Why Some Roads Are Made of Styrofoam
Summary
TLDRThis video explores the issue of bumps that often occur at the transition between roads and bridges, a common problem due to differences in how embankments and bridges settle over time. The video discusses various lightweight fill materials, such as expanded shale, foamed glass aggregate, and EPS foam, which are used to reduce the load on soft soils and prevent settlement. The video also highlights the advantages and challenges of using these materials in construction, emphasizing the importance of innovative solutions in civil engineering.
Takeaways
- 🌉 The bump often experienced when driving on or off a bridge is a common issue affecting nearly a quarter of US bridges and is caused by differential settlement between the bridge and the embankment.
- 🚧 Engineers have developed various ground modification techniques to manage the weight of structures on soft soils, with one approach being the use of lightweight fills to reduce the load on the ground.
- 🌲 Wood fibers are a type of lightweight fill that can last up to 50 years before decaying, offering a robust solution for reducing the weight of embankments.
- 🔥 Shredded tires have been successfully used as a lightweight fill in New York, reusing waste material and avoiding issues like spontaneous combustion seen in other states.
- 🏗️ Expanded shale and clay aggregates, as well as foamed glass aggregate, are manufactured lightweight fills that are created by heating materials to form tiny bubbles, reducing their density.
- 🛑 Retaining walls often require the use of lightweight fills to reduce the lateral pressure exerted by the backfill, which can be significant and proportional to the wall's height and the material's density.
- 🚧 The use of lightweight fill in the Port Canaveral expansion project saved approximately $3 million by reducing the size of the required piles and simplifying the structure.
- 🏗️ Cellular concrete, or lightweight concrete, can be pumped directly into place, speeding up construction and reducing the need for heavy equipment, making it suitable for difficult or time-consuming projects.
- 📦 Expanded polystyrene foam, or geofoam, is a lightweight fill material that is easy to handle and place but must be used with caution due to its buoyancy, susceptibility to wind, and reaction to fuel.
- 🌿 Lightweight fills like geofoam are used in various construction projects worldwide, contributing to cost-effective and long-lasting infrastructure, often without the drivers' awareness.
Q & A
What is the common issue faced by drivers when transitioning onto or off of a bridge?
-The common issue is hitting a bump in the road, which can be dangerous and expensive to fix. This bump is often caused by the differential settlement between the bridge and the embankment.
Why do bridges and embankments settle differently?
-Bridges and embankments settle differently because they are structurally distinct. Bridges are relatively lightweight and supported on a rigid foundation, while embankments are essentially heavy piles of soil that can cause the ground to settle, especially on soft soils.
What is one simple solution engineers have proposed to mitigate the settlement of embankments?
-One simple solution is to make embankments less heavy by using lightweight fills, which reduces the load on the foundation and can help prevent the formation of bumps at bridge transitions.
What are some examples of materials used as lightweight fills in embankments?
-Examples of lightweight fill materials include wood fibers, shredded tires, expanded shale and clay aggregates, foamed glass aggregate, cellular concrete, and expanded polystyrene foam (EPS or geofoam).
How do lightweight fills benefit retaining walls?
-Lightweight fills reduce lateral pressure on retaining walls, which can simplify the design and construction of these walls, and potentially reduce the size of the required structural elements.
What is the advantage of using cellular concrete as a lightweight fill?
-Cellular concrete can be pumped directly to where it needs to be, speeding up construction and eliminating the need for heavy equipment. It is also strong enough to handle traffic loads without imposing excessive weight.
What are the potential drawbacks of using expanded polystyrene foam (EPS) in embankments?
-EPS foam may not be suitable for areas with standing water or high groundwater due to buoyancy issues, it is affected by wind due to its light weight, and it can be susceptible to damage from fuel spills due to its solubility in fuel.
How does the use of lightweight fills impact the cost and effectiveness of infrastructure projects?
-While lightweight fills can be more expensive than traditional materials, they can save money on infrastructure projects by reducing the size and complexity of structural elements, thus making the infrastructure more cost-effective and long-lasting.
What is the significance of the graph that the geotechnical engineer provides in the hypothetical situation?
