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Dielectric window development for the ITER ICRF vacuum transmission line
Liisa Heikinheimo
, Jukka Heikkinen
, Yrjö Hytönen
, Juha Linden
, Markku Kemppainen
VTT Technical Research Centre of Finland
Research output
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Book/Report
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Report
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Keyphrases
Transmission Line
100%
Dielectric Window
100%
Beryllia
100%
Aluminum Oxide
75%
Dielectric Materials
50%
Material Data
50%
Thermal Expansion
50%
Alumina Dielectrics
50%
Electric Field (E-field)
50%
Temperature Distribution
25%
Mechanical Properties
25%
Rutile
25%
Tight
25%
Manufacturing Process
25%
Irradiated Materials
25%
Water Cooling
25%
Cyclic Load
25%
Radiation Resistance
25%
Steel-aluminum
25%
Thermal Stress
25%
Feedthrough
25%
Material Availability
25%
Stress Distribution
25%
Neutron Streaming
25%
Coefficient of Thermal Expansion
25%
Vacuum Vessel
25%
Thermal Properties
25%
Mcnp
25%
Finite Element Code
25%
Field Temperature
25%
Brazing
25%
Filler Material
25%
Cooling Conditions
25%
Radiation Condition
25%
Thermal Pressure
25%
Neutron Radiation
25%
Relative Motion
25%
Ceramic Materials
25%
Conductor Materials
25%
X-shape
25%
Bioshield
25%
Coolant Temperature
25%
Active Filler
25%
Vacuum Brazing
25%
Inner Conductor
25%
Heat Conduction
25%
Nuclear Properties
25%
Thermal Heating
25%
Aluminum Conductor
25%
RF Voltage
25%
ANSYS Finite Element
25%
Titanium-niobium
25%
Vacuum Tightness
25%
Pressure Shock
25%
Heat Conductivity
25%
Maximum Principal Stress
25%
Ceramic-metal Joint
25%
Copper Conductor
25%
Residual Thermal Stress
25%
Expansion Shocks
25%
Fabrication Issues
25%
INIS
ceramics
100%
aluminium oxides
100%
iter tokamak
100%
dielectrics
100%
transmission lines
100%
beryllia
80%
radiations
60%
thermal expansion
60%
data
40%
titanium
40%
metals
40%
manufacturing
40%
cooling
40%
electric fields
40%
shields
40%
neutrons
40%
thermal stresses
40%
dielectric materials
40%
dpa
40%
geometry
20%
heating
20%
aluminium
20%
temperature distribution
20%
mechanical properties
20%
voltage
20%
constraints
20%
growth
20%
distribution
20%
pressure range mega pa
20%
peaks
20%
thermal properties
20%
heat
20%
finite element method
20%
vessels
20%
copper
20%
availability
20%
irradiation
20%
steels
20%
fabrication
20%
purity
20%
dynamic loads
20%
compatibility
20%
water cooled reactors
20%
fillers
20%
shielding
20%
niobium
20%
thermal conduction
20%
beryllium oxides
20%
nuclear properties
20%
brazing
20%
Engineering
Electric Lines
100%
Aluminum Oxide
100%
Dielectrics
80%
Material Data
40%
Electric Field
40%
Full Scale
20%
Manufacturing Process
20%
Cooling Condition
20%
Expansion Coefficient
20%
Filler Material
20%
Irradiated Material
20%
Relative Movement
20%
Shock Pressure
20%
Good Condition
20%
Maximum Principal Stress
20%
Vacuum Brazing
20%
Thermal Stress
20%
Joints (Structural Components)
20%
Feedthrough
20%
Cyclic Loads
20%
Cermet
20%
Growth Temperature
20%
Temperature Distribution
20%
Finite Element Analysis
20%
Material Science
Dielectric Material
100%
Conductor
83%
Aluminum Oxide
83%
Beryllium Oxide
66%
Thermal Expansion
50%
Thermal Stress
33%
Titanium
33%
Niobium
16%
Thermal Conductivity
16%
Brazing
16%
Cyclic Loads
16%
Ceramic Material
16%
Finite Element Methods
16%
Thermal Property
16%
Aluminum
16%
Cermet
16%