Answer:
[tex]\Delta h = 5.212\,m[/tex]
Explanation:
The inelastic collision is modelled by using the Principle of Momentum Conservation:
[tex](3.8\,kg)\cdot (19\,\frac{m}{s} ) + (1.6\,kg)\cdot (-11\,\frac{m}{s} ) = (3.8\,kg + 1.6\,kg)\cdot v[/tex]
The final velocity is:
[tex]v = 10.111\,\frac{m}{s}[/tex]
The maximum height of the composite system is:
[tex](0\,\frac{m}{s})^{2} = (10.111\,\frac{m}{s} )^{2} - 2\cdot (9.807\,\frac{m}{s^{2}} )\cdot \Delta h[/tex]
[tex]\Delta h = 5.212\,m[/tex]
Answer:
5.21m
Explanation:
We are given that;
mass of first ball; m1 = 3.8kg
Speed of first ball; v1 = 19 m/s upwards
Mass of second ball; v2 = 1.6 kg
Speed of second ball; v2 = 11 m/s downwards
From conservation of linear momentum,
m1v1 + m2v2 = m_t•v_t
Where,
m1v1 is momentum of first ball
m2v2 is momentum of second ball
m_t•v_t is the combined momentum of the 2 balls.
Let's make v_t the subject
v_t = [m1v1 + m2v2]/m_t
m_t is the combined mass of both balls.
Since first and second ball are moving in opposite directions, thus;
v_t = [m1v1 - m2v2]/m_t
Thus, m_t = 3.8 + 1.6 = 5.4kg
Thus, plugging in the relevant values, we have;
v_t = [(3.8 x 19) - (1.6 x 11)]/5.4
v_t = [(3.8 x 19) - (1.6 x 11)]/5.4
v_t = (72.2 - 17.6)/5.4
v_t = 54.6/5.4 = 10.11 m/s
Now, from equation of motion,
v² = u² + 2gh
Where u is initial velocity which is now v_t while final velocity v is zero.
Now, since gravity is acting against motion, g = - 9.8m/s²
Thus,
v² = u² + 2gh gives;
0² = 10.11² - (2 x 9.8 x h)
19.6h = 102.212
h = 102.212/19.6
h = 5.21 m
