It is all a nice story and is almost real. Except each variable has to be managed and every improvement in performance entails an exponential increase in cost. That little detail makes all these transportation innovations very difficult. Recall the Concorde please.
Tunnel driving by itself is presently expensive, though i do think that heat induced pop-corning can change that significantly by increasing tunneling speed to some fraction of a foot per minute. This is still a ways away though.
This still produces a rail tunnel and a lined tunnel can never be cheap, let alone one able to support a vacuum. However cheaper rail tunnels are entirely welcome and ideal for urban areas. Imagine a spiraling rail system operating under Paris able to access every five block by five block area. Cross links already exist there and all that would typically operate at around forty miles per hour.
Cheaper tunneling works were tunnels always worked and not so well anywhere else.
Inter city continues to be well served with high speed trains. These happen to be in the national intertest that this must supercede NIMBYism.
The real innovation is not something that Newton could have cooked up. It is the city to city wormhole system. A wormhole can be established and tuned to exist at two separate gates and be engineered to operate safely. At most we will need acceleration arrestors in order to handle the shift in vector and perhaps a Faraday cage as well.
This will be a nice machine that will roll out globally and in time make every community directly connected to an up - node. We certainly can imagine this and I am seeing increasing indications that it is happening in out near future.
This also sets the stage for TIME tourism as well.
.
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'There's No Such Thing As Cold, Hard Reality': Meet The Hyperloop's Truest Believers
Aaron Gordon
https://jalopnik.com/theres-no-such-thing-as-cold-hard-reality-meet-the-hy-1837979096
GOLDEN, Colo.—Shortly
after arriving at the Global Hyperloop Conference, Brad Swartzwelter
looked me in the eye and issued himself a challenge. “If I haven’t
convinced you by the end of this conference that Hyperloop is the most glorious transportation opportunity of our time, then I’ve failed.”
Swartzwelter,
a stocky, middle-aged man with a graying goatee, tends to look at you
slightly sideways as he speaks, arching one eyebrow ever higher as he
expounds on his vision for the Hyperloop—a vast network of pods
traveling in reduced air pressure tubes at upwards of 700 miles per
hour. He holds court on the subject with self-assuredness, because he
has been holding this court, and repeating these words, perhaps longer
than any other living person.
Back in the 1990s, Swartzwelter grew
increasingly frustrated with the inefficiencies in his day job as an
Amtrak conductor; the extended delays, the waits for switches to lock
into place so his train could proceed on the correct track, the slow and
infrequent service. So, he started looking into better ways to move
people. After years of searching, he stumbled on the concept of vacuum
trains, an old idea proposed by the then-college student (later rocket
scientist) Robert Goddard in the early 1900s.
SwissMetro, one of the only real efforts to make vacuum trains a reality in the 1990s, dissolved in 2010,
but by then Swartzwelter was smitten. He knew, deep in the marrow of
his bones, that he had found the answer to the world’s transportation
problems.
Vacuum
trains, Swartzwelter predicted, would incorporate the best aspects of
every transportation mode and none of their drawbacks. As fast as a
plane, as convenient as a train, and more environmentally friendly than a
monorail.
In 2003, Swartzwelter wrote a book called Faster Than Jets: A Solution to America’s Long-Term Transportation Problems.
He says now, as he arches that eyebrow as a hint of his sarcasm, that
he believed the book would radically change the American transportation
landscape as everyone accepted the obvious genius of
magnetically-levitated trains moving through near-vacuum tubes.
That
didn’t quite happen. Vacuum trains, or, as they are better known today,
Hyperloops, remained in the kooky pile of transportation lore until
just a few years ago.
Today, Hyperloops still barely exist,
limited thus far to experimental tracks that have yet to transport a
person. But a growing number of people like Swartzwelter are invested,
either financially or emotionally, in a Hyperloop future. The Hyperloop
is still not close to reality, but whether out of deep concern for our
environmental future, potential business opportunities, or sheer
enthusiasm for the next great transportation innovation, its most
fervent supporters feel it is closer than ever.
Virgin
Hyperloop One, a company backed by about a dozen investors from around
the world including Virgin and Dubai port operator DP World, has 300
employees and is reportedly close
to starting construction on its first full-scale project in India.