-The graph represents the settlement of the embankment over time and is used to determine how long the embankment must settle before paving the road and opening the bridge, which is crucial for planning construction timelines and minimizing disruptions.
Why might a transportation engineer consider using lightweight fills for a new highway bridge project?
-A transportation engineer might consider using lightweight fills to reduce the settlement time of the embankments, allowing for a quicker construction process and less disruption to the existing traffic and community.
Outlines
🌉 The Bridge Bump Problem
The paragraph discusses the common issue of encountering bumps when driving on or off bridges, which affects nearly a quarter of all bridges in the US. The root cause is the differential settlement between the bridge and the embankment leading up to it. Bridges are typically lightweight and supported by rigid foundations, while embankments are heavy structures made of compacted soil. When these two structures settle at different rates, especially on soft soils, bumps form. Engineers have devised various methods to mitigate this issue, one of which is to reduce the weight of the embankment by using lightweight fills. The video introduces the concept of lightweight fills and sets the stage for discussing various materials and techniques used to address this problem.
🏗️ Innovative Lightweight Fills in Civil Engineering
This paragraph delves into the use of lightweight materials as fills in civil engineering to reduce the load on soft soils and prevent the formation of bumps at bridge transitions. It mentions wood fibers and shredded tires as examples of organic and waste materials that have been repurposed as lightweight fills with a service life of around 50 years. The paragraph also introduces manufactured lightweight fills such as expanded shale and clay aggregates, and foamed glass aggregate, which are created by heating materials to form tiny bubbles that reduce density. These materials are used to lessen the load on foundations, protect underground utilities, and reduce lateral pressure on retaining walls. A case study of Port Canaveral's expansion project in Florida illustrates how using lightweight fill can lead to significant cost savings despite the higher upfront cost of the material.
🚧 Advanced Lightweight Fills and Their Applications
The paragraph explores advanced lightweight fills like cellular concrete and expanded polystyrene foam (EPS or geofoam), which are used in heavy civil construction. Cellular concrete, made by replacing traditional aggregates with lightweight ones or by injecting foam, can be pumped directly into place, speeding up construction and reducing the need for heavy equipment. EPS foam, commonly known as styrofoam, is strong in compression and easy to handle, making it a popular choice for lightweight fills despite its susceptibility to buoyancy, wind, thermal disconnection, and dissolution in fuel. The paragraph highlights the use of these materials in real-world applications, such as the Alaskan Way Viaduct replacement in Seattle, emphasizing their role in creating cost-effective and long-lasting infrastructure.
🍽️ HelloFresh Sponsorship and Practical Engineering
The final paragraph shifts focus from civil engineering to the sponsorship of the video by HelloFresh, a meal kit delivery service. It discusses the personal experience of the video's host, Grady, and his wife using HelloFresh, turning cooking into a date night activity. The paragraph promotes HelloFresh's new 'Fast & Fresh' line, which offers quick and easy meal preparation, and provides a discount code for viewers to try the service. The sponsorship is woven into the video's narrative, highlighting the practicality and convenience that both the engineering solutions and HelloFresh's meal kits provide in their respective domains.
Mindmap
Keywords
💡Settlement
💡Embankment
💡Geotechnical Engineering
💡Lightweight Fills
💡Retaining Walls
💡Lateral Earth Pressure
💡Cellular Concrete
💡Expanded Polystyrene Foam (EPS)
💡Ground Modification
💡Serviceability
Highlights
Nearly 100% of drivers experience a bump when transitioning onto or off a bridge due to settlement issues.
About a quarter of all bridges in the US have settlement issues at the approaches.
Bridges and embankments, despite being adjacent, behave differently structurally, leading to differential settlement.
Embankments are essentially heavy piles of dirt, which can cause the ground to settle, especially on soft soils.
Engineers have developed creative methods to mitigate settlement, including using lightweight materials for embankments.
Lightweight fills can reduce the load on soft soils, preventing bumps and improving road stability.
Wood fibers are used as a lightweight fill with a service life of around 50 years before decay.
Shredded tires have been successfully used as a lightweight fill in New York, avoiding spontaneous combustion issues.
