Draw and explain "entrance region" and "fully developed region" in internal flow.

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...

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

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

The following is the Flow of Activities of the Fully Developed Use Case Description of Create...

The following is the Flow of Activities of the Fully Developed Use Case Description of Create Customer Account. Based on the Flow of Activities, please draw an UML Activity Diagram for the use case. <Flow of Activities> Actor: Customer indicates desire to create customer account and enters basic customer information. Customer enters one or more addresses. Customer enters credit/debit card information. System: 1.1 System creates a new customer. 1.2 System prompts for customer addresses. 2.1 System create addresses. 2.2 System...

The wall shear stress in a fully developed flow portion of a 18-in.-diameter pipe carrying water...

The wall shear stress in a fully developed flow portion of a 18-in.-diameter pipe carrying water is 1.65 lb/ft2. Determine the pressure gradient, ∂p/∂x, where x is in the flow direction, if the pipe is (a) horizontal, (b) vertical with flow up, or (c) vertical with flow down.

A fully developed flow of an oil is taking place in a pipe of diameter 300mm....

A fully developed flow of an oil is taking place in a pipe of diameter 300mm. The velocity atthe centre of the pipe is 2.0m/s. Given the specific gravity and dynamic viscosity of the oilflowing to be 0.8 and 2.5×10−3N s/m2respectively. Determine the following: i Average velocity of water in the pipe. ii Diameter at which the the velocity of water is equal to the average velocity. iii Velocity at 30mmand 40mmfrom the wall.iv Reynolds number of the flow.

Consider fully developed turbulent flow in a two-dimensional diffuser with plane walls. Estimate the opening angle...

Consider fully developed turbulent flow in a two-dimensional diffuser with plane walls. Estimate the opening angle of the diffuser for which the downstream pressure gradient is equal to zero.

Consider the fully developed flow of glycerin at 40C Trough a 70m long, 4 cm diameter,...

Consider the fully developed flow of glycerin at 40C Trough a 70m long, 4 cm diameter, horizontal, circular pipe. if the flow velocity at the centerline is measured to be 6 m/s, determinate the velocity profile and the pressure difference across this 70m long section of the pipe, and the useful pumping power required to maintain this flow.

The velocities of the water at the entrance and at the exit of a hydraulic turbine...

The velocities of the water at the entrance and at the exit of a hydraulic turbine are 10 m/sec and 3 m/sec, respectively. The change in enthalpy of the water is negligible. The entrance is 5 m above the exit. If the flow rate of water is 18,000 m 3 /hr, determine the power developed by the turbine.

Draw the switched capacitor integrator for internal amplifiers. Explain its operation

Draw the switched capacitor integrator for internal amplifiers. Explain its operation

Someone claims that the volume flow rate in a circular pipe with laminar flow can be...

Someone claims that the volume flow rate in a circular pipe with laminar flow can be determined by measuring the velocity near the walls in the fully developed region, multiplying it by the cross-sectional area, and dividing the result by 2. Do you agree? Yes or No?