Assume a very simplified model without Corolis effect, the falloff of the local gravitational field and the like. My answer is no. It is sufficient to look at the vertical velocity of the projectile, because only that determines the time. The periods do not equal, because it is possible to vertically accelerate the projectile to a velocity which is greater than the terminal velocity $v_{term.}$ of the projectile in the medium. Therfore it may take longer for the projectile to come back down because it can only approach $v_{term.}$. I am not sure, though, how it behaves if the initial velocity is lower than $v_{term.}$. My guts say it behaves the same but a different explanation comes into effect. The projectile cannot reach the height which it would if there was no drag. Hence, the projectile cannot reach the initial velocity on the way back to the ground either and it takes longer.
Answer
The quadratic case is much more involved, but for a simple linear term describing drag the height of a projectile shot vertically is given by
$m \ddot{y} + \frac{g}{v_{T}}\dot{y}+g=0$
For graviational acceleration $g$, teminal velocity $v_T$ and mass $m$. Subject to the boundary conditions $y(t=0)$ and $\dot{y}(t=0)=v_0$ this differential equation has the solution
$y = \frac{m v_T}{g}(v_0 + v_T)(1-\exp({-\frac{g t}{m v_T}}))-v_T t$
The particle reaches the apex at $\dot{y}=0$, which after solving for $t$ is given by
$t_{max}= \frac{m v_T}{g} \log(1+\frac{v_0}{v_T})$
Thus we find at time $t=2 t_{Max}$ that
$y(t=2 t_{max}) = \frac{m v}{g}[v_0(v_0+2 v_T)-2 v_T(v_0+v_T) \log(1+\frac{v_0}{v_T})]$
if we find that at this time that $y$ is negative, we conclude the particle fell to ground from the apex quicker than it climbed to it. in term of the ratio $r=\frac{v_0}{v_T}$ this condition is
$\log(1+r) > \frac{r(r+2)}{2(r+1)}$
This is never satisfied and so we conclude that your intuition was correct. In fact these two quantities reach equality only for $r=0$ which is the pathological case of no motion.
I hope this walkthrough is able to offer you insight on how to tackle the more general problem.
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