Difference between revisions of "Faraday Cup Temperature"
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<math> \sigma = 5.67*10^{-8} \frac {W}{m^2 K^4} </math> is the Stefan-Boltzmann constant. | <math> \sigma = 5.67*10^{-8} \frac {W}{m^2 K^4} </math> is the Stefan-Boltzmann constant. | ||
− | Assume the all beam power goes to one FC rod and radiated | + | Assume the all beam power goes to one FC rod and radiated power is 2 cm^2 (two back sides) we cac calculate the corresponding temperature: |
− | <math> T^4 = \frac {P}{(0.924)(2A)(\sigma)} </math> | + | <math> T^4 = \frac {P}{(0.924)(2A)(\sigma)} = \frac {1.9\ W}{(0.924)(2*10^{-4}\ m^2)(5.67*10^{-8} \frac {W}{m^2 K^4})} = </math> |
The melting temperature of Aluminum is <math> 933.5 K </math>. | The melting temperature of Aluminum is <math> 933.5 K </math>. |
Revision as of 05:18, 14 October 2010
Calculating the temperature of a Faraday Cup Rod
Number of particles per second and corresponding beam power
Assume electron beam parameters at FC location are:
Frequency: f=300 Hz Peak current: I=3 Amps Pulse width: t= 50 ps Beam energy: E=45 MeV
The number of electrons per second at FC location are:
The corresponding beam power for 45 MeV electron beam is:
Temperature calculation
Now apply the Stefan-Boltzmann Law for one Faraday cup rod
Here,
A is the radiated area of the rode.radiatedanradiated
is the Stefan-Boltzmann constant.
Assume the all beam power goes to one FC rod and radiated power is 2 cm^2 (two back sides) we cac calculate the corresponding temperature:
The melting temperature of Aluminum is
.Conclusion
An Aluminum converter that is 1/2 mil thick being struck by a 44 MeV electron beam with a 50 picosecond pulse width, 300 Hz rep rate, and 50 Amp peak current is found to be safe from melting.