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  • The world isn't perfect.

  • No matter how hard you try to solve a problem, or prevent one from happening, things still go wrong.

  • That's just how life is.

  • And sometimes, that means your basement gets flooded.

  • So, what do you do?

  • You need to get the water out, but how?

  • Well, you're going to need some equipment. Some pipes. A pump.

  • And to choose the right pump for the job, you'll need Bernoulli's Principle.

  • [Theme Music]

  • If you've seen our last episode, you already know all about fluid mechanics and the energy transfers involved.

  • But engineering is about more than just learningit's also about using your knowledge to build things and solve problems.

  • Like your flooded basement.

  • To get the water out, you'll need a pump – a device that's used to move liquids, compress gases, or force air into things like tires.

  • In this case, obviously, you'll want a pump that's designed to move liquid,

  • and powerful enough to push all that water in the basement somewhere else, like outside.

  • Preferably far away.

  • You could just pick a random pump and hope it works, but that's not the engineering way.

  • To do this properly, you can calculate how powerful your pump needs to be with the help of 18th-century Swiss mathematician Daniel Bernoulli.

  • There were actually eight mathematicians in the Bernoulli family in the 17th and 18th centuries, including Daniel's father and two brothers.

  • His father was especially jealous of his success.

  • Their rivalry was so bad that when the two of them jointly won a scientific prize, his father banned him from the house.

  • He also went on to plagiarize Daniel's later work, changing the date so it seemed like he'd actually published it before his son.

  • As competitive as their relationship was, it's possible that the challenge pushed the younger Bernoulli to become a better innovator and mathematician.

  • But either way, he discovered a good deal about fluid flow in his life.

  • He specifically wanted to understand the relationship between the speed at which blood flows and its pressure.

  • So to learn more, he conducted an experiment on a pipe filled with fluid.

  • Bernoulli noticed that when he punctured the wall of the pipe with an open-ended straw,

  • the height to which the fluid rose in the straw was related to the pressure of the fluid in the pipe.

  • Soon, physicians all over Europe were measuring their patients' blood pressure by sticking sharp glass tubes directly into their arteries.

  • Luckily for us, they've developed more gentle methods since.

  • But while the physicians of his day were being quite the pain in the arm, Bernoulli was on to something very important.

  • He realized that energy was conserved in a moving fluid.

  • It could be converted between different forms, like kinetic energythe energy of motion

  • and potential energy, but the total energy within the fluid would stay the same.

  • So if one form of energy decreases, for example, like if the fluid slows down,

  • there has to be a corresponding increase in anotherform of energy so the total remains constant.

  • Bernoulli's insight was that energy could also be converted between kinetic and potential energy and pressure.

  • Today, this is known as Bernoulli's Principle, and it says that as the speed of fluid flowing horizontally increases, the pressure drop will decrease, and vice versa.

  • This means that the fluid's speed will have an inverse relationship with its pressure, or that as one rises, the other falls.

  • Now, this principle only really applies to what's known as an isentropic flow,

  • meaning it doesn't involve any heat transfer, and it's reversible, so it can go back to its initial state with no outside work.

  • Or at least, close enough that you can neglect the effects of heat transfer or irreversibility.

  • To keep things simple, we'll assume this applies to our system.

  • For Bernoulli's Principle, the fluid also needs to flow horizontally, or not have a drastic change in height, because it doesn't consider the effects of gravity.

  • So to account for height and gravity, and apply Bernoulli's Principle to the design of our pump system, we're going to need a more general equation.

  • Bernoulli's Equation.

  • There are many forms of Bernoulli's Equation,

  • but the one we'll look at today relates the pressure, speed, and height of any two points in a steadily flowing fluid with a density ρ.

  • Since something's density is just its mass divided by its volume, this equation actually works out really neatly:

  • On both sides of the equation, you'll see that we're defining a point's total energy per unit volume by its pressure,

  • plus its kinetic energy per unit volume, and then finally adding in its potential energy per unit volume.

  • Basically, this equation says that the total energy of the first point is equal to the total energy of the second point.

  • So if, say, the two points have different speeds, it makes sense that they'd have different pressures or potential energy to balance out the equation.

  • Since the total energy will be the same at every point in the fluid, you can also write the equation like this.

  • It's very similar to what we had before, but since the total energy will always be the same,

  • you can replace the right side of the equationwhich represents the total energy at a second point along the pipewith a constant.

  • Much simpler.

  • And it gets even simpler if the fluid only flows horizontallyin other words, if there's no change in height between the points we're comparing.

