Answer:
The reaction force is 2.776kN as the force is negative and on the left of the Control Volume this indicates that the coupling in in tension.
Explanation:
By applying the continuity equation as
[tex]A_1V_1=A_2V_2\\[/tex]
By simplifying the equation
[tex]V_1=V_2(\frac{D_2}{D_1})^2[/tex]
Here
V_2=43 m/2
D1=78 mm
D2=20 mm
So the velocity is given as
[tex]V_1=V_2(\frac{D_2}{D_1})^2\\V_1=2.827 m/s[/tex]
Now by applying the equation of momentum in x direction
[tex]R_x=-P_{1g}A_1+\rho V_1^2A_1-\rho V_2^2A_2[/tex]
Here
- A1 is given by [tex]\pi D_1^2/4=\pi (78/1000)^2/4=0.00477 m^2[/tex]
- ρ is the density of water given as 1000 kg/m3
- V1 is calculated above as 2.827 m/s
- V2 is given as 42 m/s
- A2 is given by [tex]\pi D_2^2/4=\pi (20/1000)^2/4=0.00031 m^2[/tex]
Substituting the values in the equation gives
[tex]R_x=-P_{1g}A_1+\rho V_1^2A_1-\rho V_2^2A_2\\R_x=-(470 \times 10^3)(0.00477)+(1000) (2.827)^2(0.00477)-(1000) (43)^2(0.00031)\\R_x=-2776.96 N[/tex]
So the reaction force is 2.776kN as the force is negative and on the left of the Control Volume this indicates that the coupling in in tension.
