Isegoria

Damascus steel is practically synonymous with artisanal forgework, but a new study led by Philipp Kürnsteiner of the Max Planck Institute for Iron Research shows that it is possible to do something very similar with laser additive manufacturing:

Traditional folded steels combined two steels that varied by carbon content and in their microscale structure, which is controlled by how quickly it cools (by quenching). In this case, the researchers were using a nickel-titanium-iron alloy steel that works well with these 3D printing techniques, in which metal powder is fed onto the work surface and heated with a laser.

Rapid cooling of this steel also produces a crystalline form as in quenched high-carbon steels. But further heat treatment leads to the precipitation of microscopic nickel-titanium particles within the steel that greatly increase its hardness—a pricey material called “maraging steel.”

The team’s idea was to use the layer-by-layer printing process to manipulate the temperatures each layer experienced, alternating softer, more flexible layers with layers hardened by that precipitation process. While printing a cubic chunk of steel, they did this simply by turning the laser off for a couple minutes or so every few layers. The top layer would rapidly cool, converting to the desired crystalline form. Then, as additional layers were added on top, temperatures in the crystalline layer would cycle back up, inducing the precipitation of the nickel-titanium particles.

The first test piece was thrown under the microscope for an incredibly detailed analysis, including a close-enough look at the hard layers to see the precipitated particles. The researchers even atom mapped the layers to verify their composition. So the researchers were able to confirm that the process definitely accomplished what they were aiming for.

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For comparison, they printed another block continuously, producing no hardened layers at all. Both were stretched until they fractured and failed.

The Damascus-like sample was significantly stronger, holding up to about 20 percent more stretching force. It didn’t reach the strength of a typical, traditionally made maraging steel, but the researchers note that this requires “a time-consuming and costly post-process ageing heat treatment.”

When Eisenhower’s Atoms for Peace program was considering a nuclear-powered cargo-passenger ship, Mechanix Illustrated suggested something even better, an Atoms-For-Peace dirigible. What could go wrong?

Unlike a ship, the dirigible moves in an aerial ocean that completely envelops our globe. Hence, it can display its wares anywhere on the face of the earth. Seas, mountains and deserts present no barrier. Neither, considering its mission of peaceful education, should national frontiers.

A modern dirigible would be unique, the cynosure of all eyes. Unlike the ship, one-third of whose bulk is hidden by the water in which it rides, the dirigible discloses every inch of its dramatic size as it coasts along against the clear backdrop of the sky. The lower it flies, the more majestic it appears, as anyone who saw the Akron, Macon or Hindenburg will testify. No man-made vehicle has ever presented such an awe-inspiring spectacle as a giant airship breaking through a low-hanging cloud or cruising above the rooftops of a darkened city.

Its effect upon the peoples of the world would be many times more potent than that of an ordinary-looking, seaborne freighter. The fact that the dirigible, traveling at relatively low speeds and altitudes, a silvery giant by day and dramatically illuminated at night, will be visible to practically everyone en route, makes it the perfect Atoms-For-Peace transport. It can show our flag in every nook and corner of the globe, scattering as it goes messages of good will in every literate dialect.

I suppose that part’s true. What did they propose?

Magnesium, titanium and strong, lightweight Fiberglas promise greater ruggedness and durability with less poundage. This improved weight-strength ratio opens new possibilities to the dirigible engineer. For instance, the single, bottom-keel structure, an outgrowth of age-old surface ship design, might be augmented by external side and top “keels,” containing additional passenger accommodations. These extra stiffeners would vastly strengthen the airship longitudinally without too great a weight penalty.

In place of the Akron and Macon pickup gear and airplane hangar, a modern helicopter landing pad and internal hangar deck might be installed atop the hull’s center section. Built in the form of a shock-absorbing elevator, the pad could lift the copter clear of the hull for take-off and after landing, lower it to the level of the protected hangar deck for the safe, comfortable unloading of passengers. This is merely a reversal of the earlier airplane setup with the added safety advantage that both copter and airship travel at the same speed. The copter could provide a ferry service en route and at points where it is inadvisable or impractical to land the airship.

