When most people think property damage, they
think about natural disasters. But what if I told you, there’s a slow-moving
geologic phenomenon that causes more damage in the United States than earthquakes, floods,
hurricanes, and tornadoes combined? Hey I’m Grady and this is Practical Engineering. Today we’re talking about expansive soils. If you’ve ever been to a place where the
ground looks like this, or if you’ve been in a building that looks like this or this,
there’s a good chance you were in a place that had expansive soils. Just like these dinosaur toys, certain types
of clay soils change their volume depending on moisture content. They swell when they get wet, and shrink as
they dry. This is a microscopic mechanism where the
shape and arrangement of the molecules actually change according to the amount of water mixed
in. And, large portions of the U.S. gulf coast
and great plains have these kinds of soils. If you’re starting a foundation repair or
road paving business, this is an important map for one very good reason: expansive
soils break stuff. Movement on its own, and especially very slow
movement, is usually not a problem for structures. This is why we can lift buildings and even
move them to new locations. What causes damage is differential movement. This is where certain parts of a structure
move relative to each other. Differential movement leads to sticking doors
and windows, cracked walls, and just general out-of-plumbness. And this is why expansive soils are so insidious,
because they don’t expand and contract evenly. For example, if your house sits on a concrete
slab and you haven’t had any rain, the soils around the edges of the slab that are more
exposed will dry out and shrink while the interior remains moist. Now you’ve got a foundation with no support
around the edges. This breaks one of the fundamental laws of
civil engineering, which says, and I quote, “You gotta have dirt underneath your concrete.” Expansive clay isn’t just an issue for buildings. All kinds of infrastructure are at risk of
damage from a shifting foundation. Leaking pipes can cause swelling of the soil,
pulling apart joints and eventually leading to issues like sinkholes. Rain water infiltrating through the cracks
in roadways causes localized areas of swelling, making the road bumpy and uneven. Not even sidewalks, and by proxy rollerbladers,
are spared. When designing to account for expansive clays,
engineers not only have to know how much the soil can change in volume, but also how hard
it can push on anything sitting above, also known as swell pressure. So I’ve rigged up a little test so that
we can see not only how soil swells, but also how much pressure it can exert. This apparatus called an oedometer. It’s similar to a hydraulic cylinder, except
I’m using dirt instead of oil, and I’ll use a dial indicator to measure how far the
sample is able to move the piston. If you work in a soil laboratory, I’ll just
apologize now for the rest of this video. For my first test, I’ve got some soil straight
from my own backyard. After all, there’s no place like a geologic
unit containing abundant clay with high swelling potential. I put this in the oven to dry it out first,
don’t tell my wife. Just kidding she knows who she married. Now let’s put it in the apparatus and watch
what happens. As it saturates, the soil expands over time,
eventually reaching a 10% increase in volume over its dry state. Trust me, that’s enough to put a crack in
the drywall. But, it’s really not that dramatic on video. So, to help illustrate these concepts a little
better, I’ve got a bag of instant viral video. That’s right I’m talking about Superabsorbent
Polymer Beads, also known as Orbeez. These beads behave very similar to expansive
soils, except they’re way cooler than dirt in almost every way, even for a civil engineer. First I tested these with no confining pressure,
and went a bit overboard. You can imagine if you built a house on this,
you might get motion sickness every time it rains. It would wreak havoc on your structure. I tried it again with fewer orbeez, but it
was still too much. This is an exaggerated view of what happens
as water penetrates the subsurface and saturates an expansive soil. It’s hard to imagine anything that could
avoid damage in this environment. So, let’s add some weight - and fewer orbeez
this time so I don’t max out the range of my dial indicator. You can see that these fishing weights hardly
make a difference. And that makes sense, right? A house probably puts more pressure on the
ground below it than a few fishing weights. What about ten times that weight? It takes them a lot longer, but the orbeez
are still able to swell to their full dimensions under this 20lb barbell, which is about the
most my little acrylic oedometer can handle. This is not just the case for orbeez by the
way. Some clay soils have swell pressures on the
order of megapascals (that’s hundreds of pounds per square inch). So you can see how big of a challenge these
expansive soils can pose. There are lots of ways that engineers try
to mitigate damage from these kinds of soils. You can simply remove all the expansive clay
and bring in better soils for your project. You can grade the site so that water drains
away from your structure, keeping moisture fluctuations down. You mix chemicals into the soil that limit
its ability to absorb water. Finally, you can simply to build heavy enough
to counteract the swell pressure and keep the soil from expanding. But as we saw in the demonstration, even a
small amount of soil or in this case a colorful soil surrogate, can lift a lot of weight. I’m leaving out the simplest solution, which
is simply to avoid expansive soils, because it’s generally not feasible. It may be true in the parable that the wise
man built his house on rock, but some civil engineer had to build a road to that guy’s
house, and the engineer didn’t get to choose what kind of soil was on the way. Expansive soils are not a particularly newsworthy
or exciting hazard (unless you’re the type of person who makes videos about dirt in your
garage), but they still cause a tremendous amount of damage to buildings and the public
infrastructure we rely on every day. They are one of the many factors taken into
account when designing civil structures and the subject of ongoing research to find cost-effective
and sustainable practices for mitigating the damage they cause. Thank you for watching, and let me know what you think!
So that's why all the roads in Dallas are terrible!
My girlfriend did testing for a Geotech company. Soil density testing for major construction projects and stuff like that. This is so far the easiest to understand explanation of this process that I have ever heard.