Plot the temperature profile in the fully developed region only of a tube/pipe subjected to a...

Consider an internal flow through a circular tube. Assuming hydrodynamically fully developed condition, the velocity profile...

Consider an internal flow through a circular tube. Assuming hydrodynamically fully developed condition, the velocity profile is given as ??(??) = 2????????(1 ? ??^2/??^2 ). For constant surface heat flux case, a) Calculate NuD for thermally fully developed condition. b) Also, plot variations of tube surface temperature and mean fluid temperature along flow direction (x) including entry and fully developed region. c) Can you plot variation of convective heat transfer coefficient (h) along flow direction (x) including entry and fully...

A 10-mm diameter tube has a maintained surface temperature of 200°C. Engine oil enters the tube...

A 10-mm diameter tube has a maintained surface temperature of 200°C. Engine oil enters the tube at 70°C at a flow rate of 0.5 kg/s and exits at 105°C. Find the length, in m, of the tube and well as the corresponding heat transfer rate, in W. Assume fully developed flow and use the Dittus–Boelter equation to calculate the average Nusselt number. q = .    L =

a tube-within-a-tube heat exchanger operating at steady state is composed of one pipe containing Refrigerant 134a...

a tube-within-a-tube heat exchanger operating at steady state is composed of one pipe containing Refrigerant 134a and another pipe containing an ideal gas with constant specific heat at constant pressure of 1.2 kJ/(kg∙K). The refrigerant 134a enters the heat exchanger in a saturated liquid state and exits the heat exchanger in a saturated vapor state. The temperature and mass flow rate of the refrigerant 134a are -20° C and 3 kgs/s, respectively, at both its inlet and outlet. The ideal...

Liquid water flows in a long pipe of internal diameter of D = 0.01 m at...

Liquid water flows in a long pipe of internal diameter of D = 0.01 m at a mean velocity of V = 0.065 m/s. The pipe is maintained at a constant and uniform surface temperature. Assume the flow is both hydrodynamically and thermally fully developed. For simplicity, evaluate the properties of water at 300 K. Calculate the convective heat transfer coefficient of the flow inside the pipe in W/m2K?

Water flows through a pipe at an average temperature of T =50°C. The inner and outer...

Water flows through a pipe at an average temperature of T =50°C. The inner and outer radii of the pipe are r1 = 6 cm and r2 = 6.5 cm, respectively. The outer surface of the pipe is wrapped with a thin electric heater that consumes 300 W per m length of the pipe. The exposed surface of the heater is heavily insulated so that the entire heat generated in the heater is transferred to the pipe. Heat is transferred...

Water (inlet temperature of 30 C) flows at rate of 3.4 kg/s through a 30 cm...

Water (inlet temperature of 30 C) flows at rate of 3.4 kg/s through a 30 cm diameter aluminium tube. You intend to heat the water to 40 C at the exit of this tube. It is recorded that the surface temperature of the tube is 98 C. Evaluate the length of tube required for this condition. Assume fully developed flow. Then, compare your calculated length with 4 m, comment on the water exit temperature if the tube length is changed...

A concentric tube arrangement, for which the inner and outerdiameters are 80mm and 100mm, respectively, is...

A concentric tube arrangement, for which the inner and outerdiameters are 80mm and 100mm, respectively, is used to remove heatfrom a biochemical reaction occurring in a 1-m-long settlingtank. Heat is generated within the tank at a rate of 10^5W/m^3, and water is supplied to the annular region at a rate of 0.2kg/s Reaction Tank: q(prime)=1*10^5 W/m^3 L=1m mass flow rate = 0.2 kg/s di=80mm do=100mm Part (a): Determine the inlet temperature of the supply water that willmaintain an average tank...

A concentric tube heat exchanger is comprised of a stainless steel (ks = 40 W/mK) inner...

A concentric tube heat exchanger is comprised of a stainless steel (ks = 40 W/mK) inner pipe, NPS 2- nominal schedule 40 size (corresponding to an inner diameter of 52.5 mm and an outer diameter of 60.3 mm), and an outer stainless steel pipe of NPS 3-nominal schedule 40 (ID = 77.9 mm, OD = 88.9 mm). The heat exchanger has an effective length of 35 m. The inner pipe fluid is ammonia (?a = 0.3 · 10?6 m2/s, cpa...

A concentric tube heat exchanger is comprised of a stainless steel (ks = 40 W/mK) inner...

A concentric tube heat exchanger is comprised of a stainless steel (ks = 40 W/mK) inner pipe, NPS 2- nominal schedule 40 size (corresponding to an inner diameter of 52.5 mm and an outer diameter of 60.3 mm), and an outer stainless steel pipe of NPS 3-nominal schedule 40 (ID = 77.9 mm, OD = 88.9 mm). The heat exchanger has an effective length of 35 m. The inner pipe fluid is ammonia (va = 0.3 · 10-6m2/s, cpa =...