Another possibility is the development of water landing gear. A seagoing dirigible, embodying a water-tight hull and lower gas bag, was recently publicized in Germany. MI feels, however, that retractable pontoons of inflated rubber would prove lighter and more efficient. They need not be large, as airships can be trimmed so as to be almost weightless. Water, pumped up from the surface — using the hose gear long since perfected — would provide ballast to hold the ship down when anchored.

Due to the horsepower limitations of the early internal-combustion engines, dirigible designers have always had to install multiple power plants, scattered along the length of the ship. This has not proven too good an arrangement. In addition to difficulties in coordination, the propeller slip-streams have added to the skin friction of the hull with a consequent increase in drag. Modern research indicates that some form of dragless stern propulsion would better the airship’s efficiency and speed by as much as 15 per cent.

With this in mind, MI weighed the various power plant possibilities.

The final solution proved to be the easiest to apply and the one that offers the maximum advantages weight wise. This is a midship atomic steam plant using turbines to generate electricity. Comparatively lightweight wiring car ries the juice to the stern of the ship where an electric motor drives a huge, four-bladed, reversible propeller. To assist in landing and take-off maneuvers, ducted fans are mounted in gimbals in the forward and after stabilizers. These enable the skipper to move his ship up, down or at sidewise angles.

The fission plant is of the latest type, consisting of a central reactor contained within the core of a cylindrical heat-exchanger, the whole being enclosed in lightweight, laminated shielding. Its operation is simple. Steam, generated in the exchanger by the heat of fission, is ducted to twin turbine-generator installations set on either side of the reactor. Passing successively through high and low pressure turbines, the used steam is condensed and routed back to the heat exchanger in a closed system. The turbines drive twin generators and the electricity thus produced, passes into storage batteries. While heavier than a single installation, the duplicate turbine generators provide a safety factor, one being always available in the event of mechanical failure or repair work on the other.

This compact arrangement is mounted on a reinforced deck within the hull and may be readily reached from the exhibition hall directly below it. Galleries around the engine room permit visitors to inspect the unique plant without interference or danger to themselves. If the public exhibition is considered sufficiently important, a water shielded “fishbowl” type of reactor might be used. While heavier and less compact, it would provide a more impressive show.

The power plant used in the atomic submarine Nautilus weighed roughly three times as much as the entire Hindenburg. That seems like a stumbling block.

A hot air balloon is almost entirely hot air — even by mass:

Component	Pounds	Mass Fraction
Envelope	250	3.3%
Basket	140	1.9%
Burner	50	0.7%
Fuel Tanks	405	5.4%
Passengers	750	10.0%
Sub Total	1595	21.2%
Heated Air	5922	78.8%
Total	7517	100.0%

Existing lithium batteries have a low energy density, while existing fuel cells have low specific power. The air transport market requires both high specific power and high energy density:

Forecasting that suitable lithium battery technology might be as much as 15 years away, the HyPoint team began focusing its efforts on a fuel cell design specifically targeted at eVTOLs. To keep things lightweight, it would have to be an air-cooled design; liquid-cooled fuel cells, says Ivanenko, work well in the automotive world, but the associated coolant tanks and pumps add parasitic mass that literally isn’t going to fly in the aviation world.

But today’s available air-cooled fuel cells, he says, have limited power capacity and lifespan, and they only work in temperatures between -5 and 30 °C (23 and 86 °F). So the HyPoint team set out to develop something faster and hardier, and came up with what they call the “turbo air-cooled fuel cell.”

“We boost the power of the fuel cell stack by placing it inside an air duct, where pressurized, humidified and thermally stabilized air is circulated by fans,” says Ivanenko. “The compression of air is maintained about 3 bars inside by a compression system, and the air with reduced oxygen content is charged through a control valve, and replaced with fresh compressed air with normal oxygen content.”

