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  • Our world is made up of matter.

  • And one way that we study matter is with chemistry.

  • How we use that knowledge leads us to chemical engineering.

  • Chemical engineering is one of the broadest of the engineering fields, focused not only on chemicals

  • which make up everythingbut also on developing and designing plants and processes for manufacturing chemicals.

  • Now, let's imagine we've come up with an amazing new product that we have to create through a chemical process.

  • It could be some new kind of personal water purifier, or makeup that lasts as long as you want it to, or a revolutionary clothing material.

  • Whatever it is, we're going to have to go through some steps before we all get rich.

  • Once we've designed our product, we'll need to create a facility where we can make it.

  • And in order to know how to do that, it would help if you understand a little about the history of chemical engineering.

  • [Theme Music]

  • To begin, let's dispel a common assumption: that chemical engineering is simply chemistry applied to engineering.

  • Sure, there's a lot of chemistry involved, but the engineering side has a lot to do with answering questions, like

  • What can we do with these chemicals? How can we make them?

  • Where can we go from here, and What are the possibilities?”

  • Chemical engineering got its unofficial start back around the time of the American Revolutionary War.

  • During the war, blockades were put up to stop trade between the American colonies and Europe.

  • France was especially affected by these blockades, because America is where it got its supply of sodium carbonate, also known as soda ash.

  • At the time, soda ash was used for a whole bunch of things, from cooking, to manufacturing glass and paper, to making soap.

  • Since France couldn't get sodium carbonate from its normal trade routes,

  • the French Royal Academy offered up a prize in 1775 to anyone who could make sodium carbonate from sodium chloridewhich we know as common salt.

  • It took about 15 years, but a French chemist and physician named Nicolas Leblanc finally figured out how to do it around 1789.

  • His methods, now known as the Leblanc Process, first heated sodium chloride with sulfuric acid to produce sodium sulfate, which was called the salt cake.

  • The salt cake was then mixed with crushed limestone and coal, and fired.

  • This left the combination of sodium carbonate and calcium sulfide, also known as black ash.

  • The final step separated the sodium carbonate from the black ash by washing it with water, which was then evaporated.

  • We call this extraction process lixiviation.

  • Leblanc's process became the forerunner of modern chemical manufacturing, and paved the way for future chemical engineers to come.

  • By 1791, he opened up a small factory in Saint Denis and began large-scale production of soda ash.

  • But his plant was soon taken over by revolutionaries during the French Revolution, who also released his trade secrets.

  • While this process was revolutionary in its own right, it was pretty bad for the environment.

  • It produced a ton of waste that smelled rather putrid.

  • Since chemical processes can often have nasty byproducts,

  • governments can often pass pollution legislation, especially around big cities and bodies of water.

  • But none of this has stopped the chemical industry from growing.

  • In the late 19th century, British chemist George Davis worked as an inspector for the Alkali Act,

  • which was an early piece of environmental legislation in response to the Leblanc process.

  • The act required soda manufacturers to reduce the amount of hydrochloric acid gas that they released into the atmosphere.

  • Around 1887, Davis gave a series of lectures at the Manchester School of Technology.

  • His talks formed the basis for his two-volume Handbook of Chemical Engineering, which was the first of its kind.

  • There were already chemistry books written for specific industries, like acid production and brewing.

  • But what made Davis' work unique was that it organized basic operations that are common to many industries, like transporting liquids and gases or distillation.

  • In the US, his work helped stimulate new ways of thinking about chemical processes

  • and sparked the creation of chemical engineering degrees at universities around the country.

  • Any chemical engineers that we work with to help develop our product will likely have their education rooted in Davis' teachings.

  • Around the turn of the 20th century, cars were starting to become a regular part of modern life.

  • And soon chemical engineers were playing an important role in their use, by making gasoline.

  • Drills were already finding crude oil, but that's not gasoline.

  • The oil needed to be refined.

  • So we needed refineries, which were basically giant chemical plants.

  • Chemical engineers improved the process of making gasoline by introducing methods like cracking,

  • where heavy hydrocarbon molecules are broken down into lighter molecules by heat and pressure.

