Use scale analysis to find an expression for 8/x and Nu for flow over a flat plate with athin thermal boundary Layer.Find the expression 8/x = 4.92 Re**Consider the following NACA airfoils:2412, 23012, 23021a. For each of these airfoils, find the L/D ratio for angle of attack of 0, 4, 8 and 12b. For each airfoil find the angle of maximum L/D and find the stall anglec. Find which airfoil will provide the maximum lift for any given geometry and flowconditions

Answered: Image /qna-images/answer/bc5f8dbb-5957-40d0-9aec-327de23b2441.jpg

Answered: Use scale analysis to find an…

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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A two-dimensional airfoil (object 1) is subject to air flow of upstream velocity 28 m/s. The upstream air pressure and temperature are 0.4 atm and 280 K, respectively. The characteristic length of object 1 is 25 mm and its surface temperature is uniform at 320 K. Now, a geometrically similar airfoil (object 2) with different characteristic length 167 mm is placed in water flow. The upstream water temperature is 300 K and the surface temperature of object 2 is uniformly at 310 K. What is the upstream water velocity in m/s for object 2 such that the boundary layer analogy exists between the two cases? Note that liquid water properties can be approximated as those for a saturated liquid at the same temperature. Object 1 Tsl Air Tool V₁ Li Water Too2 V₂ Object 2 L₂ T₁2
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Air at 15°C flows at 10 m/s over a flat plate of length 3 m. Using one-seventh power law of the turbulent flow, what is the ratio of local skin friction coefficient for the turbulent and laminar flow cases? (The kinematic viscosity of air is 1.470 × 10−5 m2/s.) (a) 4.25 (b) 5.72 (c) 6.31 (d ) 7.29 (e) 8.54
Air at 305 K flows at 4 m/s over a flat plate at 350 K. The air properties are as follows: density =1.1 kg/m3, viscosity =18.1×10−6 Pa.s, specific heat capacity =1005 J/kgK, and thermal conductivity =0.024 W/mK. The velocity and temperature profiles are assumed to be linear, giving the local Nusselt number to be Nux = 0.289 Rex1/ 2Pr1/3. The flow will become turbulent at a Reynolds number of 5×105. Assume the width of the plate perpendicular to the air flow is 1 m. At what distance from the leading edge does the flow become turbulent? ________m What is the heat transfer at the point of transition? ___________W What is the total heat transfer along the length of the plate where the flow is laminar? __________W
Calculate the heat transfer from a 60 cm x 60 cm plate on which air flows at 40⁰C and. The plate temperature is 100⁰ C while the air speed is 5 m/s.Find the thickness of the boundary layer at a distance of x = 20 cm, for the same data in problem "number 1 In the picture below"

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