Reaching Breaking Point: Materials, Stresses, & Toughness: Crash Course Engineering #18

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In 1912, the Titanic set off for her maiden voyage across the Atlantic Ocean.

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The ship’s builders were convinced that even in the most disastrous collision at sea,

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the ship could float for two to three days, enough time for nearby ships to come to its rescue.

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But on April 14th, the Titanic struck a massive iceberg and in just three short hours the ship had sunk.

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The collision fractured the ship’s hull, cracking it like a china plate, as well as shearing off the rivets holding it in place.

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And as we all know, it was an absolute disaster.

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One of our most important tasks as engineers is to try and avert catastrophes like these.

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You see, when it comes to structures, tools and equipment, we need to make sure they’re made of the right stuff.

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That means taking a closer look at the materials they’re made of.

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So this episode is really going to test your, uh mettle.

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[Theme Music]

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If a material exists, there’s a pretty good chance an engineer has thought about using it at some point.

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As far back as two and a half million years ago, early humans were using the materials around them, primarily stone and wood, to build tools like hammers and axes.

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These days, we’ve developed totally new materials.

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There’s aerogel, for example, which is an ultra-light substance that can withstand high temperatures.

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Not to mention graphene, a one-atom-thick sheet of carbon atoms that’s stronger than steel and superb at conducting heat and electricity.

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While those advanced materials might be used more widely in the future, today, most materials that engineers work with can be categorized into three groups.

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Metals and their alloys; ceramics and glass; and polymers.

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Which material is best suited for a job depends on its properties, and how those properties affect it in practice.

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More specifically, whatever we’re using, it’s vital to know the material’s mechanical properties.

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Mechanical properties relate to how a material’s shape changes when a force is applied to it.

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To make better sense of this, it helps to have a concrete example in mind.

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But we’re not actually going to use concrete. At least not yet.

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Instead, we’ll consider a steel beam, like the kind widely used in civil engineering and construction.

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Of course, we could make beams out of all kinds of materials, and the resulting beams would have different properties.

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But no matter what you’re making them out of, there’s one important thing to know: no material is perfectly rigid.

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As long as you apply a large enough force, a beam will deform and change shape, even if only internally.

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Some things you encounter in everyday life might seem totally rigid because the change in shape is so small.

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But when that stops being the case, it can have dramatic consequences.

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Something that all engineers aim to avoid is failure .

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Not in the sense of whether or not you do things exactly right all the time.

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Even engineers aren’t perfect, and sometimes we get things a little wrong.

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It’s all part of the learning process.

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When it comes to materials, the word ‘failure’ describes the point at which a material breaks.

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And unlike messing up a few problems on your math homework, this is the kind of failure that isn’t worth the learning opportunity!

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In a system like a car, where everything depends on the structural integrity of the materials, the outcome could be fatal.

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So to prevent critically dangerous situations, engineers characterize a material’s mechanical properties so they can prevent it from failing.

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If you’re using a beam to construct a building, those properties are crucial for keeping the structure standing tall.

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This is where stress comes in.

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We touched on what stress means in an engineering context when we looked at fluids: it’s the force applied over a particular area of the material.

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We can apply this type of stress to our beam in three distinct ways:

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There’s compressive stress, which pushes in on the ends of a material.

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Then there’s tensile stress, which stretches and potentially elongates it.

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And finally, there’s shear stress, where you push sideways on a material in opposite directions.

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To measure the effects of this stress on our beam, we look at its strain.

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Strain is how much the beam’s length changes in a particular direction.

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When we were discussing stresses on liquids, the level of deformity was linked to the liquid’s viscosity: how easily it flowed in response to pressure.

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In a materials context, the level of deformity is a little more complicated.

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But like so many things in engineering, visualizing it as a graph can help.

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Let’s take the beam and put it in an extensometer, a piece of equipment with an awesome name that will apply tensile strength to the beam and measure its strain.

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To graph what’s happening, we’ll put the level of stress we’re applying, represented by the greek letter ‘sigma,’ on the vertical axis.

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Then we’ll put the strain on the horizontal axis.

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When the stress we’re applying is perpendicular to the ends of the beam, as in the extensometer,

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the resulting change in length is called the normal strain.

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That’s represented with the letter ‘epsilon.’

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As we increase the stress on the object, the material will begin to display signs of strain, changing its length.

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The amount of stress a material is subjected to before it undergoes a particular amount of strain –

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in other words, the slope of the line – is known as the modulus of elasticity.

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That quantity is a measure of how resistant our material is to bending and stretching.

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The closer the line is to vertical, the higher the modulus.

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To make sense of the units here, stress is measured in gigapascals because it’s a force applied over an area,

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which gives it the same dimensions as pressure.

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Strain, meanwhile, is a ratio of two lengths, so it’s a dimensionless quantity – it has no units.

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Putting that all together, the modulus of elasticity has units of gigapascals.

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But what does the modulus actually mean?

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Let’s compare beams made of two different materials: rubber and concrete.

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Rubber has a modulus of elasticity of just 0.01 gigapascals, while concrete has a modulus of 30.

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That means for a given amount of stress applied to each material, the rubber will have a proportional change in length 3,000 times that of the concrete!

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That’s not surprising, right?

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We know it’s easier to stretch rubber than concrete.

