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  • Whether you're heating up leftovers from last night, or just trying to stay cool in the summer, heat transfer is everywhere.

  • In some ways, the world is literally built around it.

  • Any well-engineered building is designed and made out of materials that help keep the inside of the building at a good temperature,

  • even during bitter blizzards or horrendous heat waves.

  • A furnace or A/C will only get you so farwithout protecting against heat transfer, you might as well try to air condition your whole neighborhood.

  • A big part of engineering is using your knowledge of natural processes to keep them from interfering with whatever you're trying to do

  • or in some cases, taking advantage of those processes.

  • So without a solid understanding of how and why heat moves the way it does, your designs won't be very successful.

  • Especially if you've just discovered a tropical island.

  • [Theme Music]

  • So. This tropical island.

  • It's small, totally deserted, and seems like the perfect place to build that vacation home you've always dreamed of.

  • The tropical weather is really nice, but it's also hotvery hot.

  • So you'll probably want to design your house to keep the heat out, and the cold in.

  • In other words: you'll want to prevent as much heat transfer as possible.

  • Even though heat isn't a fluid itself, heat transfers in a way that's kind of similar to the fluid movement we've talked about in past episodes.

  • When fluids move, there's always a driving force behind themspecifically, a difference in either pressure or velocity.

  • With heat transfer, the driving force is a difference in temperature.

  • In fact, if you don't have a temperature difference, you can't have heat transfer. Period.

  • If you have two boxes right next to each other, and they're both at the same temperature,

  • then one of the boxes won't randomly start giving its heat energy away to the other one.

  • But if you're watching this video on your laptop and it's, well, on top of your lap,

  • then your legs might be warming up as heat is transferred to them from your laptop.

  • That's because right now your laptop is warmer than your skin, and when heat passively transfers,

  • it always moves from a higher temperature to a lower one.

  • You'd have to use the cycles and work energy we've talked about beforebasically, an engineto make it move in the opposite direction.

  • And unless you have perfect insulation, which is practically impossible in most settings, then a temperature difference will cause heat transfer.

  • So, this house you're building is going to heat up from the warm, tropical air no matter what.

  • But there's a lot you can do to slow down the process.

  • There are three main types of heat transfer to look out for: conduction, convection, and radiation.

  • With conduction, heat energy is transferred by the collisions of molecules or other particles.

  • When two things touch, the faster moving molecules of the warmer object crash into the slower moving molecules of the colder object,

  • transferring energy that heats them up.

  • In your house, that will cause heat transfer through the layers of the walls.

  • As the outer layer warms up, conduction will transfer the heat through to the cooler inner layers.

  • To slow this down, you'll want to build the walls out of a material with low thermal conductivitysomething that doesn't transfer heat well.

  • Copper, for example, has a high thermal conductivity, so if you made your walls out of it, you'd effectively be making a giant sauna.

  • Which doesn't sound like a great place to live.

  • For one thing, it would probably be a burn hazard.

  • Materials like brick and drywall, on the other hand, have lower thermal conductivities, so they'd be much better choices.

  • Anything that's sold as insulation also has a very low thermal conductivity, so you'll probably want some layers of that, too.

  • The thicker these layers, the more resistant the walls will be to heat transfer by conduction.

  • Specifically, they'll have more of what's called thermal resistance,

  • which is defined as the thickness of the layer of material, divided by the material's thermal conductivity and the area of the layer.

  • All this means is that materials with a lower thermal conductivity have a higher thermal resistance, and that a thicker layer will also have a higher thermal resistance.

  • But if there's more area for heat to be conducted through, that will lower the thermal resistance.

  • Thermal resistance is also equal to the temperature difference divided by the heat transfer rate.

  • Which also makes sense.

  • It means that for a given temperature difference, materials with a higher heat transfer rate will have a lower thermal resistance, and vice versa.

  • You can use this equation to determine the level of thermal resistance you'll need

  • if you want a low rate of heat transfer for the temperature difference you'd expect to have in the layers of your walls.

