTION BONDING

Reaction bonded silicon carbide, RBSC, is made
by infiltrating liquid silicon into a compact of
carbon and silicon carbide. The Si reacts with
the carbon to form SiC which then bonds with the
original SiC particles. Pores are filled with liquid
Si. Consequently, high temperature strength
falls off at silicon's melting temperature.
Dimensional changes with RBSC can be less than
1%. One interesting variation is to use carbon
fibers rather than carbon particles.
ENGINE PRODUCTS
Kyocera engine products include cam rollers, turbocharger rotors,
glow plugs, cylinder liners, seals, pistons, piston pins, valve and
valve guides, fuel injection parts and various custom made
components made from a wide selection of advanced ceramic
materials.
Ceramic Piston
Head and
Rings
Ceramic Cam
Roller
Ceramic Seal
Assembly
Ceramic
Turbocharger
Rotor
TEXTILE MANUFACTURING
Kyocera's wide range of ceramic materials, such as
alumina, cermet, sapphire, zirconia and silicon
nitride, coupled with excellent forming and finishing
capabilities provides the basis for expanding the
applications of ceramic textile components.
Guides and Finish Tips
http://americas.kyocera.com/kicc/industrial/textiles.html
SEAL, PUMP AND VALVE
Kyocera seal, pump and valve products
include alumina faucet discs, alumina and
silicon carbide automotive water pump
seals, alumina appliance seals, alumina
blood seals, zirconia containment shells and
various custom made components made from
a wide range of advanced ceramic materials.
Shafts and Valves
Pump Parts
http://americas.kyocera.com/kicc/industrial/seal.html
Hip implants
Advantages of Ceramics
•Low friction
•Biocompatibility
•Compressive strength
http://ceramics.org/ceramictechtoday/tag/capacitor/
http://www.amjorthopedics.com/html/new/0605.asp
Hip implants
Disadvantage of Ceramics
•Low Ductility
http://emedicine.medscape.co
m/article/398669-media
ARMOR
http://www.coorstek.com/resources/8510-091_Ceramic_Armor.pdf
ARMOR
http://www.coorstek.com/resources/8510-091_Ceramic_Armor.pdf
THERMAL SHOCK RESISTANCE
http://americas.kyocera.com/kicc/industrial/seal.html
ALUMINA
Alumina is the most widely used
advanced ceramic material. It
offers very good performance in
terms of wear resistance,
corrosion resistance and strength
at a reasonable price. Its high
dielectric properties are beneficial
in electronic products.
Applications include armor,
semiconductor processing
equipment parts, faucet disc
valves, seals, electronic
substrates and industrial machine
components.
http://americas.kyocera.com/kicc/industrial/types.html
SILICON CARBIDE
Silicon carbide has the highest
corrosion resistance of all the
advanced ceramic materials. It
also retains its strength at
temperatures as high as 1400°C
and offers excellent wear
resistance and thermal shock
resistance.
Applications include armor,
mechanical seals, nozzles,
silicon wafer polishing plates
and pump parts.
http://americas.kyocera.com/kicc/industrial/types.html
SILICON NITRIDE
Silicon nitride exceeds other
ceramic materials in thermal
shock resistance. It also offers an
excellent combination of low
density, high strength, low thermal
expansion and good corrosion
resistance and fracture
toughness.
Applications include various
aerospace and automotive engine
components, papermaking
machine wear surfaces, armor,
burner nozzles and molten metal
processing parts.
http://americas.kyocera.com/kicc/industrial/types.html
ZIRCONIA
Zirconia has the highest
strength and toughness at room
temperature of all the advanced
ceramic materials. The fine
grain size allows for extremely
smooth surfaces and sharp
edges.
Applications include scissors,
knifes, slitters, pump shafts,
metal-forming tools, fixtures,
tweezers, wire drawing rings,
bearing sleeves and valves.
http://americas.kyocera.com/kicc/industrial/types.html
SUMMARY OF MATERIALS







Hot-pressed silicon nitride (HPSN) has the strongest specific
strength (strength/density) at 600oC of any material. It has
excellent thermal shock resistance.
Sintered silicon nitride (SSN) has high strength and can be
formed into complex shapes.
Reaction-bonded silicon nitride (RSBN) can be formed into
complex shapes with no firing shrinkage.
Hot-pressed silicon carbide (HPSC) is the strongest of the silicon
carbide family and maintains strength to very high temperatures
(1500oC).
Sintered silicon carbide (SSC) has high temperature capability
and can be formed into complex shapes
Reaction-bonded silicon carbide (RSBC) can be formed into
complex shapes and has high thermal conductivity.
Partially stabilized zirconia (PSZ) is a good insulator and has high
strength and toughness. It has thermal expansion close to iron,
facilitating shrink fit attachments.