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So the modulus of elasticity, which you can measure from the stress-strain diagram,

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gives you an idea of how much the material resists a change in shape under an applied stress.

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For example, in units of gigapascals, the modulus of glass is around 50, while brass is around 100.

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Steel is higher still, at around 200, while diamond clocks in at a whopping 1,220 gigapascals!

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So far, all the lines on the stress-strain diagram have been straight, with constant slopes.

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But as you apply even more stress, that relationship breaks down, and the material will begin to deform and stretch along its cross section as well as its length.

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We call that point the yield stress.

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For example, apply enough tensile strength to a bar of clay and eventually it gets thinner in the middle as it stretches to meet the demands of high tensile stress.

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Finally, if we apply enough tensile stress, the material breaks apart entirely and undergoes failure.

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And the exact same thing can happen to our steel beam, too!

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The stress-strain curve tells you about another important property for avoiding failure and determining a material’s suitability: its toughness.

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A material’s toughness is the amount of energy it can absorb before it undergoes failure.

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On our diagram, that’s represented by the total area under the curve for the material, from the origin to the failure point.

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If you know a bit of calculus, you’ll recognise this as the integral of the stress-strain curve.

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Toughness isn’t the same as strength, though!

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A material might be very strong, with a very high modulus of elasticity, but break after only a small amount of strain.

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On the other hand, a material might be able to strain a long distance without breaking,

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but have a very low modulus of elasticity, like Play-Doh.

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Toughness is a balance between the two.

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And while a tough material might be useful for making the foundations of a building,

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in other applications it might be something you want to avoid!

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For example, by adding carbon to the steel beam, you can give it a greater yield stress.

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It barely deforms under a single impact, but that also makes it more brittle.

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Meanwhile, low carbon steel has a low modulus of elasticity, it will deform much more quickly

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because it has a low yield stress, but that makes it more ductile, so it’s more useful for shaping and welding.

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But neither of those options maximizes the toughness of steel!

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Toughness would be finding the middle ground where you maximize the area under the curve,

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so the steel is able to absorb as much energy as possible before fracturing.

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A measurement that comes in handy for measuring this is the Charpy impact test,

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which tells us the toughness of our material by whacking it with a hammer.

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No, seriously.

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The Charpy test measures toughness by taking a small sample of material and striking it with a hammer on a pendulum and trying to break it.

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The height you drop the hammer from and the height that the hammer swings up to after smashing through the material

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can determine how much energy the hammer lost breaking the sample.

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And that tells you how tough the material is.

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While not all material tests are quite as fun to perform,

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there are lots of different mechanical properties to consider in materials that could make them totally great for the job at hand or just completely useless.

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For example, there’s hardness, which is how much your material deforms in a particular location – that is, how easily you can dent it.

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Measuring hardness is simple enough: you use a device called an indenter to apply a localized load to your material and see how much it gets dented.

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Pretty straightforward!

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Another mechanical property which can be a good or a bad thing, depending on the situation, is creep strength.

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Which thankfully has nothing to do with the Minecraft monster.

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Creep strength is how much a material resists deforming or, to use the engineering term, resists creep under long term stress or extreme temperatures.

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In some cases, a low creep is a good thing.

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In the blades of a propellor, too much creep could elongate the blades and make them hit the casing, damaging them.

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But in a concrete structure, some amount of creep can be useful since it prevents the concrete from cracking outright.

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There’s also fatigue strength, which measures how many times a material can endure a certain amount of stress before it fails.

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Sometimes even applying small loads of stress well below the yield stress still leaves tiny impacts, like microscopic cracks in the material.

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If that small amount of stress is applied repetitively, the cracks can deepen and spread in the material until they eventually cause fracture.

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As you’d expect, a material might be able handle lots of little bits of stress applied to it over time before it fractures.

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But it might only survive failure under a few large stresses.

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The fatigue strength is the highest possible stress a material can withstand a given number of times before undergoing failure.

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Of course, hardness, creep strength, and fatigue strength are just some of a material’s mechanical properties.

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We might also need to consider how the surface of our chosen material reacts with its environment,

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how much it costs to produce and obtain, and even what it looks like.

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And while all of those are important, it isn’t much use considering those other properties

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until you’re sure the material is mechanically up to the task of handling the stresses and strains the world is gonna throw its way.

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And knowing about the the strengths of the materials you use will add to your strengths as an engineer.

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In this episode, we’ve started considering the materials that are used in engineering.

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We looked at mechanical properties of materials, which describe how much strain a material undergoes given a certain amount of stress.

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From stress-strain diagrams, we found useful properties that could be measured like the modulus of elasticity and toughness,

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and described other material properties like hardness, creep strength, and fatigue strength.

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Next time, we’ll get into the real substance of things and discuss the materials themselves in a bit more depth,

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starting with what makes a metal a metal.

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Crash Course Engineering is produced in association with PBS Digital Studios.

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If you have a couple minutes, we have some homework for you because PBS Digital Studios is conducting its annual survey,

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which gives us a chance to hear from you and helps us make some big decisions.

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Plus, 25 random people will win a PBSDS t-shirt.

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Head on over to the link in the description.

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Crash Course is a Complexly production and this episode was filmed in the Doctor Cheryl C. Kinney Studio with the help of these wonderful people.

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And our amazing graphics team is Thought Cafe.