The question is incomplete, but from the given information it's clear that this is a standard mixing problem. Let [tex]A(t)[/tex] be the amount of salt (in kilograms) in the tank at time [tex]t[/tex].
Then the rate of change of the amount of salt in the tank is described by the differential equation
[tex]\dfrac{\mathrm dA(t)}{\mathrm dt}=\left(0\dfrac{\text{kg}}{\text{L}}\right)\left(40\dfrac{\text{L}}{\text{min}}\right)-\left(\dfrac{A(t)}{200}\dfrac{\text{kg}}{\text{L}}\right)\left(40\dfrac{\text{L}}{\text{min}}\right)[/tex]
[tex]\drac{\mathrm dA}{\mathrm dt}=-\dfrac A5[/tex]
Separating the variables, we get
[tex]\dfrac{\mathrm dA}A=-\dfrac{\mathrm dt}5[/tex]
and integrating both sides yields
[tex]\ln|A|=-\dfrac t5+C[/tex]
[tex]\implies A=Ce^{-t/5}[/tex]
Initially, the tank contains [tex]\left(0.35\dfrac{\text{kg}}{\text{L}}\right)\left(200\text{ L}\right)=70\text{ kg}[/tex] of salt, i.e. [tex]A(0)=70[/tex]. This means you have
[tex]70=Ce^{-0/5}\implies C=70[/tex]
and so the amount of salt in the tank as a function of time is
[tex]A(t)=70e^{-t/5}[/tex]
