Difference between revisions of "Radiators Temperature"
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| − | + | Calculation of Equilibrium temperature of Radiators | |
| + | 1. Calculating number of particles per second | ||
| + | Frequency: f=1000Hz | ||
| + | Peak current: I=10mAmp=0.01 Amp | ||
| + | Pulse width: ∆t= 50 ns=5*10-8 seconds | ||
| + | So how many electrons we have in each second? | ||
| + | By Q=It, we have | ||
| + | N*e=f*I*∆t | ||
| + | Where Ne is the total electron numbers hits target per second, e is electron charge and f, I and ∆t are given above. | ||
| + | So | ||
| + | N= f*I*∆t/e=1000*0.01*5*10-8/(1.6*10-19)=3.12075*1012 | ||
| + | So, we have around 3.12075*1012 electrons hit radiator per second. | ||
Revision as of 14:22, 29 May 2008
Calculation of Equilibrium temperature of Radiators 1. Calculating number of particles per second Frequency: f=1000Hz Peak current: I=10mAmp=0.01 Amp Pulse width: ∆t= 50 ns=5*10-8 seconds So how many electrons we have in each second? By Q=It, we have N*e=f*I*∆t Where Ne is the total electron numbers hits target per second, e is electron charge and f, I and ∆t are given above. So N= f*I*∆t/e=1000*0.01*5*10-8/(1.6*10-19)=3.12075*1012 So, we have around 3.12075*1012 electrons hit radiator per second.