Assume the temperature of the exhaust in an exhaust pipe can be approximated by T = To (1 + ae-bx) [1 + c cos(@t)], where To = 100 °C, a = 3, b = 0.03 m²¹, c = 0.066, and w = 100 rad/s. If the exhaust speed is a constant 3 m/s, determine the time rate of change of temperature of the fluid particles at (a) x = 0 and (b)x= 4 m when t = 0. DT (a) °C/s (b) Dt DT Dt i °C/s

Elements Of Electromagnetics
7th Edition
ISBN:9780190698614
Author:Sadiku, Matthew N. O.
Publisher:Sadiku, Matthew N. O.
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Assume the temperature of the exhaust in an exhaust pipe can be approximated by
T = To (1 + ae-bx) [1 + c cos(@t)],
where To = 100 °C, a = 3, b = 0.03 m ¹, c = 0.066, and w = 100 rad/s. If the exhaust speed is a constant 3 m/s, determine the time rate of
change of temperature of the fluid particles at (a) x = 0 and (b) x = 4 m when t = 0.
DT
(a)
°C/s
(b)
Dt
DT
Dt
=
°C/s
Transcribed Image Text:Assume the temperature of the exhaust in an exhaust pipe can be approximated by T = To (1 + ae-bx) [1 + c cos(@t)], where To = 100 °C, a = 3, b = 0.03 m ¹, c = 0.066, and w = 100 rad/s. If the exhaust speed is a constant 3 m/s, determine the time rate of change of temperature of the fluid particles at (a) x = 0 and (b) x = 4 m when t = 0. DT (a) °C/s (b) Dt DT Dt = °C/s
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