  • And the resistance of the different layers adds up, so the total thermal resistance of the walls is equal to the resistance of each layer combined.

  • It's like putting on layers of clothing on a cold day.

  • The more layers you have, the lower your rate of heat loss will be, and the easier it is to stay warm.

  • So for your house, if the drywall and brick don't have enough thermal resistance to keep the inside cool, you can add layers of insulation to up the resistance.

  • That takes care of the heat transfer within the walls, but there's more going on outside of them.

  • Which brings us to the second method of heat transfer:

  • convection, the transfer of energy by the physical movement of a fluidwhich in engineering, can be a liquid or a gas.

  • As a fluid moves against or across a surface, it can add or take away heat.

  • For example, as air heats up, its particles spread out, lowering its density.

  • That warmer air rises, taking heat energy with it, and is replaced by cooler, denser air.

  • That's called natural convection, because variations in the temperature of the fluid create natural movement without any external forces.

  • There's also forced convection, where something external like a fan or the wind moves the fluid.

  • Heat transfer by convection actually involves some conduction, especially at first.

  • When the warm outside air comes into contact with your house's walls,

  • it creates the no-slip condition we've talked about before, where the layer touching the surface comes to a stop.

  • Right on top of that, there's what's called a boundary layer, where the air is moving, but slowly.

  • The lower velocity slows down the rate of heat transfer,

  • creating a thermal boundary layer where there's more conduction between the particles, and less convection.

  • Beyond the boundary layer, though, heat transfer mostly happens by convection through the faster-moving air.

  • You can measure how much heat is being transferred by convection using what's known as the convective heat transfer coefficient, represented by the letter h.

  • It's proportional to the thermal conductivity of the fluid over the thickness of the boundary layer,

  • which just means that thinner fluids with higher thermal conductivity will transfer more heat.

  • Makes sense.

  • h also depends on how fast a fluid is moving.

  • The less a gas moves around, the less heat is transferred through convection.

  • That's why windows often have double panes.

  • The air trapped between the layers of glass can't move very much, reducing the heat transfer.

  • So, double-paned windows are probably a good idea for your house.

  • There's not much else you can do to minimize the effects of convection, since you can't really control what the air does as it moves around outside.

  • But you can reduce the effects of the last type of heat transfer: radiation.

  • Radiation is the transfer of energy in the form of electromagnetic waves

  • and in this context, we're talking about any electromagnetic waves, not just the cancer-causing kind.

  • You feel this radiation every time you walk outside and bask in the sun or warm up by a fire.

  • Unlike conduction and convection, radiation can happen without any contact between the heat source and the object.

  • That's why heat energy from the sun is able to reach the earth.

  • Reflective coatings can help reduce the heat transfer from radiation a little since they absorb fewer electromagnetic waves.

  • But when it comes to radiation, where your house is will be much more important than what it's made of.

  • Since the sun will likely be the biggest radiative source, you'll want to build the house somewhere it won't get too much direct sunlight.

  • So, there are a lot of factors to consider when you're trying to minimize heat transfer.

  • But with a shady spot, walls with lots of thermal resistance, and some double-paned windows,

  • you should have a pretty comfortable place to hang out on your tropical island.

  • So today we learned all about heat transfer and the different mechanisms behind it.

  • We started with conduction and learned about the thermal conductivity of materials.

  • Then we moved on to convection and boundary layers, learning that convection can be both forced and natural.

  • Finally, we covered radiation and how it differs from the other two methods in that it doesn't need an intervening medium to transfer heat energy.

  • Next time we'll talk all about how we can use what we just learned about heat transfer, and apply that to heat exchangers.

  • 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 It's Okay to Be Smart, Above the Noise, and Global Weirding with Katharine Hayhoe.

  • 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.

Whether you're heating up leftovers from last night, or just trying to stay cool in the summer, heat transfer is everywhere.

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熱の移動。クラッシュコース工学#14 (Heat Transfer: Crash Course Engineering #14)

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    林宜悉 に公開 2021 年 01 月 14 日
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