Answer:
h=20.66m
Explanation:
First we need the speed when the cord starts stretching:
[tex]V_2^2=V_o^2-2*g*\Delta h[/tex]
[tex]V_2^2=-2*10*(-31)[/tex]
[tex]V_2=24.9m/s[/tex] This will be our initial speed for a balance of energy.
By conservation of energy:
[tex]m*g*h+1/2*K*(h_o-l_o-h)^2-m*g*(h_o-l_o)-1/2*m*V_2^2=0[/tex]
Where
[tex]h[/tex] is your height at its maximum elongation
[tex]h_o[/tex] is the height of the bridge
[tex]l_o[/tex] is the length of the unstretched bungee cord
[tex]800h+21*(79-h)^2-63200-24800.4=0[/tex]
[tex]21h^2-2518h+43060.6=0[/tex] Solving for h:
[tex]h_1=20.66m[/tex] and [tex]h_2=99.24m[/tex] Since 99m is higher than the initial height of 79m, we discard that value.
So, the final height above water is 20.66m
Answer: using the conservation of potential energy stored in spring giving that at maximum amplitude velocity becomes zero.
Mgd= 1/2k(d-l)^2..... equation 1
M= 80kg=mass , g= 10m/s^2 =gravity, d=?=length of fully extended bungee rope, l=31m= length of bungee rope before extension, k=42N/m= spring constant
Simplifying equation above gives
2Mgh/k= d^2 - 2dl + l^2 ....eq 2
Substituting figures into the equ above gives
0 = d^2 - 100.1d +961 ...equ 3
Equ3 can be solved since it is a quadratic equation
d= (-b +or- square root (b^2 - 4ac))/2a ....equa4
Where a=1, b= -100.1, c= 961
Substituting figures into eequa4
d= 89.34m
So therefore the height above the river to me when bungee is fully extended is= 110 - 89.34
= 20.66
Explanation: The bungee cord behaves as an ideal spring once it begins to stretch, with spring constant k.
Assuming that it performs simple harmonic motion.