The extra oxygen on the cathode side of the fuel cell stack, in conjunction with a new High Temperature Proton Exchange Membrane (HTPEM) technology HyPoint has developed, allows you to force three times as much hydrogen through the fuel cell as a traditional design, tripling its specific power output without adding any parasitic cooling mass that might weigh a VTOL aircraft down.

With the entire system taken into account, the HyPoint system delivers 2,000 watts of power per kilogram of mass. The best of the liquid-cooled fuel cells deliver between 150-800 W/kg, and other air-cooled fuel cells sit at about 800 W/kg.

The energy density of the full system comes in at around 960 Wh/kg, where lithium batteries typically sit at about a third of that figure and other air- and liquid-cooled fuel cell systems come in a little over half – all according to HyPoint’s own figures.

The system has some other huge benefits as well, says Ivanenko; it accepts “dirty” hydrogen that’s only 99 percent pure, which is a fraction of the cost of the 99.999 percent purified hydrogen you need for an LPTEM system. “That’s a huge decrease in a significant operational parameter for a commercial eVTOL operation,” he adds.

It works at more or less any real-world temperature, from -50 to +50 °C (-58 to 122 °F) and beyond. And while it’s still in the lab at this stage, the team projects these fuel cells will last some 20,000 hours without maintenance, where LTPEM systems typically last around 5,000 hours – another very significant factor for a commercial operator.

Lancaster, California will be home to a “greener than green” trash-to-hydrogen production plant three times the size of any other green H2 facility:

SGH2 says its process is the cleanest of all on the market, while matching the price of the cheapest producers — and pulling tens of thousands of tons of garbage out of landfills.

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According to a recent memorandum of understanding, the city of Lancaster will host and co-own the SGH2 Lancaster plant, which will be capable of producing up to 11,000 kg of H2 per day, or 3.8 million kg per year, while processing up to 42,000 tons of recycled waste per year. Garbage to clean fuel, with a US$2.1 to $3.2 million saving on landfill costs per year as a sweetener.

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The process, developed by SGH2′s parent company Solena, uses high-temperature plasma torches putting out temperatures between 3,500 and 4,000 °C (6,332 to 7,232 °F). This ionic heat, with oxygen-enriched gas fed in, catalyzes a “complete molecular dissociation of all hydrocarbons” in whatever fuel you’ve fed in, and as it rises and begins to cool, it forms “a very high quality, hydrogen-rich bio-syngas free of tar, soot and heavy metals.”

The process accepts a wide variety of waste sources, including paper, old tires, textiles, and notably plastics, which it can handle very efficiently without toxic by-products. The bio-syngas exits the top of a plenum chamber, and is sent to a cooling chamber, followed by a pair of acid scrubbers to remove particulate matter.

A centrifugal compressor further cleans the gas stream, leaving a mixture of hydrogen, carbon monoxide and carbon dioxide. This is run through a water-gas shift reactor that adds water vapor and converts the carbon monoxide to carbon dioxide and more hydrogen gas. The two are separated, neatly capturing all the CO2 as hydrogen comes out the other end.

A Berkeley Lab lifecycle carbon analysis concluded, says SGH2, that each ton of hydrogen produced by this process reduces emissions by between 23 and 31 tons of CO2 equivalent — presumably counting emissions that would be created if the garbage was burned instead of converted into hydrogen. That would be between 13–19 tons more carbon dioxide avoided than any other green hydrogen production process.

What’s more, while electrolysis requires some 62 kWh of energy to produce one kilogram of hydrogen, the Solena process is energy-positive, generating 1.8 kWh per kg of hydrogen, meaning the plant generates its own electricity and doesn’t require external power input.

The 5-acre facility, in a heavy industrial zone of Lancaster, will employ 35 people full-time and create some 600 jobs in construction. SGH2 is hoping to break ground in Q1 2021 and achieve full operational status by 2023. The company is in negotiations with “California’s largest owners and operators of hydrogen refueling stations” to buy the plant’s entire output for a 10-year period.

