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  • We recently explored the fascinating engineering that made the SR-71 possible. Exploring it's

  • unique hybrid engines, coolant systems and much more, but we neglected to explore one

  • of the most fascinating aspects of it's design. The new and exciting material science

  • that made it possible.

  • The SR-71's speed was not limited by the power of it's engines. It was limited by

  • the heat it's structure could withstand. Today we are going to explore Titanium, a

  • material that composed 93% of the SR-71s structure. A material that had never been truly utilized

  • to its full potential until the SR-71 came along. We will explore it's material properties,

  • how it's made and how the engineers of the SR-71 overcame the challenges they encountered

  • while using the innovative new material.

  • Titanium is one of those words that has entered common language. It's become synonymous

  • with strength. Sia likens titanium to being bulletproof, and yes with the right thickness

  • it is bullet proof. That's why it was used in the A-10 to protect the pilot.

  • But, in reality the strongest titanium alloys are only about as strong as the strongest

  • steel alloys and their temperature tolerance is actually worse, while Aluminium is lighter.

  • What makes titanium special is not it's tensile strength, weight or high temperature

  • performance, but a combination of all of these material properties that made it perfect for

  • the SR-71.

  • When choosing materials for a particular application, engineers will often consult something called

  • a material selection diagram. Where we plot two material properties on the x and y axes.

  • This allows us to see relative benefits of materials so we can choose a material according

  • to our needs.

  • Here is a particularly relevant material selection diagram for the aerospace industry. With density

  • on the x axis and strength, the maximum pressure it can withstand before breaking, on the y-axis.

  • Our three primary metallic material choices for aircraft structure are Aluminium, Steel

  • and Titanium. Located here, here and here. They spread across the y-axis because different

  • alloys have different strengths. [1]

  • Steel is by far the heaviest, which rules it out of most aircraft structures, but it

  • still gets used where it's strength and heat tolerance is needed. We can also see

  • that Aluminium is in fact lighter than Titanium, but Titanium is stronger than Aluminium.

  • A better measure here is the strength to weight ratio. A ratio found by dividing the metals

  • strength by its density.

  • After all, we can make an aluminium part stronger by just adding more material. But, if we need

  • to add so much material that the part is now heavier than an equivalent strength part made

  • from Titanium, then it's not worth it.

  • Here Titanium wins. It's strength to weight ratio, or specific strength, is better than

  • Aluminium, yet today very little titanium is used in everyday objects. Planes primarily

  • use aluminium, not titanium.

  • Why is that?

  • One reason: It's really expensive, despite titanium being the 9th most common element

  • in earth's crust at a percent weight of 0.6%. There is more titanium in the earth's

  • crust than carbon, an element no-one considers rare.

  • Yet, in it's purified form it currently costs about four and half thousand dollars

  • per metric tonne. Aluminium in comparison costs a third of that at a grand and a half

  • per metric tonne, which itself is a relatively expensive metal as result of it's high energy

  • electrolysis refinement process. [2] To boot, that is today's price which has dropped

  • dramatically since the SR-71 was created.

  • Titanium is expensive, because it's refinement process is a nightmare.

  • To make Titanium, we start with a feedstock in the form of Titanium Dioxide, with this

  • chemical formula. [3]

  • This oxide ore called rutile can be found in high concentrations in these dark sandy

  • soils. To build the SR-71 the US needed to buy vast quantities of the mineral from the

  • Soviets, who had large deposits of rutile. To do this they purchased the material through

  • ghost organisations to hide the final destination of material. Had the Soviets known what they

  • were helping build, they would not have sold material. However, the US likely could have

  • just purchased the material from mines in Australia.

  • This is a relatively common raw material and is primarily used as a white pigment for paints

  • and is even found in sunscreen lotion as an ultraviolet radiation blocking pigment.

  • Our trouble begins when we need to separate those two oxygen molecules to get pure titanium.

  • For Iron ore refinement, we heat it in the presence of carbon to force the oxygen to

  • separate from the iron and bind with carbon to form carbon dioxide. With aluminum oxide,

  • it's melting point is too high, so we instead dissolve it in a solvent and then use electrolysis

  • to separate the oxygen molecule. Neither of these methods work with Titanium. Titanium

  • dioxide is both thermal stable and resistant to chemical attack.

  • In the 1940s the first reliable process to produce a chemically pure form of titanium

  • was developed, called the Kroll Process. This process made the SR-71 possible. [4]

  • It begins by first converting the titanium dioxide to titanium chloride. To do this titanium

  • dioxide is mixed with chlorine and pure carbon and heated. Any oxygen or nitrogen leaking

  • in will ruin the process, so this has to be done in relatively small batches in a sealed

  • vessel. Once this process is complete, we have Titanium Chloride.

