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1 year ago

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On a snowy day, when the coefficient of friction μs between a car’s tires and the road is 0.50, the maximum speed that the car c

an go around a curve is 20 mph. What is the maximum speed at which the car can take the same curve on a sunny day when μs=1.0?

2 answers:

Tju [1.3M]1 year ago

8 0

The maximum speed at which the car can take the same curve on a sunny day is about 28 mph

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<h3>Further explanation</h3>

Centripetal Acceleration can be formulated as follows:

$\large {\boxed {a = \frac{ v^2 } { R } }$

<em>a = Centripetal Acceleration ( m/s² )</em>

<em>v = Tangential Speed of Particle ( m/s )</em>

<em>R = Radius of Circular Motion ( m )</em>

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Centripetal Force can be formulated as follows:

$\large {\boxed {F = m \frac{ v^2 } { R } }$

<em>F = Centripetal Force ( m/s² )</em>

<em>m = mass of Particle ( kg )</em>

<em>v = Tangential Speed of Particle ( m/s )</em>

<em>R = Radius of Circular Motion ( m )</em>

Let us now tackle the problem !

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<u>Given:</u>

coefficient of friction on a snowy day = μs₁ = 0.50

maximum speed of the car on a snowy day = v₁ = 20 mph

coefficient of friction on a sunny day = μs₂ = 1.0

<u>Asked:</u>

maximum speed of the car on a snowy day = v₂ = ?

<u>Solution:</u>

<em>Firstly , we will derive the formula to calculate the maximum speed of the car:</em>

$\Sigma F = ma$

$f = m \frac{v^2}{R}$

$\mu N = m \frac{v^2}{R}$

$\mu m g = m \frac{v^2}{R}$

$\mu g = \frac{v^2}{R}$

$v^2 = \mu g R$

$\boxed {v = \sqrt { \mu g R } }$

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<em>Next , we will compare the maximum speed of the car on a snowy day and on the sunny day:</em>

$v_1 : v_2 = \sqrt { \mu_1 g R } : \sqrt { \mu_2 g R }$

$v_1 : v_2 = \sqrt { \mu_1 } : \sqrt { \mu_2 }$

$20 : v_2 = \sqrt { 0.50 } : \sqrt { 1.0 }$

$20 : v_2 = \frac{1}{2} \sqrt{2}$

$v_2 = 20 \div \frac{1}{2} \sqrt{2}$

$v_2 = 20 \sqrt{2} \texttt{ mph}$

$\boxed{v_2 \approx 28 \texttt{ mph}}$

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<h3>Learn more</h3>

Impacts of Gravity : brainly.com/question/5330244
Effect of Earth’s Gravity on Objects : brainly.com/question/8844454
The Acceleration Due To Gravity : brainly.com/question/4189441

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<h3>Answer details</h3>

Grade: High School

Subject: Physics

Chapter: Circular Motion

Nana76 [90]1 year ago

7 0

Answer:

28.1 mph

Explanation:

The force of friction acting on the car provides the centripetal force that keeps the car in circular motion around the curve, so we can write:

$F=\mu mg = m \frac{v^2}{r}$ (1)

where

$\mu$ is the coefficient of friction

m is the mass of the car

g = 9.8 m/s^2 is the acceleration due to gravity

v is the maximum speed of the car

r is the radius of the trajectory

On the snowy day,

$\mu=0.50\\v = 20 mph = 8.9 m/s$

So the radius of the curve is

$r=\frac{v^2}{\mu g}=\frac{(8.9)^2}{(0.50)(9.8)}=16.1 m$

Now we can use this value and re-arrange again the eq. (1) to find the maximum speed of the car on a sunny day, when $\mu=1.0$ . We find:

$v=\sqrt{\mu g r}=\sqrt{(1.0)(9.8)(8.9)}=12.6 m/s=28.1 mph$

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2 years ago

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T=2.94*10^-10 N/m.

Explanation:

Biologists think that some spiders "tune" strands of their web to give enhanced response at frequencies corresponding to those at which desirable prey might struggle. Orb spider web silk has a typical diameter of 20μm, and spider silk has a density of 1300 kg/m³.

To have a fundamental frequency at 150Hz , to what tension must a spider adjust a 14cm -long strand of silk?

l=length of the spider silk, 14cm

velocity of wave = √(T/μ)

where T = tension and

μ = mass per unit length)

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1 year ago

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1 year ago

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current = ε / R

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