- 6.6.1: The temperature distribution within a laminar thermal boundary laye...
- 6.6.2: In flow over a surface, velocity and temperature profiles are of th...
- 6.6.3: In a particular application involving airflow over a heated surface...
- 6.6.4: Water at a temperature of T 25 C flows over one of the surfaces of ...
- 6.6.5: For laminar flow over a flat plate, the local heat transfer coeffic...
- 6.6.6: A flat plate is of planar dimension 1 m 0.75 m. For parallel lamina...
- 6.6.7: Parallel flow of atmospheric air over a flat plate of length L 3 m ...
- 6.6.8: For laminar free convection from a heated vertical surface, the loc...
- 6.6.9: A circular, hot gas jet at T is directed normal to a circular plate...
- 6.6.1: Experiments have been conducted to determine local heat transfer co...
- 6.6.11: A concentrating solar collector consists of a parabolic reflector a...
- 6.6.12: Air at a free stream temperature of T 20 C is in parallel flow over...
- 6.6.13: The heat transfer rate per unit width (normal to the page) from a l...
- 6.6.14: Experiments to determine the local convection heat transfer coeffic...
- 6.6.15: An experimental procedure for validating results of 6.14 involves p...
- 6.6.16: If laminar flow is induced at the surface of a disk due to rotation...
- 6.6.17: Consider the rotating disk of 6.16. A diskshaped, stationary plate ...
- 6.6.18: Consider airflow over a flat plate of length L 1 m under conditions...
- 6.6.19: A fan that can provide air speeds up to 50 m/s is to be used in a l...
- 6.6.2: Consider the flow conditions of Example 6.2 for two situations, one...
- 6.6.21: Assuming a transition Reynolds number of 5 105 , determine the dist...
- 6.6.22: To a good approximation, the dynamic viscosity , the thermal conduc...
- 6.6.23: For the situation described in Example 6.2, the boundary layer can ...
- 6.6.24: Consider a laminar boundary layer developing over a flat plate. The...
- 6.6.25: Consider a laminar boundary layer developing over an isothermal fla...
- 6.6.26: 6 Experiments have shown that the transition from laminar to turbul...
- 6.6.27: An object of irregular shape has a characteristic length of L 1 m a...
- 6.6.28: Experiments have shown that, for airflow at T 35 C and V1 100 m/s, ...
- 6.6.29: Experimental measurements of the convection heat transfer coefficie...
- 6.6.3: To assess the efficacy of different liquids for cooling an object o...
- 6.6.31: Gases are often used instead of liquids to cool electronics in avio...
- 6.6.32: Experimental results for heat transfer over a flat plate with an ex...
- 6.6.33: Consider conditions for which a fluid with a free stream velocity o...
- 6.6.34: Consider the nanofluid of Example 2.2. (a) Calculate the Prandtl nu...
- 6.6.35: For flow over a flat plate of length L, the local heat transfer coe...
- 6.6.36: For laminar boundary layer flow over a flat plate with air at 20 C ...
- 6.6.37: Sketch the variation of the velocity and thermal boundary layer thi...
- 6.6.38: Consider parallel flow over a flat plate for air at 300 K and engin...
- 6.6.39: Forced air at T 25 C and V 10 m/s is used to cool electronic elemen...
- 6.6.4: Consider the electronic elements that are cooled by forced convecti...
- 6.6.41: Consider the chip on the circuit board of 6.39. To ensure reliable ...
- 6.6.42: A major contributor to product defects in electronic modules relate...
- 6.6.43: The defroster of an automobile functions by discharging warm air on...
- 6.6.44: A microscale detector monitors a steady flow (T 27 C, V 10 m/s) of ...
- 6.6.45: A thin, flat plate that is 0.2 m 0.2 m on a side is oriented parall...
- 6.6.46: Atmospheric air is in parallel flow (u 15 m/s, T 15 C) over a flat ...
- 6.6.47: Determine the drag force imparted to the top surface of the flat pl...
- 6.6.48: For flow over a flat plate with an extremely rough surface, convect...
- 6.6.49: A thin, flat plate that is 0.2 m 0.2 m on a side with rough top and...
- 6.6.5: As a means of preventing ice formation on the wings of a small, pri...
- 6.6.51: A circuit board with a dense distribution of integrated circuits (I...

# Solutions for Chapter 6: Introduction to Convection

## Full solutions for Introduction to Heat Transfer | 6th Edition

ISBN: 9780470501962

Solutions for Chapter 6: Introduction to Convection

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