Sorry for the late answer, I intended to write this 2 weeks ago but couldn't find the time.

OK, so let's look at the amount of potential energy locked up in our configuration of water spheres: I calculated the radius to be $r=\sqrt{\frac{3}{4\pi }\cdot \frac{1}{17}\cdot 1.35\cdot {10}^{18}{m}^3}=266.644$ km. By symmetry, the potential energy would be the same if all the water were located at the center of these spheres, i.e. 133.322 km above ground. Add negative potential energy of Earth's oceans in its equilibrium state (1.844 km, half the average ocean depth), and we get a total of $g\cdot h=9.81\frac{m}{s^2}\cdot 135166m=1.325\frac{MJ}{kg}$

That's a lot of energy. Let's assume the water is at 0°C initially (most ocean water is in the cold deep layers). To bring all this water to the boiling point, we'd need $100K\cdot 4.186\frac{kJ}{kg\cdot K}=0.4186\frac{MJ}{kg}$. That leaves us $0.9064\frac{MJ}{kg}$ to boil the water. Given the latent heat needed, we can boil $\frac{906.4\frac{kJ}{kg}}{2257.92\frac{kJ}{kg}}=40.14\%$ of the water.

Since Earth's oceans is 262 times as massive as the atmosphere and we boiled almost half of it, we now have an atmospheric pressure of 105 bars, exceeding that of Venus. Of course, the boiling point of water increases with pressure, but the latent heat of vaporization decreases and these two effects pretty much cancel each other out. It does mean however that we'll have a surface temperature of 315°C, approaching that of Venus. In other words, all life on Earth's surface, including the hardiest extremophile bacteria, is toast (or rather steam buns). Absolute overkill actually, since DNA itself disintegrates completely at around 200°C. The only safe place would be deep underground where the heat can't penetrate until it is radiated off into space.

What about seeking refuge in the ISS? Let's see what the atmospheric conditions are at its orbital height of 400 km. We'll use the barometric formula without temperature lapse because this isn't an equilibrium state anyway. ${\rho }_{400km}={\rho }_0\cdot exp\left(\frac{-g\cdot M\cdot h}{R\cdot T_0}\right)=58.94\frac{kg}{m^3}\cdot exp\left(\frac{-9.81\frac{m}{s^2}\cdot 0.018\frac{kg}{mol}\cdot 400000m}{8.314\frac{J}{K\cdot mol}\cdot 588K}\right)=58.94\frac{kg}{m^3}\cdot e^{-14.44}=3.14\cdot {10}^{-5}\frac{kg}{m^3}$This is equivalent to the air density of our current atmosphere at 60 km height.

Here's a video of the Mir space station at 80 km height.