(a) Original momentum of the fullback: 285 kg m/s
The original momentum of the fullback is equal to the product between his velocity and its mass:
[tex]p_i=mv[/tex]
where:
m = 95 kg is the mass
v = 3.0 m/s is the velocity
Substituting the numbers into the formula, we find
[tex]p_i=(95 kg)(3.0 m/s)=285 kg m/s[/tex]
(b) Impulse exerted on the fullback: -285 kg m/s
The impulse exerted on the fullback is equal to his variation of momentum:
[tex]I=\Delta p=p_f -p_i[/tex]
where:
[tex]p_f = 0[/tex] is the final momentum of the fullback (zero because he comes to a stop)
[tex]p_i = 285 kg m/s[/tex] is the initial momentum
Substituting,
[tex]I=0-(285 kg m/s)=-285 kg m/s[/tex]
(c) Impulse exerted on the tackler: 285 kg m/s
The total momentum of the fullback and the tackler must be conserved:
[tex]p_i + P_i = p_f + P_f[/tex]
where [tex]p_i[/tex] and [tex]p_f[/tex] are the initial and final momentum of the fullback, while [tex]P_i, P_f[/tex] are the initial and final momentum of the tackler.
We can re-arrange the equation as follows:
[tex]P_f - P_i = p_i -p_f\\\Delta p_{tackler} = -\Delta p_{fullback}\\I_{tackler} = -I_{fullback}[/tex]
which means that the impulse exerted on the tackler is the negative of the impulse exerted on the fullback, so:
[tex]I=-(-285 kg m/s)=285 kg m/s[/tex]
(d) Average force exerted on the tackler: 335.3 N
The impulse on the tackler is equal to the product between the average force and the time of the collision:
[tex]I=F \Delta t[/tex]
Since [tex]\Delta t=0.85 s[/tex], we can find the average force:
[tex]F=\frac{I}{\Delta t}=\frac{285 kg m/s}{0.85 s}=335.3 N[/tex]
(a) The original momentum of the fullback is 285 kgm/s.
(b) The impulse exerted on the full back is -285 kgm/s.
(c) The impulse exerted on the tackler is 285 kgm/s.
(d) The average force exerted on the tackler is 356.25 N.
The given parameters;
The original momentum of the fullback is calculated as follows;
[tex]P_i = mv\\\\P_i = 95 \times 3\\\\P_i = 285 \ kg.m/s[/tex]
The impulse exerted on the full back is calculated as follows;
[tex]J = \Delta P = mv_f - mv_i\\\\J = m(v_f - v_i)\\\\J = 95(0-3)\\\\J = - 285 \ kg.m/s[/tex]
The impulse exerted on the tackler is calculated as follows;
[tex]J_1 = -J_2\\\\J_2 = -J_1\\\\J_2 = -(-285 \ kgm/s)\\\\J_2 = 285 \ kgm/s[/tex]
The average force exerted on the tackler is calculated as follows;
[tex]F = \frac{\Delta mv}{t} \\\\F = \frac{285}{0.8} \\\\F = 356.25 \ N[/tex]
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