PLEASE solve using the formulas given Problem:Determine the minimum stop distances from a speed of 62 mph and 75 mph respectively on dry concretewith H, = 0.99 and f = 0.02 for a vehicle with the following data:Static Weights:CG Height:Front: 1610 lbRear: 110014.0 inWheel Base: 101 inFinal Drive Ratio:2.90Tire Size: 13.0 inAir Drag Coefficient:Effective Mass Factor:0.301.00Frontal Projected Area: 22 square feet(Note: you may not need to use all of the data)Solve the problem for two cases: a) neglecting the air resistance, b) considering the air resistance. Simin =Case 1: Air Drag Not Considered:Vo WVdV =2g[Ho + (f + sin 0)]Yb(13)g HoW + (fW + W sin 0)Case 2: Air Drag Considered:-Vo WV.Smin =HoW + (fW + W sin 0 + 0.00118C,AV²)WSd{In[HoW+ (fW +W sin 0 +0.00118C,AV²)]}%3D2(0.00118C,A)Let: Cc = 0.00118C„AVoIn[HoW + (fW + W sin 0 + 0.00118C,AV²)]W%3D2(0.00118CDA)11Smin = -Yb:{In[u,W + (fW + W sin 0 + C,V3)] – In[HoW + (fW + W sin 0)]}2CcFinally,1In 1 +2Cc(14)Note: The unit for Vo is 4Smin = -Yband for Smin is feet.W (Ho + f + sin 0)

Given that, Weight of the vehicle, W=1610+1100=2710 lb The horizontal force acting on the wing,…

Answered: Determine the minimum stop distances…

Determine the minimum stop distances from a speed of 62 mph and 75 mph respectively on dry concrete with H, = 0.99 and f = 0.02 for a vehicle with the following data:

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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1) Calculations for the red dog food can rolling down the slope in the Rube Goldberg design are as follows (we will name it Step 1): Step 1 (calculations are given): Coefficient of friction → μ = 0.14 Mass of the object-m-368 gm = 0.368kg Initial height of the object (red can on top of books) → h=8.89, cm = 0.0889 m Slope of the file folder → 9 = 14° Travelling Distance by the object = 11.5 inch = 0.292 m And length that the object will travel=h/sin 0 = 0.0889/ sin14° = 0.367 m So, the radius of the object →R=0.367 -0.292 = 0.075 m Initial Velocity of red can → u=0 Velocity and Force Calculations for Step 1: -From total mechanical energy conservation: → Initial mechanical energy = final mechanical energy → mg - In case of pure rolling, the velocity of the center of mass: →V=Ro= 0.075 x 14.28 = 1.07 m/s. -Hence the change in force acting on the object for the travel: →F=mgsin0 = 0.368 × 9.81 × sin14° =0.89 N Step 2: The Selective Step (Step 2) in this design and for the questions below…
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In a wind farm the following information is given: Average wind speed = 8 m/s, Rotor diameter = 80 m Coefficient of performance= C,= 0.45, Air Density p = 1.25 Kg/m³ Compute the number of wind turbines in order to produce the equivalent energy of a 600 MW CCGT operating at 80% of the load factor. In example 1, if the regular spacing of turbines is 5 times the rotor diameter, and for a gas generator, tonnes of CO2 / GWh of electrical output is 405, calculate: (i) The number of turbines per Km². (ii) The total ground area required in Km?. (ii) The Per day CO2 emission saved in tonnes.
4) Calculations for the red dog food can rolling down the slope in the Rube Goldberg design are as follows (we will name it Step 1): Step 1 (calculations are given): Coefficient of friction → μ = 0.14 Mass of the object → m = 368 gm = 0.368kg Initial height of the object (red can on top of books) → h=8.89, cm = 0.0889 m Slope of the file folder → 0 = 14° Travelling Distance by the object = 11.5 inch = 0.292 m And length that the object will travel = h/sin 0 = 0.0889/ sin14° = 0.367 m So, the radius of the object → R=0.367 -0.292 = 0.075 m Initial Velocity of red can → u = 0 Velocity and Force Calculations for Step 1: -From total mechanical energy conservation: → Initial mechanical energy = final mechanical energy → mg - In case of pure rolling, the velocity of the center of mass: → V = Ro = 0.075 × 14.28 1.07 m/s. -Hence the change in force acting on the object for the travel: →F=mgsine = 0.368 × 9.81 × sin14° =0.89 N Step 2: The Selective Step (Step 2) in this design and for the…