Answer :
Answer:
[tex]N=157.143\:\:N[/tex]
Explanation:
We firstly determine the impulse momentum of ball B in tangential direction.
[tex]m_B v_0_f=m_B v_B_t\\\\v_B_t=v_0_f=10\sin(40^\circ)=6.428\:\:m/s[/tex]
Then we simplify the equation for impulse momentum for ball A and ball B.
[tex]m_B v_0 = m_A v_A + m_B v_B_x + m_B v_B_t\\\\2*10=2v_A+2[v_B_n\cos(40^\circ)+6.428\sin(40^\circ)]\\\\2v_A+1.532v_B_n=11.736[/tex]
Now the equation for coefficient of restitution is determined to solve above equation with 2 equations 2 unknowns.
[tex]v_B_n-v_A_n=e(0-v_0_n)\\\\v_B_n-v_A\cos(40^\circ)=-0.8*10cos(40^\circ)\\\\v_B_n-0.776v_A=-6.128[/tex]
Hence,
[tex]v_A=6.655\:\:m/s\\\\v_B_n=-1.03\:\:m/s[/tex]
Now we apply Conservation of Energy Principle.
[tex]T_1+V_1=T_2+V_2\\\\\frac{1}{2} m_Av_A^2+0=\frac{1}{2} m_Av_2^2+m_Agh_2+\frac{1}{2} kx_2^2\\\\h_2=-0.4\:\:m, \:\:thus, \:\:x_2=1.2-0.4=0.8\:\:m\\\\\frac{1}{2} *2*(6.655)^2=\frac{1}{2} *2v_2^2+2*9.81*(-0.4)+\frac{1}{2} *100*(0.8)^2\\\\44.289=v_2^2-7.848+32\\\\v_2=4.487\:\:m/s[/tex]
Finally, we apply Newton's 2nd Law.
[tex]\sum F=ma_n=m\frac{v_2^2}{\rho}\\\\N-mg-kx_2=m\frac{v_2^2}{\rho}\\\\N=m_A(g+\frac{v_2^2}{\rho}})+kx_2=2*(9.81+\frac{(4.487)^2}{0.7})+100*0.8\\\\N=157.143\:\:N[/tex]