Electric vertical takeoff and landing (eVTOL) aircraft can be surprisingly energy-efficient:

Under the EPA’s standard freeway driving test, a 2020 Nissan Leaf Plus uses about 275 Watt-hours per mile when it averages 50 miles per hour. It can comfortably seat four, but its average occupancy is somewhere around 1.6. Thus, the Leaf’s energy consumption is about 171Wh per passenger mile across all trips.

Our current Heaviside prototype uses about 120Wh per passenger mile, and does so at twice the speed of the Leaf: 100 miles per hour (of course, we can fly much faster, if we choose). We can save another 15% of energy because while roads are not straight, flight paths usually are. All together, Heaviside requires 61% as much energy to go a mile.

Why is Heaviside this efficient — doesn’t it take more energy to go faster? Yes, and it makes the high efficiency we’ve achieved even more dramatic. The answer is that Heaviside can take advantage of slim and low-drag aerodynamic forms that are just not practical on cars.

A type of rocket engine once thought impossible has just been fired up in the lab:

Engineers have built and successfully tested what is known as a rotating detonation engine, which generates thrust via a self-sustaining wave of detonations that travel around a circular channel.

As this engine requires far less fuel than the combustion engines currently used to power rockets, it could eventually mean a more efficient and much lighter means of getting our ships into space.

“The study presents, for the first time, experimental evidence of a safe and functioning hydrogen and oxygen propellant detonation in a rotating detonation rocket engine,” said aerospace engineer Kareem Ahmed of the University of Central Florida.

The idea of the rotating detonation engine goes back to the 1950s. It consists of a ring-shaped — annular — thrust chamber created by two cylinders of different diameters stacked inside one another, creating a gap in between.

Gas fuel and oxidiser are then injected into this chamber through small holes and ignited. This creates the first detonation, which produces a supersonic shockwave that bounces around the chamber. That shockwave ignites the next detonation, which ignites the next, and so forth, producing an ongoing supersonic shockwave to generate thrust.

This should produce more energy for less fuel compared to combustion, which is why the US Military is investigating and funding it; this new research was funded by the US Air Force, and it’s not the only such project the military are looking into.

In practice, however, there’s a reason rockets are generally powered by internal combustion instead, in which the fuel and oxidiser are mixed to produce a slower, controlled reaction to generate thrust.

Detonation is chaotic and much harder to control. In order for the whole thing to not blow up — very literally — in your face, everything needs to be precisely calibrated.

(Hat tip to Hans Schantz.)

TechCrunch explains how to create the best at-home videoconferencing setup, for every budget:

Level 0
Turn on a light and put it in the right place
Be aware of what’s behind you
Know your system sound settings

Level 1
Get an external webcam (e.g. Logitech C922x)
Get a basic USB mic (e.g. Samson Meteor Mic)
Get some headphones

Level 2
Use a dedicated camera and an HDMI-to-USB interface (e.g. Elgato Cam Link 4K, IOGEAR Video Capture Adapter, Magewell USB 3.0 Capture)
Get a wired lav mic (e.g. Rode’s Lavalier GO)
Get multiple lights and position them effectively

Level 3
Use an interchangeable lens camera and a fast lens
Get a wireless lav mic (e.g. Rode Wireless Go)
Use in-ear monitors (e.g. Shure PSM300 Pro Wireless In-Ear Monitor System, Bang & Olufsen E8)
Use 3-point lighting (e.g. Elgato’s Key Lights)

Level 4
Get an HDMI broadcast switcher deck (e.g. Blackmagic ATEM Mini)
Use a broadcast-quality shotgun mic (e.g. Rode VideoMic NTG)
Add accent lighting (e.g. Hue Play Smart LED Light Bars)

A global pandemic has done what 30 years of internet manifestoes never accomplished — a mass migration into our screens: