Why Buildings Need Foundations
Summary
TLDRIn this episode of Practical Engineering, Grady explores the critical role of foundations in construction, highlighting their necessity for stability and the challenges they face from environmental factors. He examines various types of foundations, from shallow to deep, and explains their purpose in distributing weight, resisting horizontal and uplift forces, and preventing degradation. The video delves into the complexities of designing cost-effective foundations that balance structural integrity with practicality.
Takeaways
- 🏠 The narrator's house had a 75-year-old foundation that needed replacement, highlighting the importance of foundation stability in homes.
- 🏗️ Foundations are crucial for all structures as they provide stability and distribute weight evenly, preventing differential movement and stress.
- 📚 The primary rule for engineers designing foundations is that structures placed on the ground should remain stable and not move.
- 🛠️ There are multiple types of foundations, including pier and beam, strip footing, and raft foundations, each designed to address specific soil conditions and structural needs.
- 🌪️ Foundations must resist not only the weight of structures but also external forces like wind and earthquakes, which can cause uplift and horizontal pressure.
- 🐛 Foundations need to protect against long-term degradation from environmental factors such as moisture, bugs, and fungi that can weaken building materials.
- 🌡️ The ground is subject to changes due to freezing and thawing cycles and soil expansion from moisture, which foundations must account for to prevent structural damage.
- 💧 Deep foundations, such as piles, are used for larger structures or when surface soils are not strong enough, transferring loads to deeper, more stable soil layers or bedrock.
- 🔨 The installation process of piles, such as driving them into the ground, can differ significantly from the static loads they will bear in service, requiring special testing methods.
- 💰 Foundations must be cost-effective, balancing the need for structural stability with economic considerations, as over-engineering can lead to unnecessary expenses.
- 🔬 The script emphasizes the complexity and importance of foundation engineering, which involves understanding soil mechanics, structural loads, and environmental factors.
Q & A
Why did the narrator decide to replace the piers of their house?
-The narrator decided to replace the piers because they were 75 years old and nearing the end of their useful life, which was essential to maintain the structural integrity of the house.
What is the primary rule for engineers designing foundations?
-The primary rule for engineers designing foundations is that when something is put on the ground, it should not move, to prevent stress and potential structural damage.
What is differential movement in the context of structures?
-Differential movement refers to the phenomenon where one part of a structure moves relative to the other parts, which can introduce stress and potentially cause the structure to pull apart.
What is bearing failure and how does it occur?
-Bearing failure occurs when the forces exerted on the soil are high enough to shear through soil particles, causing the soil directly below the load to be forced downward and the surrounding soil to bulge up at the edges.
What is the main function of a foundation in relation to the weight of a structure?
-The main function of a foundation is to evenly distribute the downward force of a structure over a large enough area to reduce bearing pressure and avoid shear failures or excessive settlement.
How do wind and earthquakes affect the loads on structures?
-Wind and earthquakes create additional loads on structures by exerting horizontal pressure, uplift, and rapid fluctuations, which the foundation must resist to prevent lifting or sliding.
What are the challenges that a foundation must overcome in relation to the ground?
-A foundation must overcome challenges such as resisting the effects of long-term degradation and decay from biological factors like termites and moisture, which can lead to mold and rot.
Why is it important for a foundation to reach a deep enough layer in the soil?
-Reaching a deep enough layer in the soil is important to avoid problems caused by water in the subgrade, such as freeze-thaw cycles and expansive clay soil, which can cause a structure to shift or settle unevenly.
What is the difference between deep and shallow foundations?
-Deep foundations rely on piles driven or drilled deep into the earth to stronger soil layers or bedrock, while shallow foundations transfer the structure's weight to the surface of the earth or just below it.
What is the purpose of a basement in the context of a building's foundation?
-A basement serves as a building's foundation by providing additional support for the structure and can also be used for storage or living space. It is usually constructed on a raft or strip footings.
How do driven piles support a structure and what is their advantage?
-Driven piles support a structure by transferring loads at the bottom (end bearing) and along their length through skin friction. Their advantage is that they are installed in the same way they will be loaded, allowing for efficiency in installation.
What is the statnamic testing of piles and how does it differ from traditional static tests?
-Statnamic testing of piles is a method where a mass is accelerated upward using explosives to create an equal and opposite force on the pile. Unlike traditional static tests, which require heavy weights or reaction piers, statnamic testing simulates a static force for a longer duration, making it more representative of actual service conditions without the need for massive infrastructure.
Outlines
🏠 Home Foundation Woes and Engineering Basics
The script begins with a personal account of the narrator's experience with the deteriorating foundation of their 75-year-old house, which led to a decision to replace it. This serves as an introduction to the broader topic of foundations in construction, emphasizing their importance not only for homes but also for job stability in the fields of structural and geotechnical engineering. The narrator, Grady, introduces the concept of Practical Engineering and outlines the primary rule for designing foundations: stability upon the ground. The video promises to delve into the various types of foundations and the challenges they face, such as bearing capacity, settlement, and differential movement, which can cause structural damage if not properly managed.
🏗️ Foundation Design Challenges and Types
This paragraph delves into the multifaceted role of foundations in construction, highlighting six key jobs they must perform. These include distributing structural weight to prevent shear failures or excessive settlement, resisting horizontal and uplift forces from wind and earthquakes, protecting against biological degradation, avoiding issues caused by freeze-thaw cycles and expansive soils, reaching stable soil layers to prevent water-related problems, and combating erosion from flowing water. The narrator also discusses the cost-effectiveness of foundations, noting the balance between durability and economic practicality. The paragraph outlines two main classes of foundations: deep and shallow, with the latter being more common for smaller structures like homes. Shallow foundations, such as pier and beam, strip footings, and raft foundations, are explained, each with their own advantages and limitations.
🔨 Deep Foundations and Pile Installation Techniques
The final paragraph focuses on deep foundations, necessary for larger structures or when surface soils are not strong enough to support the load. Deep foundations rely on piles, which can be driven or drilled into the earth to reach stronger soil layers or bedrock. The paragraph discusses the advantages of driven piles, which are installed in a manner that simulates their final load-bearing configuration. However, it also addresses the challenges of pile installation, such as the difference between dynamic installation forces and static service loads. The narrator introduces the statnamic testing method, which uses explosively accelerated masses to simulate static loads for more accurate testing. The video concludes by emphasizing the complexity and importance of foundation engineering and invites viewer engagement for further topics of interest.
Mindmap
Keywords
💡Foundation
💡Geotechnical Engineering
💡Differential Movement
💡Bearing Pressure
💡Settlement
💡Horizontal Loads
💡Degradation
💡Frost Heave
💡Shallow Foundations
💡Deep Foundations
💡Piles
💡Statnamic Testing
Highlights
The foundation of a 75-year-old house was replaced due to its age and the inevitability of structural issues.
Foundations are crucial for all structures as they provide stability and resist movement.
The primary rule for designing foundations is to ensure that structures placed on the ground do not move.
Differential movement in structures can introduce stress and potentially cause damage.
Foundations must distribute a building's weight to prevent bearing failure or excessive settlement.
Wind and earthquakes impose additional loads on structures that foundations must resist.
Foundations protect structures from long-term degradation caused by environmental factors like moisture and insects.
Soil behavior changes with temperature and moisture, affecting the integrity of a foundation.
Foundations must reach deep enough to avoid issues caused by freezing and thawing cycles or expansive clay soil.
For structures exposed to flowing water, foundations must be designed to prevent erosion.
Foundations need to be cost-effective, balancing the need for durability without over-engineering.
Shallow foundations, like pier and beam or strip footing, are common for smaller buildings and homes.
Raft foundations provide a solid slab to distribute loads and resist ground movement.
Deep foundations, often using piles, are necessary for taller structures or weaker surface soils.
Driven piles are installed by pushing them into the ground, but this method presents challenges in load equivalency.
Statnamic testing offers a solution for accurately testing pile capacity under static conditions.
The video concludes by emphasizing the complexity and importance of foundation engineering in various environments.
Transcripts
When we bought our house several years ago, we fell in love with every part of it except one:
the foundation. At 75 years old, we knew these old piers were just about finished
holding this old house up. This year we finally bit the bullet to have them replaced.
Any homeowner who’s had foundation work done can commiserate with us on the cost
and disruption of a project like this. But homes aren’t the only structures with foundations.
It is both a gravitational necessity and a source of job stability to structural and geotechnical
engineers that all construction - great and small - sits upon the ground. And the ways in which we
accomplish such a seemingly unexceptional feat are full of fascinating and unexpected details.
I’m Grady and this is Practical Engineering. In today’s episode, we’re talking about foundations.
This video is sponsored by CuriosityStream and Nebula. More on them later.
There’s really just one rule for structural and geotechnical engineers designing foundations:
when you put something on the ground, it should not move. That seems like a pretty straightforward
directive. You can put a lot of stuff on the ground and have it stay there. For example,
several years ago I optimistically stacked these pavers behind my shed with the false hope
that I would use them in a landscaping project someday, but their most likely future is to sit
here in this shady purgatory for all of eternity. Unfortunately, buildings and other structures are
a little different. Mainly, they are large enough that one part could move relative to the other
parts, a phenomenon we call differential movement. When you move one piece of anyTHING relative to
the rest of it, you introduce stress. And if that stress is greater than the inherent strength of
the thing, that thing will pull itself apart. It happens all the time, all around the world,
including right here in my own house. When one of these piers settles or heaves more
than the others, all the stuff it supports tries to move too. But doorframes, drywall,
and ceramic tile work much better and last much longer when the surrounding structure stays put.
There are many kinds of foundations used for the various structures in our built environment,
but before we dive into how they work, I think it will be helpful to first talk about what they’re
up against, or actually down against. Of course, buildings are heavy, and one of the most important
jobs of a foundation is to evenly distribute that weight into the subsurface as downward
pressure. Soil isn’t infinitely strong against vertical loads. It can fail just like any other
component of a structural system. When the forces are high enough to shear through soil particles,
we call it a bearing failure. The soil directly below the load is forced downward,
pushing the rest of the soil to either side, eventually bulging up around the edges.
Even if the subsurface doesn’t full-on shear, it can still settle. This happens when the particles
are compressed more closely together, and it usually takes place over a longer period of time.
(I have a video all about settlement that you can check out after this.)
So, job number 1 of a foundation is to distribute the downward force of a structure over a large
enough area to reduce the bearing pressure and avoid shear failures or excessive settlement.
Structural loads don’t just come from gravity. Wind can exert tremendous and rapidly-fluctuating
pressure on a large structure pushing it horizontally and even creating uplift like the
wing of an airplane. Earthquakes also create loads on structures, shifting and shaking them with very
little warning. Just like the normal weight of a structure, these loads must also be resisted
by a foundation to prevent it from lifting or sliding along the ground. That’s job number 2.
Speaking of the ground, it’s not the most hospitable place for many building materials.
It has bugs, like termites, that can eat away at wooden members over time, reducing their
strength. It also has moisture that can lead to mold and rot. My house was built in the 1940s
on top of cedar piers. This is a wood species that is naturally resistant to bugs and fungi,
but not completely immune to them as you can see. So, job number 3 of a foundation is to resist
the effects of long-term degradation and decay that come from our tiny biological neighbors.
Another problem with the ground is that soil isn’t really as static as we think.
Freezing isn’t usually a problem for me in central Texas, but many places in the world see
temperatures that rise and fall below the freezing point of water tens or hundreds of times per year.
We all know water expands when it freezes, and it can do so with prodigious force. When this
happens to subsurface water below a structure, it can behave like a jack to lift it up. Over time,
these cycles of freeze and thaw can slowly shift or raise parts of a structure more than others,
creating issues. Similarly, some kinds of soil expand when exposed to moisture.
I also have a video on this phenomenon, so you have two videos to watch after this one. Expansive
clay soil can create the same type of damage as cycles of freeze and thaw by subtly moving
a structure in small amounts with each cycle of wet and dry. So job number 4 of a foundation is
to reach a deep enough layer that can’t freeze or that doesn’t experience major fluctuations
in moisture content to avoid these problems that come with water in the subgrade below a structure.
Job number 5 isn’t necessarily applicable to most buildings, but there are many types of
structures (like bridges and retaining walls) that are regularly subject to flowing water.
Over time (or sometimes over the course of a single flood), that water can create erosion,
undermining the structure. Many foundations are specifically designed to combat erosion,
either with hard armoring or by simply being installed so deep into the earth
that they can’t be undermined by quickly flowing water.
Job number 6 really applies to all of engineering: foundations have to be cost effective. Could the
contractor who built my house in the 1940s have driven twice as many piers, each one to
three times the depth? Of course it can be done, but (with some minor maintenance and repairs),
this one lasted 75 years before needing to be replaced. With the median length of homeownership
somewhere between 5 and 15 years, few people would be willing to pay more for a house with
500 years of remaining life in the foundation than they would for one with 30. I could have
paid this contractor to build me a foundation that will last hundreds of years... but I didn’t.
Engineering is a job of balancing constraints, and many of the decisions in foundation engineering
come down to the question of “How can we achieve all of the first 5 jobs I mentioned
without overdoing it and wasting a bunch of money in the process?” Let’s look at a few ways.
Foundations are generally divided into two classes:
deep and shallow. Most buildings with only a few stories, including nearly all homes,
are built on shallow foundations. That means they transfer the structure’s weight to the surface of
the earth (or just below it). Maybe the most basic of these is how my house was originally built.
They cut down cedar trees, hammered those logs into the ground as piles, layed wooden
beams across the top of those piers, and then built the rest of the house atop the beams.
Pier and beam foundations are pretty common, at least in my neck of the woods, and they have
an added benefit of creating a crawlspace below the structure in which utilities like plumbing,
drains, and electric lines can be installed and maintained. However, all these individual,
unconnected points of contact with the earth leave quite a bit of room for differential movement.
Another basic type of shallow foundation is the strip footing, which generally consists
of a ribbon or strip of concrete upon which walls can sit. In some cases the floor is isolated from
the walls and sits directly on concrete slab atop the subgrade, but strip footings can also support
floor joists, making room for a crawlspace below. For sites with strong soils, this is a great
option because it’s simple and cheap, but if the subgrade soils are poor, strip footings can still
allow differential movement because all the walls aren’t rigidly connected together. In that case,
it makes sense to use a raft foundation - a completely solid concrete slab that extends
across the entire structure. Raft foundations are typically concrete slabs placed directly on
the ground (usually with some thickened areas to provide extra rigidity). They distribute
the loads across a larger area, reducing the pressure on the subgrade, and they can
accommodate some movement of the ground without transferring the movement into a structure,
essentially riding the waves of the earth like a raft on the ocean (hence the name). However,
they don’t have a crawlspace which makes plumbing repairs much more challenging.
One issue with all shallow foundations is that you still need to install them below the frost
line - that is the maximum depth to which water in the soil might freeze during the harshest part
of the winter - in order to avoid frost heaving. In some parts of the contiguous United States,
the frost line can be upwards of 8 feet or nearly two-and-a-half meters.
If you’re going to dig that deep to install a foundation anyway,
you might as well just add an extra floor to your structure below the ground.
That’s usually called a basement, and it can be considered a building’s foundation
(although the walls are usually constructed on a raft or strip footings as described above).
As a structure’s size increases, so do the loads it imposes on the ground, and eventually
it becomes infeasible to rely only on soils near the surface of the earth. Tall buildings,
elevated roadways, bridges, and coastal structures often rely on deep foundations for support. This
is especially true when the soils at the surface are not as firm as the layers farther below the
ground. Deep foundations almost always rely on piles, which are vertical structural elements that
are driven or drilled into the earth, often down to a stronger layer of soil or bedrock, and there
are way more types than I could ever cover in a single video. Piles not only transfer loads at the
bottom (called end bearing), but they can also be supported along their length through a phenomenon
called skin friction. This makes it possible for a foundation to resist much more significant
loads - whether downward, upward or horizontal - within a given footprint of a structure.
One of the benefits of driven piles is that you install them in somewhat the
same way that they’ll be loaded in their final configuration. There’s some efficiency there
because you can just stop pushing the pile into the ground once it’s able to resist
the design loads. There’s a problem with this though. Let me show you what I mean.
This hydraulic press has more than enough power to push this steel rod into the ground.
And at first, it does just that. But eventually, it reaches a point where the weight of the press
is less than the bearing capacity of the pile, and it just lifts itself up. Easy… (you might think).
Just add more weight. But consider that these piles might be designed to support the weight
of an entire structure. It’s not feasible to bring in or build some massive weight
just to react against to drive a pile into the ground. Instead, we usually use hammers,
which can deliver significantly more force to drive a pile with only a relatively small weight.
The problem with hammered piles is that the dynamic loading they undergo during installation
is different from the static loading they see once in service. In other words,
buildings don’t usually hammer on their foundations. For example, if a pile can
withstand the force of a 5-ton weight dropped from 16 feet or 5 meters without moving, what’s
the equivalent static load it can withstand? That turns out to be a pretty complicated question,
and even though there are published equivalencies between static and dynamic loads, their accuracy
can vary widely depending on soil conditions. That’s especially true for long piles where
the pressure wave generated by a hammer might not even travel fast enough to load the entire member
at the same moment in time. Static tests are more reliable, but also much more expensive because you
either have to bring in a ton (or thousands of tons) of weight to put on top, or you have to
build additional piles with a beam across them to give the test rig something to react against.
One interesting solution to this problem is called statnamic testing of piles.
In this method, a mass is accelerated upward using explosives, creating an
equal and opposite force on the pile to be tested. It’s kind of like a reverse hammer,
except unlike a hammer where the force on the pile lasts only for a few milliseconds,
the duration of loading in a statnamic test is often upwards of 100 or 200 milliseconds.
That makes it much more similar to a static force on the pile without having to bring in
tons and tons of weight or build expensive reaction piers just to conduct a test.
I’m only scratching the surface (or subsurface) of a topic that fills hundreds of engineering
textbooks and the careers of thousands of contractors and engineers. If all the earth
was solid rock, life would be a lot simpler, but maybe a lot less interesting too. If there are
topics in foundations that you’d like to learn more about, add a comment or send me an email,
and I’ll try to address it in a future video, but I hope this one gives you some appreciation
of those innocuous bits of structural and geotechnical engineering below our feet.
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