Hyperloop Transportation Technologies, a company started by two
crowdsource funding evangelists with no transportation experience who
pay most of its employees only in stock, is working on a full-scale test
track in France. Overall, about a half-dozen serious Hyperloop
companies exist, vying to turn a century-long fever dream into
something.
But describe a Hyperloop to a layperson—tens of
thousands of miles of tubes transporting people at hundreds of miles an
hour—and it sounds, well, nuts. Anecdotally, the most common reactions I
get are something along the lines of “Why would anyone want that?” and
“Who will pay for it?”
Which
is why I have come to the Global Hyperloop Conference, organized by the
Hyperloop Advanced Research Partnership (HARP), a tiny non-profit that
seeks to be a kind of clearinghouse for Hyperloop knowledge.
If
the attendance at this conference was any indication, not very many
people are on board with this whole Hyperloop thing. At least not yet.
According to a list shared with all the participants after the
conference, about half of the conference’s 60 or so attendees were
either speakers or panelists at some point during the two-day
conference.
This reflects HARP’s vibe as more of an enthusiast
community than a burgeoning multi-billion dollar industry. Steve Cohn,
HARP’s newly appointed president and a retired scientist from the
National Center for Atmospheric Research, told me after one panel that
HARP is made up of about 15 core members who video chat almost every
week. They have barely enough funding to put on the conference every
year and keep their website running.
“We are a bunch of
volunteers” who “love technology,” he said in a quiet, gentle voice as
others small talk in groups around us.
This is also very much in
keeping with the Kitty Hawk vibe the Hyperloop community cultivates, a
reference frequently made in the Hyperloop community to the moment
Orville and Wilbur Wright executed the first controlled human flight.
Virgin Hyperloop One claims it achieved
its “Kitty Hawk moment” on May 12, 2017 when it achieved its first
magnetic levitation in a tube at 70 miles per hour. Much like the
original Kitty Hawk moment more than a century ago, this, too, went
mostly unnoticed by the general public.
“In spite of the fact
we’re enthusiastic and somewhat have rose colored glasses on,” Cohn
continued, “we’re scientists and understand the need to be unbiased in
our conclusions.” (To be clear, not all of them are scientists.)
Indeed,
the involvement of people like Cohn who, at least to me, appear to be
perfectly rational and accomplished scientists, makes it slightly more
difficult to dismiss Hyperloops as nuts. At the very least, it indicates
some other factor is at play beyond hucksterism in the age of rampant venture capital funding of dubious startup ideas.
Is
it even remotely possible, I began to wonder, that they’re onto
something? Could Hyperloops really be the greatest transportation
breakthrough in generations as Swartzwelter claims, the one that can
save humanity? Or is this just another con where the bullshit artists
have roped in a couple of patsies?
Making Up Words
Should you manage to locate a copy of Faster Than Jets,
you will not find the word “hyperloop” anywhere in it. That’s because
the word didn’t exist in 2003—and indeed few people other than
Swartzwelter were giving any thought to vacuum trains—until a decade
later, when Elon Musk made it up.
In a now-legendary 2013 white paper
those in the Hyperloop community call “The Alpha Paper” with more than a
hint of ideological reverence, Musk wrote that, similarly to
Swartzwelter’s origin story, the exorbitant costs and low speeds of
American rail infrastructure—specifically California’s high speed rail
project in Musk’s case—convinced him there had to be a better way. Musk
revived the idea of vacuum trains over 57 pages replete with his
informal techno-futuristic style.
In an unusual move widely
interpreted as a form of intellectual philanthropy, rather than attempt
to develop a Hyperloop himself, Musk published The Alpha Paper and
challenged anyone who wanted to take a stab at building one.
So
what, exactly, is a Hyperloop? Although it has no exact definition,
“Hyperloop” is used to describe high-speed travel through a low-pressure
tube. And for all the complicated physics involved, the concept is
devilishly simple.
Airplanes fly at 30,000 feet where the air
pressure is much lower, which reduces air resistance, enabling faster
travel. The idea of a Hyperloop—and the vactrain and every similar
proposal that came before it—is to simulate that low-pressure
environment here at surface level in a tube.
But what exactly is
moving through the tube, and how, and under what method the air pressure
is being reduced to near-vacuum state (and how it will be kept there),
is a matter of debate and experimentation by the handful of Hyperloop
companies that have sprouted up post-Alpha Paper.