Expanded shale and clay aggregates are manufactured lightweight fills created by heating raw materials to form tiny bubbles.
Foamed glass aggregate is made by heating raw material with a foaming agent to create bubbles, then cooled to form aggregate.
Lightweight fills reduce lateral pressure on retaining walls, simplifying design and construction.
Cellular concrete is a lightweight concrete that can be pumped and placed, speeding up construction.
Expanded polystyrene foam (EPS or geofoam) is used as a lightweight fill, despite its susceptibility to buoyancy and wind.
EPS foam is strong in compression and can support significant weight, such as a car.
Lightweight fills like EPS foam are popular for their ease of placement and cost-effectiveness in certain applications.
Despite potential issues with buoyancy, wind, and chemical sensitivity, EPS foam is used extensively in major projects like in Seattle.
Lightweight fills contribute to cost-effective and long-lasting infrastructure, improving the driving experience.
Transcripts
If you’ve ever driven or ridden in an automobile, there’s a near 100% chance you’ve hit a bump in
the road as you transition onto or off of a bridge. In fact, some studies estimate that
it happens on a quarter of all bridges in the US! It’s dangerous to drivers and expensive to fix,
but the reason it happens isn’t too complicated to understand. It’s a tale (almost) as old as time:
You need a bridge to pass over another road or highway. But,
you need a way to get vehicles from ground level up to the bridge. So, you design an embankment,
a compacted pile of soil that can be paved into a ramp up to the bridge. But,
here’s the problem. Even though the bridge and embankment sit right next to each other,
they are entirely different structures with entirely different structural behavior. A bridge
is often relatively lightweight and supported on a rigid foundation like piles driven or drilled
deep into the ground. An embankment is - if the geotechnical engineers will forgive me for saying
it - essentially just a heavy pile of dirt. And when you put heavy stuff on the ground,
particularly in places that have naturally soft soils like swamps and coastal plains, the ground
settles as a result. If the bridge doesn’t settle as much or at the same rate, you end up with a
bump. Over the years, engineers have come up with a lot of creative ways to mitigate the settlement
of heavy stuff on soft soils, but one of those solutions seems so simple, that it’s almost
unbelievable: just make embankments less heavy. Let’s talk about some of the bizarre materials we
can use to reduce weight, and a few of the reasons it’s not quite as simple as it sounds. I’m Grady
and this is Practical Engineering. In today’s episode, we’re talking about lightweight fills.
This video is sponsored by HelloFresh. More on them later.
The Latin phrase for dry land, “terra firma,” literally translates to firm earth. It’s
ingrained in us that the ground is a solid entity below our feet, but geotechnical engineers know
better. The things we build often exceed the earth’s capacity to withstand their weight,
at least not without some help. Ground modification is the technical term for all
the ways we assist the natural soil’s ability to bear imposed loads, and I’ve covered quite
a few of them in previous videos, including vertical drains that help water leave the soil;
surcharge loading to speed up settlement so it happens during construction instead of afterwards;
soil nails used to stabilize slopes; and one of the first videos I ever made:
the use of reinforcing elements to create mechanically stabilized earth walls.
One of the simplest definitions of design engineering is just making sure
that the loads don’t exceed the strength of the material in question. If they do,
we call it a failure. A failure can be a catastrophic loss of function,
like a collapse. But a failure can also be a loss of serviceability, like a road that becomes too
rough or a bridge approach that develops a major bump. Ground modification techniques mostly focus
on increasing the strength of the underlying soil, but one technique instead involves decreasing the
loads, allowing engineers to accept the natural resistance of a soft foundation.
Let me put you in a hypothetical situation to give you a sense of how this works:
Imagine you’re a transportation engineer working on a new highway bridge that will replace an
at-grade intersection that uses a traffic signal, allowing vehicles on the highway to
bypass the intersection. This is already a busy intersection, hence the need for the bypass,
and now you’re going to mess it all up with a bunch of construction. You design the embankments
that lead up to the bridge to be built from engineered fill - a strong soil material that’s
about as inexpensive as construction gets. You hand the design off to your geotechnical engineer,
and they come back with this graph: a plot of settlement over time. Let’s just say
you want to limit the settlement of the embankment to 2 inches or 5 centimeters
after construction is complete. That’s a pretty small bump. This graph says that, to do that,
you’ll have to let your new embankment sit and settle for about 3 years before you pave the
road and open the bridge. If you put this up on a powerpoint slide at a public meeting in front
of all the people who use this intersection on a daily basis, what do you think they’ll say?