  • We then need to purify the Titanium Chloride from any impurities in the titanium ore through

  • distillation. Where we heat the product and separate titanium chloride using it's lower

  • boiling point.

  • This Titanium Chloride vapour is fed into a stainless steel vessel containing molten

  • magnesium at 1300 kelvin. Titanium is highly reactive with oxygen at high temperatures,

  • so the vessel also needs to be sealed and filled with argon. Here the Titanium Chloride

  • reacts with the magnesium, which itself is an expensive metal, to form titanium and magnesium

  • chloride.

  • This reduction reaction is extremely slow between 2 and 4 days. Then once the reaction

  • is complete we need let the product cool, before removing the magnesium chloride products

  • through high temperature distillation once again. The magnesium and chlorine are recycled

  • with electrolysis, another energy intensive process.

  • At this stage we have titanium sponge, which needs further processing still. Typically

  • a porous metal like this would be simply heated and compressed into rolls of sheet metal or

  • some other form of useful end product. But Titanium will react with oxygen and nitrogen

  • if heated this high, we can't do that. [5]

  • So the titanium sponge is compressed into an electrode along with any alloying alloys

  • needed. Heat is then generated through an electric arc current inside another sealed

  • vessel. This form of heat needs no oxygen. This melts the electrode to form a large titanium

  • ingot..

  • This process results in an incredibly expensive material that becomes even more expensive

  • as a result of the difficulty the engineers found when attempting to form it into its

  • final shape. [6]

  • The engineers of the SR-71 were among the first people in history to make real use of

  • the material. In that process they ended up throwing away a lot of material, some through

  • necessity, some through error. At times the engineers were perplexed as to what was causing

  • problems, but thankfully they documented and catalogued everything, which helped find trends

  • in their failures.

  • They discovered that spot welded parts made in the summer were failing very early in their

  • life, but those welded in winter were fine. They eventually tracked the problem to the

  • fact that the Burbank water treatment facility was adding chlorine to the water they used

  • to clean the parts to prevent algae blooms in summer, but took it out in winter. [7]

  • Chlorine as we saw earlier reacts with titanium, so they began using distilled water from this

  • point on.

  • They discovered that their cadmium plated tools were leaving trace amounts of cadmium

  • on bolts, which would cause galvanic corrosion and cause the bolts to fail. This discovery

  • led to all cadmium tools to be removed from the workshop.

  • However the largest wastes were caused by the lack of appropriate forging presses in

  • the United States. Titanium alloys require much higher pressure to deform during forging

  • than aluminium alloys or steel alloys. [8] The best forge in the United States at that

  • time could only produce 20% of the pressure needed to form these titanium parts. Clarence

  • L. Johnson, the manager of Skunk Works at the time pleaded for the development of an

  • adequate forging press, which he stated would need to be a 250,000 ton metal forming press.

  • [9] Because of these inadequacies in forming capabilities, the final forging dimensions

  • were nowhere near the design dimensions and much of the forming process had to be completed

  • through machining. Meaning, most of the material was cut away to form the part, resulting in

  • 90% of the material going to waste. When your raw material costs this much, this kind of

  • waste really hurts.

  • To add insult to injury. Drill bits and other machining tools were being thrown away at

  • a rapid pace. Titanium is a difficult material to machine, precisely because of it's qualities

  • that made it suitable for use in the SR-71.

  • This is a material selection diagram with thermal conductivity on the x axes and thermal

  • expansion on the y. Here we can see that titanium has low values for both. Among the lowest

  • for metals. [10]

  • It's low thermal expansion made accommodating thermal expansion as the plane heated up easier,

  • but measures still had to be made to prevent it causing stress.

  • The skin panels were fastened to the underlying structure with oblong holes which would allow

  • the skin to expand and contract without the fasteners causing buckling.

  • And the skin over the wing was also corrugated to prevent warping during expansion, this

  • is actually quite noticeable, you can see the sections that are corrugated quite clearly

  • here. [11]

  • This didn't affect machining difficulties, but the extremely low thermal conductivity

  • did. Machining materials produce a lot of heat can damage the tool and cause unfavorable

  • material properties in the titanium, like hardening. Which means the metal under the

  • fresh cut is now harder, and therefore even more damaging to the tool. This is usually

  • minimized with coolant, but titanium's low thermal conductivity means very little heat

  • is transferred into the coolant.

  • To deal with this lower machining speeds need to be used along with high volumes of coolant,

  • which is also expensive. This slows the rate heat is generated and increases the rate it

  • is removed. [12] This slower machine speed makes the process incredibly slow, but this

  • is offset by taking larger cuts in each pass, which has the added benefit of cutting under

  • the work hardened layers.

  • Titanium is also more sensitive to dull tools, as it's stiffness is quite low. Machinists

  • refer to metals like this as being gummy. They tend to form long chips that can clog

  • the work area and cause all sorts of problems. If not properly managed they can ruin the

  • work surface and damage the tools.