  • That means we can cancel out the term with potential energy, leaving us with only the pressure and the kinetic energy per unit volume equal to a constant.

  • By now, you're probably wondering how we can find out the actual value of this constant we keep talking about.

  • Well, we know it's the total energy per unit volume, and that one way to find it is to add up the pressure, kinetic energy over volume, and potential energy over volume.

  • But when we're talking about a real-life scenario with a pump involved,

  • we have to take into account the energy that's being put into and lost from the system to move the fluid.

  • We've said this energy can take two forms: work and heat.

  • Work is what's driving the pump.

  • That work is what's moving the water along, and contributing to the total energy.

  • But it's not the only factor.

  • There's something else that we need to take into account: friction.

  • As water flows through the pipe, the movement will induce stress in the fluid, which causes friction

  • the resistance you get when two things slide against each other.

  • Friction makes a system lose energy to heat, and there's going to be a lot of it as the water rubs against the inside of the pipe.

  • Now, even with the pump, the total energy of the fluid will still be constant throughout the pipe.

  • Which means the changes in energy from work and friction will need to balance out with changes to the three forms of internal energy

  • so, pressure, kinetic energy, and potential energy.

  • That's the only way the total energy will remain the same.

  • Going back to Bernoulli's Equation, we can now modify it slightly.

  • The first thing we'll do is rewrite it in terms of changes in energy:

  • On the left side, there are the changes to the internal forms of energy:

  • the change in pressure, plus the change in kinetic energy per unit volume, plus the change in potential energy per unit volume.

  • That's all equal to a constant.

  • Then, we'll divide the whole thing by density, which remember, is really the same as multiplying by volume and dividing by mass.

  • So now we're talking about overall changes per unit mass throughout the flow, instead of changes per unit volume.

  • This is what needs to balance out with the energy added by the pump and lost to friction.

  • So, instead of a constant, we can now say the left side of the equation is equal to W, the work put in to change the energy per unit mass,

  • minus frictional losses per unit mass.

  • Many engineers will take this equation a step further and divide the whole thing by gravity,

  • which gets you the value known as headthe height to which a pump can drive the fluid.

  • Now, the actual amount of energy lost to friction depends on a bunch of different parameters.

  • One of the big ones is the velocity of the fluid.

  • The greater its velocity, the greater the frictional losses.

  • It makes sense if you think about itthere's going to be much more intense rubbing against the sides of the pipe if the water's moving faster.

  • And remember last episode when we talked about laminar and turbulent flow?

  • Well that matters here too, because a turbulent, or fluctuating flow will increase the friction more than a laminar, or smooth flow will.

  • The length of the pipe matters, too.

  • If there's more pipe for the water to rub against, it will lose more energy to friction.

  • And then there's roughness: the rougher the pipe, the more friction there will be.

  • Not to mention every valve, fitting, bend, and intersection in the pipe, which will also increase the friction.

  • To figure out how powerful the pump needs to be to get the water out of your basement

  • in other words, how much work it should be capable of producingyou'll have to account for all of this.

  • You'll want to minimize friction by keeping the pipe as simple and short as possiblethis way, you won't need as much work to counter the energy loss.

  • The pump also needs to be able to perform enough work to account for the pressure and velocity of the water, as well as any changes in elevation.

  • Reality tends to be a little messier than the simplified version of Bernoulli's equation we're using,

  • but it should be enough to get a sense of which pump you'll need to finally clear out your basement.

  • Who knows how much mold is growing down there by now.

  • More generally, Bernoulli's equation is a good foundation for working with fluids and figuring out how to build your designs around them.

  • The world isn't always perfect, but with the right engineering skills and tools, it doesn't have to be.

  • So today was all about diving further into fluid flow and how we can use equipment to apply our skills.

  • We talked about Bernoulli's Principle and the relationship between speed and pressure in certain flowing fluids.

  • We then learned how to apply the principle with Bernoulli's Equation.

  • Taking that equation, and substituting a constant with work and frictional loss, gave us a great way to use it in real-world examples.

  • I'll see you next time, when we'll talk all about heat transfer.

  • Make sure you bring a bottle of sunscreen.

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

  • You can head over to their channel to check out a playlist of their latest amazing shows, like Brain Craft, Deep Look, and PBS Space Time.

  • 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.

  • And our amazing graphics team is Thought Cafe.

The world isn't perfect.

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流体の流れと装置.クラッシュコースエンジニアリング#13 (Fluid Flow & Equipment: Crash Course Engineering #13)

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    林宜悉 に公開 2021 年 01 月 14 日
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