4. Water Water at 300 K and a flow rate of 5 kg/s enters a black, thin-walled tube, which passes through a large furnace whose walls and air are at a temperature of 700 K. The diameter and length of the tube are 0.25 m and 8 m, respectively. Convection coefficients associated with water flow through the tube and airflow over the tube ms are 300 W/m² K and 50 W/m² K, respectively. . . Ignore water tube wall thickness and resistance. -Tube, D = 0.25 m L = 8 m, ε = 1 Air T=700 K m = 5 kg/s Tm,i = 300 K Tm.o -Furnace, Tur 700 K = yllui Use the linearized approximation of radiation effect introduced in previous chapters, i.e., Rrad = ε·σ·A· 152 (T2+T2) (Ts + T∞) to include the radiation between the furnace and tube. Calculate the outlet temperature of the water flow, Tm,o gm

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4. Water at 300 K and a flow rate of 5 kg/s enters a black, thin-walled tube, which passes through a large furnace whose walls and air are at a temperature of 700 K. The diameter and length of the tube are 0.25 m and 8 m, respectively. Convection coefficients associated with water flow through the tube and airflow over the tube misare 300 W/m² K and 50 W/m² K, respectively. . Ignore water tube wall thickness and resistance. Water bas m = 5 kg/s T= 300 K -Tube, D = 0.25 m L = 8 m, ε = 1 Air T=700 K -Furnace, Tur 700 K Tm.o Use the linearized approximation of radiation effect introduced in previous chapters, i.e., Rrad = ε · σ · A · 152 (T2+T2) (Ts + T∞) to include the radiation between the furnace and tube. Calculate the outlet temperature of the water flow, Tm.o