Even with these
details up for debate, the hypothetical benefits are nearly
incalculable. The Alpha Paper predicted speeds of more than 700 mph, a
number still widely used by Hyperloop evangelists. Virgin Hyperloop One
uses 600 mph, others use 670. Whatever the number is, they all think
they can go multiple times faster than high-speed rail.
(However, at this point, nobody has come even remotely close to achieving it. The current speed record of 288 mph was recently set with a roughly human-sized pod in a small scale tube.)
But
the purported benefits don’t stop at high speeds. A fully realized
Hyperloop, the thinking goes, would achieve these speeds using less
energy than required to power an electric car. Some go even further and
say less than a lightbulb.
In other words, Hyperloop suggests a
no-compromise future of transportation technology: faster than a jumbo
jet, net-zero clean energy—or even net-positive if you mount solar
panels on the tubes—and just as convenient as urban rail from city
center to city center.
This sounds nuts. But, to Hyperloop
boosters like Cornell University Professor Richard Geddes, one of the
speakers at the conference, it sounds nuts in the same way that
describing the operations of Newark Airport while standing on that North
Carolina Outer Banks beach in 1903 watching the Wright brothers fly a
plane for the first time would have been nuts.
To people like Geddes, the fact that it sounds nuts is not a deterrent, but a goal. It is what makes all this worth doing.
From
the 50 years from 1919 to 1969, Swartzwelter said, we went from rickety
World War I-era biplanes to supersonic jets and landing a man on the
moon. In his mind, over the following 50 years, from 1969 to today, we
went nowhere.
Swartzwelter believes we are due.
“There’s No Such Thing As Cold, Hard Reality”
Fifty
years from now, Swartzwelter predicts, he will be able to hop into his
electric car and drive to his local Hyperloop station, perhaps a mile or
so away from his home near Denver. From there, he can zoom his way to
Telluride for a ski day, or to Denver International Airport to catch a
connection to any city in the country, and be home by dinner. This
connection will not involve getting out the Hyperloop, but seamlessly
switching tracks via a perfectly-functioning algorithm managing hundreds
of interconnecting tubes.
Not every Hyperloop vision has
precisely matched Swartzwelter’s, but neither are they too far apart,
and they’re all lubricated with a healthy application of
techno-optimism. Chuck Michael, head of U.S. feasibility studies for HTT
said in a presentation their system has a top speed of “theoretically”
760 mph, with 160,000 daily passengers based on 40 second headways, all
of which are orders of magnitude improvements over even the most
advanced high-speed rail networks.
Mars Geuze presented remotely
from the Netherlands for his company, Hardt Hyperloop, to reinforce
their vision of “a world where distance doesn’t matter anymore.”
Another
presenter, John Whitcomb of “Hypernet Holding Corporation”—which so far
as I can tell exists only on paper—posited in a bullet point of a slide
that Hyperloops could serve a $760 billion per year market, a
projection he declared to be “reasonable but probably not accurate.”
In
general, nearly everyone at the conference spoke of Hyperloops as an
inevitability, a matter of if not when, and some sooner rather than
later. For example, Dave Clute, the interim president for HARP, thinks
we’re 10 years out from a Hyperloop network in the Midwest. He did not
elaborate on this prediction before moving on to his next point.
And HARP’s communications director, David Pring-Mill, rebuffed the idea that Hyperloops have, as a Daily Beast headline from March put it, failed as an idea as they’ve slammed into “cold, hard reality.”
Once
upon a time, Pring-Mill contended, horses and buggies were the cold,
hard reality of the transportation world. Then, in what he characterized
as “the blink of an eye,” railroads lined the continents. Another blink
and airplanes, metal tubes in the sky, became the norm for
long-distance transportation. Now, Pring-Mill posits, we shall blink
once more, and metal tubes on the ground will be the newest cold, hard
reality.
“There’s no such thing,” he said, “as cold, hard reality.”
Green-Colored Glasses
For
all of its aspirational bluster, the Hyperloop is addressing at least
one real and urgent problem: airplane travel is terrible for the
environment.
One passenger’s share of one flight can account for as much CO2 as some people are responsible for in an entire year.
A cross-country flight can result in as much as a ton of CO2 emissions
per person. Plus, the high altitude at which these emissions take place
exacerbate the effect, so the actual impact on the environment can be several times worse than the CO2 emissions alone.
