The system shown is at steady state, steady flow. At inlet 1, the following are known: specific volume v1 = 0.00107 m³/kg, volume flow rate, V1 = 0.002 m³/s, and specific enthalpy h1 = 450 kJ/kg; at inlet 2, the following are known: density P2 = 992 kg/m³, pipe diameter d2 = 0.058 m, velocity Vel2 = 1.4 m/s, and specific enthalpy h2 = 703 kJ/kg. If at exit 3, the specific enthalpy is hg = 1,567 kJ/kg, what is the total rate of change of enthalpy of the system? Express the answer in kW. P. da Vel. ha h. Control volume ha V boundary

The system shown is at steady state, steady flow. At inlet 1, the following are known: specific volume v1 = 0.00107 m³/kg, volume flow rate, V1 = 0.002 m³/s, and specific enthalpy h1 = 450 kJ/kg; at inlet 2, the following are known: density P2 = 992 kg/m³, pipe diameter d2 = 0.058 m, velocity Vel2 = 1.4 m/s, and specific enthalpy h2 = 703 kJ/kg. If at exit 3, the specific enthalpy is hg = 1,567 kJ/kg, what is the total rate of change of enthalpy of the system? Express the answer in kW. P. da Vel. ha h. Control volume ha V boundary

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

ChapterMA: Math Assessment

Section: Chapter Questions

Problem 1.1MA

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