Most likely they’re going to ask you to find a way to speed up the process (politely or
otherwise). From what I can tell from my inbox, a construction site where no one’s doing any
work is a commuter’s biggest pet peeve. So, you start looking for alternative designs and you
remember a key fact about roadway embankments: the weight of the traffic on the road is only
a small part of the total load experienced by the natural ground. Most of the weight is the
embankment itself. Soil is heavy. They teach us that in college. So what if you could replace
it with something else? In fact, there is a litany of granular material that might
be used in a roadway embankment instead of soil to reduce the loading on the foundation,
and all of them have unique engineering properties (in other words, advantages, and disadvantages).
Wood fibers have been used for many years as a lightweight fill with a surprisingly robust
service life of around 50 years before the organic material decays. Similarly,
roadway embankments have been seen as a popular way to reuse waste materials. In particular,
the State of New York has used shredded tires as a lightweight fill with success,
so far avoiding the spontaneous combustions that have happened in other states. There are also some
very interesting materials that are manufactured specifically to be used as lightweight fills.
Expanded shale and clay aggregates are formed by heating raw materials in a rotary kiln to
temperatures above 1000 celsius. The gasses in the clay or shale expand,
forming thousands of tiny bubbles. The aggregate comes out of the kiln in this round shape, and it
has a lot of uses outside heavy civil construction like insulation, filtration, and growing media for
plants. But round particles like this don’t work well as backfill because they don’t interlock. So,
most manufacturers send the aggregate through a final crushing and screening process before
the material is shipped out. Another manufactured lightweight fill is foamed glass aggregate. This
is created in a similar way to the expanded shale where heating the raw material plus a foaming
agent creates tiny bubbles. When the foamed glass exits the kiln, it is quickly cooled, causing it
to naturally break up into aggregate sized pieces. You can see in my graduated cylinders here that
I have one pound or about half a kilogram of soil, sand, and gravel. It takes about twice
as much expanded shale aggregate to make up that weight since its bulk density is about half that
of traditional embankment building materials. And the foamed glass aggregate is even lighter.
All these different lightweight fills can be used to reduce the loading on soft soils below roadways
and protect underground utilities from damage, but they also have a major advantage when used
with retaining walls: reduced lateral pressure. I’ve covered retaining walls in a previous video,
so check that out after this if you want to learn more, but here’s an overview. Granular materials
like soil aren’t stable on steep slopes, so we often build walls meant to hold them back,
usually to take fuller advantage of a site by creating more usable spaces. Retaining
walls are everywhere if you know where to look, but they also represent one of the
most underappreciated challenges in civil engineering. Even though soil doesn’t flow
quite as easily as water does, it is around twice as dense. That means building a wall to
hold back soil is essentially like building a dam. The force of that soil against the wall,
called lateral earth pressure, can be enormous, and it’s proportional both
to the height of the wall and the density of the material it holds back. Here’s an example:
When Port Canaveral in Florida decided to expand terminal 3 to accommodate larger cruise ships,
they knew they would need not only a new passenger terminal building but also a truly colossal
retaining wall to form the wharf. The engineers were tasked with designing a wall that would be
around 50 feet (or 15 meters) tall to allow the enormous cruise ships to dock directly alongside
the wharf. The port already had stockpiles of soil leftover from previous projects,
so the new retaining wall would get its backfill for free. But, holding back 50
feet of heavy fill material is not a simple task. The engineers proposed a combi-wall system
that is made from steel sheet piles supported between large pipe piles for added stiffness,
in addition to a complex tie-back structure to provide additional support at the top of the wall.
When the design team considered using lightweight fill behind the retaining wall, they calculated
that they could significantly reduce the size of the piles of the combi-wall, use a more-commonly
available grade of steel instead of the specialty material, and simplify the tie-back system.
