Respuesta :
a) 893 N
b) 8.5 m/s
c) 3816 W
d) 69780 J
e) 8030 W
Explanation:
a)
The net force acting on Bolt during the acceleration phase can be written using Newton's second law of motion:
[tex]F_{net}=ma[/tex]
where
m is Bolt's mass
a is the acceleration
In the first 0.890 s of motion, we have
m = 94.0 kg (Bolt's mass)
[tex]a=9.50 m/s^2[/tex] (acceleration)
So, the net force is
[tex]F_{net}=(94.0)(9.50)=893 N[/tex]
And according to Newton's third law of motion, this force is equivalent to the force exerted by Bolt on the ground (because they form an action-reaction pair).
b)
Since Bolt's motion is a uniformly accelerated motion, we can find his final speed by using the following suvat equation:
[tex]v=u+at[/tex]
where
v is the final speed
u is the initial speed
a is the acceleration
t is the time
In the first phase of Bolt's race we have:
u = 0 m/s (he starts from rest)
[tex]a=9.50 m/s^2[/tex] (acceleration)
t = 0.890 s (duration of the first phase)
Solving for v,
[tex]v=0+(9.50)(0.890)=8.5 m/s[/tex]
c)
First of all, we can calculate the work done by Bolt to accelerate to a speed of
v = 8.5 m/s
According to the work-energy theorem, the work done is equal to the change in kinetic energy, so
[tex]W=K_f - K_i = \frac{1}{2}mv^2-0[/tex]
where
m = 94.0 kg is Bolt's mass
v = 8.5 m/s is Bolt's final speed after the first phase
[tex]K_i = 0 J[/tex] is the initial kinetic energy
So the work done is
[tex]W=\frac{1}{2}(94.0)(8.5)^2=3396 J[/tex]
The power expended is given by
[tex]P=\frac{W}{t}[/tex]
where
t = 0.890 s is the time elapsed
Substituting,
[tex]P=\frac{3396}{0.890}=3816 W[/tex]
d)
First of all, we need to find what is the average force exerted by Bolt during the remaining 8.69 s of motion.
In the first 0.890 s, the force exerted was
[tex]F_1=893 N[/tex]
We know that the average force for the whole race is
[tex]F_{avg}=820 N[/tex]
Which can be rewritten as
[tex]F_{avg}=\frac{0.890 F_1 + 8.69 F_2}{0.890+8.69}[/tex]
And solving for [tex]F_2[/tex], we find the average force exerted by Bolt on the ground during the second phase:
[tex]F_{avg}=\frac{0.890 F_1 + 8.69 F_2}{0.890+8.69}\\F_2=\frac{(0.890+8.69)F_{avg}-0.890F_1}{8.69}=812.5 N[/tex]
The net force exerted by Bolt during the second phase can be written as
[tex]F_{net}=F_2-D[/tex] (1)
where D is the air drag.
The net force can also be rewritten as
[tex]F_{net}=ma[/tex]
where
[tex]a=\frac{v-u}{t}[/tex] is the acceleration in the second phase, with
u = 8.5 m/s is the initial speed
v = 12.4 m/s is the final speed
t = 8.69 t is the time elapsed
Substituting,
[tex]a=\frac{12.4-8.5}{8.69}=0.45 m/s^2[/tex]
So we can now find the average drag force from (1):
[tex]D=F_2-F_{net}=F_2-ma=812.5 - (94.0)(0.45)=770.2 N[/tex]
So the increase in Bolt's internal energy is just equal to the work done by the drag force, so:
[tex]\Delta E=W=Ds[/tex]
where
d is Bolt's displacement in the second part, which can be found by using suvat equation:
[tex]s=\frac{v^2-u^2}{2a}=\frac{12.4^2-8.5^2}{2(0.45)}=90.6 m[/tex]
And so,
[tex]\Delta E=Ds=(770.2)(90.6)=69780 J[/tex]
e)
The power that Bolt must expend just to voercome the drag force is given by
[tex]P=\frac{\Delta E}{t}[/tex]
where
[tex]\Delta E[/tex] is the increase in internal energy due to the air drag
t is the time elapsed
Here we have:
[tex]\Delta E=69780 J[/tex]
t = 8.69 s is the time elapsed
Substituting,
[tex]P=\frac{69780}{8.69}=8030 W[/tex]
And we see that it is about twice larger than the power calculated in part c.