Although airplanes currently account for only about 1.3 percent of emissions, according to a Bloomberg report,
all airplane travel—including passenger jets, private jets, cargo, and
military—is expected to grow 4.4 percent annually for the next two
decades.
Moreover, long-distance travel is one area of carbon
emissions where we have no good ideas on how to reduce emissions through
innovation. Electric motors are unlikely to be able to provide enough
power relative to the weight of batteries to fly heavy planes
efficiently. Even Airbus’s head of electrification efforts told
Bloomberg that, as the publication paraphrased, “An emissions-free
solution for long-haul flights, on the other hand, will likely remain
elusive for decades to come.”
At present one of the only solutions is to fly less. A lot less. Given the might of the global airline industry, the number of people it employs, and the convenience it offers 2.7 million people every day in the U.S. alone, abstinence is a very big ask.
Enter
the Hyperloop. One of the cornerstone promises of the Hyperloop future
is that it will be low, or no, emissions. Using some type of magnetic
levitation (Maglev) technology—each Hyperloop company is producing its
own proprietary version that works slightly differently—Hyperloops would
float through near-vacuum tunnels. Because of the low air resistance
and Maglev technology, it wouldn’t take much energy at all to get the
pods moving. Using Maglev would also reduce friction so the pods would
need little additional energy to keep moving, even at fantastic speeds.
Using
back-of-the-envelope calculations, Cohn estimates that a well-developed
Hyperloop network across major land masses could reduce emissions in
the transportation sector by 28 percent, mostly replacing long-haul
trucking and plane trips over land. Transportation emissions as a whole
currently account for about a quarter to a third of overall emissions,
depending on the country or continent.
But,
in order for these emission reductions to become reality, so too must a
network of tubes. Tens of thousands of miles of tubes.
To
make those energy savings a reality in time to avert climate disaster,
those tubes have to be built across land quickly. Very quickly. The
Intergovernmental Panel on Climate Change has warned the rest of humanity
that emissions must be reduced to near-zero by 2050 to have a chance of
limiting total global temperature rise to 1.5 degrees Celsius. Failing
to do this, the panel warned, would expose hundreds of millions of
people to climate-related risks such as extreme weather, flooding, heat,
and famine.
This gives us roughly 30 years, at most, to build
out such a Hyperloop network. How to do that is one of the biggest
hurdles facing Hyperloops.
“Space Is Easy, Earth Is Hard”
Just
as with highways and railroad tracks, there are three options for where
to build Hyperloop tubes: at ground level, above ground on elevated
structures, or below ground in tunnels.
Early on, the Hyperloop
community generally settled on a preference for tunnels for two main
reasons. First, they offer the straightest option, which is crucial to
fulfilling their high-speed ambitions. At 700 mph—not far off the speed
of sound—even the most gradual bends or dips would create extreme G
forces and be nearly intolerable for the passengers inside.
A Hyperloop would need approximately six miles to execute a 90-degree turn at 600 mph, a Virgin Hyperloop One engineer told the New York Times.
Even following a public right-of-way like a highway, with the elevation
changes and bends in the road, would force Hyperloops to go much
slower.
Second, exposure to weather and the elements could be
problematic, or at least less desirable. Ryan Janzen of the Canadian
Hyperloop firm TransPod, said tube vibration as the pods woosh
through—not to mention from severe weather—could create a Hyperloop
version of turbulence and perhaps lower the speed at which the pods can
move. Underground, the tubes are shielded from all of that, even during
earthquakes. (Janzen added that every rendering in which you see clear
tubes are merely for illustrative purposes; the tubes, in reality, will
be thick, opaque steel.)
But—there
is always a “but” with Hyperloops—digging tunnels is hard, slow, and
expensive, all of which are the exact antithesis of what Hyperloops are
supposed to be.
According to Michael Mooney, a professor at the
Colorado School of Mines who specializes in tunneling, planners tend to
use a rule of thumb for estimating project costs he called “1x, 3x,
10x,” meaning elevated projects cost three times more than at-grade
ones, and tunnels cost 10 times more.
The more advanced tunnel
boring machines (TBMs) operating in the world today on major
transportation projects tend to achieve a tunneling rate of about 100
feet per day. Using back-of-the-envelope calculations, this would mean
one TBM would take approximately 32.5 years to dig from Washington, D.C.
to New York City, assuming constant digging 24 hours a day, 365 days a
year.