Even though the lightweight fill was significantly more expensive than the
free backfill available at the site, it still saved the project about $3 million dollars
compared to the original design. The fill at Port Canaveral (and all the lightweight fills
we’ve discussed so far) are granular materials that essentially behave like normal soil, sand,
or gravel fills (just with a lower density). They still have to be handled, placed, and compacted to
create an embankment or retaining wall backfill just like any typical earthwork project. But,
there are a couple of lightweight fills that are installed much differently.
Concrete can also be made lightweight using some of the aggregates mentioned earlier in place of
normal stone and sand, or by injecting foam into the mix, often called cellular concrete.
On projects where it’s difficult or time consuming to place and compact granular fill,
you can just pump this stuff right out of a hose and place it right where it needs to be, speeding
up construction and eliminating the need for lots of heavy equipment. There are a few companies that
make cellular concrete, and they can tailor the mix to be as strong or lightweight as needed for
the project. You can even get concrete with less density than water, meaning it floats!
This test cylinder was graciously provided by Cell-Crete so I could give you a close
up look at how the product behaves. Of course we should try and break it. Let’s put it under
the hydraulic press and see how much force it takes. The pressure gauges on my press showed
a force of just under a ton to break this sample. That is equivalent to a pressure
of around 200 psi or 1.4 megapascals, much stronger than most structural backfills. You’re
not going to be making skyscraper frames or bridge girders from cellular concrete,
but it’s more than strong enough to hold up to traffic loads without imposing tons
of weight into a retaining wall or the soft soils below an embankment.
The last lightweight fill used in heavy civil construction is also the most surprising:
expanded polystyrene foam, also known as EPS and colloquially as styrofoam.
When used in construction, it’s often called geofoam, but it’s the same stuff
that makes up your disposable coffee cups, mannequin heads, and packaging material.
EPS seems insubstantial because of its weight, but it’s actually a pretty strong material in
compression. About 7 years ago I used my car to demonstrate the compressive strength of
mechanically stabilized earth. Well, I still have that jack and I still drive that car,
so let’s try the experiment with EPS foam.
This is probably around 5 to 600 pounds,
and there is some deflection, but the block isn’t struggling to hold the weight.
In an actual embankment, the pavement spreads out traffic
loads so they aren’t concentrated like what’s shown in my demonstration to the
point where you would never know that you’re driving on styrofoam.
EPS foam has some cool benefits, including how easy it is to place. The blocks can be lifted by a
single worker, placed in most weather conditions, don’t require compaction or heavy equipment,
and can be shaped as needed using hot wires. But it has some downsides too. This material won’t
work well for embankments that see standing water or high groundwater, because of the buoyancy. The
embankment could literally float away. They’re also so lightweight that you have to consider a
new force that most highway engineers don’t think about when designing embankments: the wind. Also,
because EPS foam is such a good insulator, it creates a thermal disconnect between the
pavement and the underlying ground, making the road more susceptible to icing. Finally,
EPS foam has a weakness to a substance that is pretty regularly spilled onto roadways:
it dissolves in fuel. If a crash, spill, or leak were to happen on an embankment
that uses EPS foam without a properly designed barrier, the whole thing could just melt away.
Even with all those considerations, EPS foam is a popular choice for lightweight fills. We even have
a nice government report on best practices called Guideline and Recommended Standard
for Geofoam Applications in Highway Embankments (if you’re looking for some lightweight bedtime
reading). It was used extensively in Seattle on the replacement of the Alaskan Way Viaduct to
avoid overstressing the landfill materials that underlie major parts of the city. Thousands of
drivers in Seattle and millions of people around the world drive over lightweight embankments,
probably without any knowledge of what’s below the pavement. But the next time you pass over a
bridge and don’t feel a bump transitioning between the deck and roadway embankments,
it might just be lightweight aggregate, cellular concrete, or geofoam below your
tires working to make our infrastructure as cost-effective and long-lasting as possible.
Speaking of lightweight, one of my goals in 2023 is to keep eating healthy meals for dinner.
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something fun and new for the new year. Thank you for watching, and let me know what you think.
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