  • They also implemented the process of polymerization,

  • where propylene and butylene are combined into molecules of two or three times their original molecular weight.

  • With these improvements, gasoline became more economically viable, which made gas cheaper and owning a car less expensive.

  • Now, large-scale chemical production like this requires a lot of planning.

  • So, as chemical plants develop, a big part of chemical engineering becomes what we'll callUnit Operations”.

  • This was first introduced by the American Arthur D. Little in 1915, and it breaks down each part of a chemical plant into individual units.

  • Do you need to get chemicals flowing from one side of the plant to the other?

  • Use pipes. That's a unit.

  • And you'll need pumps to drive the flow. That's another unit.

  • Need to stimulate a reaction? Use a reactor.

  • Want to mix those chemicals together? Go for a mixer.

  • Need to separate them?

  • Try distillation columns or maybe reverse osmosis membranes.

  • All of these are units, and they highlight the key theories that chemical engineers need to understand to keep a plant running.

  • It's important to think of processes as a whole,

  • but it will be just as important to break down our chemical plant into unit operations when we get to the manufacturing phase.

  • Once engineers realizedin part thanks to Little's work

  • that all of these unit operations were founded on basic principles, such as momentum transfer, mass transfer, and thermodynamics,

  • they could then become more creative in how they manufactured chemicals.

  • They no longer had to use the same equipment for the same limited purposes.

  • Instead, they could devise new ways of using their tools and machines.

  • This allowed chemical engineering to grow into one of the broadest engineering fields.

  • As recently as the 1970's, the field was much more narrow than it is now.

  • Back then, around 80% of graduating chemical engineers took jobs in the chemical process industry and government.

  • By 2000, that 80% had dropped to about 50%.

  • One of the reasons for this was the emergence of biotechnology.

  • Heavily focused on research and development, biotechnology engineering applies technology to biological systems and living organisms.

  • Once we know how and why biological processes work, we can find ways to change, adapt, and control them, with the aim of making our lives better.

  • In a similar fashion, pharmaceutical and healthcare companies also played a big role in expanding what chemical engineers do.

  • Every day, new drugs and medicines are made and improved upon.

  • Chemical engineers also work on how best to deliver these drugs into our bodies.

  • Some might best be injected, like insulin or an epipen, while others work well in a spray form, like an inhaler.

  • A lot of chemical engineering goes into many of the foods that we eat as well.

  • We've had to figure out such dark magic as getting corn syrup from corn and making artificial sweeteners.

  • We've found dairy substitutes and used plants to make vegan and vegetarian meats that taste like they came from an animalkind of.

  • This has all done wonders for people with food allergies and dietary restrictions.

  • There's also a growing focus on the environment and sustainable energy within the field of chemical engineering.

  • We want to both preserve what we already have and find energy sources that won't run out of power.

  • So one source that's closely related to chemical engineering is biomass: renewable organic material that comes from plants and animals.

  • This ranges from wood and leftover crops, to garbage and manure.

  • As of 2016, biomass fuels provide about 5% of the primary energy used in the United States.

  • And chemical engineers play a big part in figuring out what can be used as biomass and how to best break it down to get energy from it.

  • All of these developments in chemical engineering are what will really give us the knowledge to make our wonderful new product, whatever it is.

  • We can improve upon what's already there, or make something truly revolutionary.

  • When you're a creator, the possibilities are endless.

  • So today we learned a lot about the history of chemical engineering, starting with its origins in sodium carbonate.

  • We then talked about George Davis, the father of chemical engineering, and his teachings.

  • We moved on to oil refineries and chemical factories, learning about the unit operations behind them.

  • We ended our lesson by talking about the newer and emerging fields of biotechnology, pharmaceuticals and food, and finally renewable energy.

  • Next time we'll learn about industrial and biomedical engineering and how they're changing the world.

  • 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 The Origin of Everything, Infinite Series, and Eons.

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

  • And our amazing graphics team is Thought Cafe.

Our world is made up of matter.

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B2 中高級

化學工程的歷史。工程速成班#5 (The History of Chemical Engineering: Crash Course Engineering #5)

  • 15 1
    林宜悉 發佈於 2021 年 01 月 14 日
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