There isn’t that much air above you.

from the ground up there is about 1 kilogram of air about every square centimeter.

Or about 1 hectopascal since a pascal is a newton per square meter and a newton is a kg accelerated at 1m/s² (about a tenth of earths gravity).

All that math aside the point is that depending on your cross section there are not millions of pounds above you, just dozens of pounds.

You are used to that and don’t really feel it.

In situations where you don’t feel the air pressure, this is usually overshadowed by other things like lack of oxygen or gravity.

1. There aren’t millions of pounds of air coming down on you. Directly above you is only about 1,000 pounds of air.
2. Air is a gas and therefore doesn’t apply it’s pressure down on you, but in all directions, flowing all around you.
3. Whatever part of it that *is* pushing down on you is a constant, and you normalize it.

It’s not really millions of pounds… 1 atmosphere of pressure is around 14lb per square inch.

The main reason we aren’t stronger without, is because the internal pressure in our body is almost equal to the external atmospheric pressure, so it’s not like our muscles are working to hold that air up. It’s more like your body is a water balloon filled with water, and submerged in water. The balloon doesn’t deform, even though it’s “holding back” the weight of all that external water…

Short answer, we do feel it. Atmospheric pressure is 14.7 psi at sea level. This is the weight of that column of air above you.

So each square foot of ground has 14.7 pounds of air resting on it.

Consider a suction cup. If you press it to a surface, you are clearing the air from between the cup and the surface. Other than a tiny bit of adhesion from the rubber, there are no other forces – the entire reason a suction cup sticks to the surface is that there *isn’t* air pressure on one side but there is on the other. So, the force that you feel when pulling on the section cup – that’s air pressure in action.

If you break the seal, there’s air on both sides, and you can move the suction cup freely. This is what’s happening to our bodies. There’s air on all sides of us, compressing us, but not restricting our motion through the air. 1,000 pounds on one side and 1,000 pounds on the other side equals 0 pounds of net force (but a lot of compression).

That’s why the air pressure doesn’t make us particularly strong. We don’t need to be strong to deal with the air pressure, we just need a biology that can cope with that level of uniform compression. We’re mostly made of water, and water is nearly incompressible, so our bodies can handle pretty huge changes in pressure with no issue – our bodies only encounter mechanical problems when there are uneven forces (pulling or pushing on one part of our body and not another), which creates internal tension and can tear tissue or break bones. The actual problems we encounter at extremely low or high pressures are not these major structural things, but stuff like fluids evaporating into low pressure, gasses being absorbed in the wrong amounts from high pressure, or the few membranes that do maintain some kind of internal pressure not being able to adjust to the extreme value.