The Composite Radiosity and Gap (CRG) Model of Thermal Radiation
The Composite Radiosity and Gap (CRG) Model of Thermal Radiation
The Composite Radiosity and Gap (CRG) Model of Thermal Radiation
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STAR<br />
PROSTAR 3.10<br />
13-Sep-01<br />
TEMPERATURE<br />
RELATIVE<br />
CELSIUS<br />
ITER = 6957<br />
LOCAL MX= 771.7<br />
LOCAL MN= 37.00<br />
750.0<br />
700.0<br />
650.0<br />
600.0<br />
550.0<br />
500.0<br />
450.0<br />
400.0<br />
350.0<br />
300.0<br />
250.0<br />
200.0<br />
150.0<br />
100.0<br />
50.00<br />
Z<br />
Y<br />
X<br />
Figure 1. <strong>The</strong> calculated temperature field inside <strong>of</strong> the confined burner. (°C)<br />
STAR<br />
PROSTAR 3.10<br />
28-Nov-01<br />
SC 2-R<br />
ITER = 6957<br />
LOCAL MX= 0.4887E+05<br />
LOCAL MN= 573.9<br />
0.4200E+05<br />
0.3900E+05<br />
0.3600E+05<br />
0.3300E+05<br />
0.3000E+05<br />
0.2700E+05<br />
0.2400E+05<br />
0.2100E+05<br />
0.1800E+05<br />
0.1500E+05<br />
0.1200E+05<br />
9000.<br />
6000.<br />
3000.<br />
-0.3906E-02<br />
Z<br />
Y<br />
X<br />
Figure 2. <strong>The</strong> calculated radiosity field inside <strong>of</strong> the confined burner. (W/m 2 )