An orbital ring is visualized as a solid body that transfers any potential energy drop to the whole structure (raising the potential energy on the opposite side). In that way, the ring converts gravitational forces into structural forces inside the ring.

The ring is generally visualized as stationary, relative to the ground. Each segment is held by ground anchors and rope/tether from floating off (and thus, holding the opposing side from falling down).

As a result, the ring is not in orbit.

What does this mean?

There are only two ways to bring a ring down : shear a piece off completely or break enough tethers that the whole thing is coming down.

If a Piece is Sheared Off

Since it has no orbital velocity, sheared-off components will begin to fall immediately. At space station-like altitudes of 400 kilometers, each falling piece has $ 1 times 9.8 times 400,000 approx $ 4 megajoule of potential energy. Scaling up, each ton has about 4 gigajoule of energy.

The component is initially at rest, so frictional protection by the atmospheric heating is going to be significantly reduced. It will take $sqrt{} 400 - 100 km times 1,000 {m over {km}} times 2 div 9.8$ = 247 seconds to hit the Karman line. In that time, the falling load will have built up a velocity of 2,424 meters per second.

I'm ripping off my calculator for Saturn, so this is low, but the frictional heating should be a few hundred degrees (about 700 K). Not enough to melt steel.

When the fragment hits the atmosphere, ${1 over 2} rho v^2 A$ of force will be bleeding away potential energy.

For a 1-ton steel cylinder-shaped piece of debris, about 1 millimeter thick, 3 meters wide, and $1,000 div 5,000 {{kg} over {m^3}} div 3 pi div {1 over 1,000} approx $ 21 meters long, the terminal velocity of the fragment is $ sqrt{} [1,000,000 kg times 9.8] div [21 times 3 times 1.2 {{kg} over {m^3}} times {1 over 2}]$ = 509 meters per second / 1,832 kph. And carrying 129 megajoules of energy.

That's really not so bad. A typical airplane crash has 3658 megajoules of energy.

What If The Whole Thing Comes Down?

To figure this out, I think I need to understand the structure of the orbital ring. The only way I can think of constructing one (and I see it's mentioned this way in other implementations) is to build the whole ring on the ground, and add links, lifting the whole ring with each extension to the circumference.

How much does the ring weigh while resting on the ground. Still sticking with steel 3 meters in diameter, 0.001 meters thick, and 39,940 kilometers long and made of steel at a density of ~5,000 ${kg} over {m^3}$ $approx$ 599 million kilograms. The stress is carried by the walls : about 587 gigapascals. This is way above the compressive strength of steel -- so we'll need to assume some kind of exotic material.

However, it makes sense that after the first part hits, the remainder of the falling ring will be partly supported by the ring structure.

The destruction will be in a 3-meter ring around the planet, and because of shakiness as the thing rattles apart and falls the area that is subject to falling debris or made unsafe to fly (or walk) will be much broader, but I don't think the devastation will be close to civilization-ending.