  • The engineers at Lockheed gradually learned these lessons and developed better tools for

  • the job. When the first version of the SR-71 was being constructed, the drill bits used

  • to cut the holes for the rivets could only drill 17 holes before they were unusable and

  • needed to be discarded. By the end of the SR-71 program they had developed a new drill

  • bit which could drill 100 holes and then be sharpened for further use. [13] By the end

  • of the program the engineers had found enough improvements to save 19 million dollars on

  • the manufacturing program.

  • It's pretty clear that titanium is expensive and extremely difficult to work with. Had

  • Aluminium been an option for the SR-71 with a little bit of added weight, the engineers

  • would have jumped at the opportunity, but Aluminium simply cannot deal with the temperatures

  • that steel and titanium can.

  • This is a material selection diagram displaying several metals specific strength as a function

  • of temperature. This is ultimately what made titanium so attractive for the SR-71. [14]

  • Titanium alloys maintain a great deal of their strength up to temperatures as high as 450

  • degrees celsius. The same cannot be said for aluminium. What I find fascinating, is that

  • Titanium's max operating temperature is less a function of loss in strength, but a

  • function of oxidation.

  • Pure titanium is highly reactive to oxygen, which forms an oxide layer on the outside

  • of the metal which is brittle. This oxide layer has some benefits as it provides excellent

  • corrosion resistance which is why many submarines use titanium to resist attack from salt water.

  • But at higher temperatures this oxide layer and titanium are soluble to oxygen, which

  • means the oxygen can permeate through the outer oxide layer and diffuse into the metal,

  • causing oxide layer to grow and eventually helps dangerous cracks to form.The primary

  • titanium alloy used in the SR-71 was (B-120VCA) [15] was thirteen percent vanadium, eleven

  • percent chromium and three percent aluminium. Both Chromium and Aluminium form thermally

  • stable oxide layers on the outer skin of the metal. Which prevents oxygen from diffusing

  • further into the metal and causing it to become more brittle.

  • Which raises the max operating temperature of the metal. While the vanadium acts as a

  • stabilizer for a crystal structure referred to as the beta phase, which leads to a material

  • with higher tensile strength and better formability, with the ability to heat treat to higher strength.

  • [16]

  • In my humble opinion, advancements in material science like this have the largest knock on

  • effect in the advancement of human technologies. So much so, that we name entire eras of human

  • history after the materials we developed during that time. During WW2, the development of

  • aluminium alloys suitable for aviation allowed for the emergence of some incredible planes

  • and with that some incredible tactics. Like aerial invasions, a method of invasion that

  • first emerged in World War 2. I just released the 5th episode of the logistics of d-day

  • on Nebula, the streaming platform I created with my YouTube friends. In this episode I

  • explore the tactics of the allied aerial landings in Normandy. I explore the technologies that

  • helped the planes navigate to their dropzones in an era before GPS, where the airborne troops

  • landed and why, and even explore some of the wooden gliders they used to carry heavy equipment

  • into the battlefield.

  • I am currently working on the next episode which explores the immense Logistics required

  • to build front line airfields to facilitate Close Air Support. The first episode of this

  • series is available for free here on YouTube, if you would like to see what you are signing

  • up for. By signing up to Nebula, you will get access to future episodes and the 4 current

  • exclusive episodes. How The Allies Fooled The Germans, which explores the deception

  • tactics used to hide the location of the invasion. Clearing a way to the beaches, which explains

  • the methods used to knock a hole through the walls of fortress europe. How The Allies Got

  • Ashore, which explores the logistics of the amphibious assault and The Logistics of the

  • Aerial Landings.

  • And to boot you will get access to all Real Engineering videos with no ads.

  • The best way to get access to Nebula is by signing up to CuriosityStream. Which costs

  • just 2.99 a month, or 19.99 for an entire year. By doing that you will get access to

  • all of CuriosityStreams award winning documentaries and get access to Nebula bundled with it for

  • free. That's a great deal.

  • CuriosityStream is all about big-budget non-fiction videos, we're building Nebula because we want

  • a place for educational creators to try out new content ideas that might not work on YouTube.

  • Especially stuff that might get demonetized, like a war-related series.

  • CuriosityStream loves independent creators and wants to help us grow our platform, so

  • they're offering Real Engineering viewers free access to Nebula when you sign up at

  • CuriosityStream.com/realengineering

  • As always, thanks for watching and thank you to all my Patreon supporters. If you would

  • like to see more from me the links to my instagram, twitter, subreddit and discord server are

  • below.

We recently explored the fascinating engineering that made the SR-71 possible. Exploring it's

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Titanium - The Metal That Made The SR-71 Possible

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    joey joey に公開 2021 年 06 月 03 日
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