And
that’s just for one tunnel; there would, of course, need to be at least
two even in this single example, and likely many more than that to
fulfill the kind of ridership numbers HTT and others envision. They
could use multiple TBMs, of course, but given the sheer scale of the
undertaking, it’s hard to see how one project could take anything less
than decades.
These,
I thought, would be sobering realizations for anyone pumped about a
Hyperloop future. But few others seemed fazed by it. The Boring Company,
a venture both run by Musk and Muskian in its vision, thinks
it can tunnel faster and cheaper, at a rate of $1 million per mile, a
figure dozens of times cheaper than industry standards, and hundreds of
times cheaper than urban rail projects like New York’s Second Avenue Subway.
“Let’s
pump the brakes a bit on the million dollar cost,” Mooney said at one
point, before adding, “Boy, I think we’re a long ways away from a
million dollars a mile.”
And
that’s even before accounting for the fact that, here in the U.S., land
ownership rights extend to the Earth’s core. You can’t dig a tunnel
underneath someone’s property in the same way you can fly a plane over
it. Either Hyperloop companies would have to buy their way underneath
people’s land, use a public right of way like a highway or
pipeline—which, again, would sacrifice speed—or, Swartzwelter’s
preferred option, change the law so land ownership extends only to a
certain depth.
No matter which course of action, it’s hard to imagine any of them being speedy.
The
first time I was intellectually sparring with Swartzwelter over this
tunneling issue, he made the off-hand remark that I nevertheless thought
about throughout the rest of the conference.
“Space is easy. Earth is hard,” he asserted. “Nobody is suing you in space.”
Reality Check
The
conference went on like this for two full days, as existential threats
to the viability of the Hyperloop were casually deflected for more
enthusiastic conversations like what shape should the tubes be or how
will we stop riders from losing their shit—both figuratively and
literally—due to their vestibular system becoming all whacky in a
windowless pod shooting through a tube at 700 mph.
About midway
through the second day, I realized this was not so much a conference
about Hyperloops, but in people’s undying faith in technological
innovation to fix the world’s problems. “We’re at the stage of trying to
understand what it’s important to understand,” Cohn said during one
panel, which could just as easily be rephrased to say we don’t
understand very much about Hyperloops at all.
After I expressed
yet another of my seemingly never-ending concerns about the viability of
Hyperloops, Swartzwelter arched that eyebrow again and replied, “I am
an optimist. I believe we will find answers to these questions.”
I wasn’t so sure. Sitting in the back of the conference room by the coffee table, I often felt very alone in my doubts.
The
exception was HARP’s most skeptical member, Ian Sutton, a former safety
engineer who now writes technical books on the subject. To round out
the conference, he gave an unscheduled speech to offer what he described
as a reality check.
“My
perception is members of the public, until they see [a full scale
working Hyperloop], they’re not going to buy into it. It’s just going to
be talk,” Sutton cautioned.
This echoed a point made the
previous day by Colorado Department of Transportation Executive Director
Shoshana Lew, who briefly dropped in, that it’s good practice to “start
to show results before burdening people with construction.” It’s not
helpful, she seemed to be saying, to conduct all your experiments and
demonstrations in secret, as Hyperloop companies tend to do.
In
one of the more grounded moments of the conference, she followed that up
by touting a direct bus service CDOT launched called Bustang (I know) offering direct service from Denver’s Union Station to Boulder.
“Don’t
underestimate,” she added in a remark she meant quite literally about
bus drop-off points but nevertheless landed well philosophically, “the
best solution is easy to get to.”
In this sense, the Hyperloop is
an extremely difficult solution to get to. In his reality check, Sutton
sees several major challenges facing Hyperloops, including but not
limited to: safety (not just achieving it but convincing the public of
it); scalability (“just because something can be done doesn’t mean it
will be done”); funding, including how to deal with the inevitable cost
overruns (Geddes had earlier said it would take “large amounts of
institutional capital” like sovereign wealth funds to make Hyperloop a
reality); timing on actually building a workable network and whether it
comports with the rate of climate change; and legal challenges such as
land takings.
“I think,” Sutton concluded, “an important role for HARP to play is to be a little bit cautious.”
As
much as I respected Sutton getting up in front of a room of Hyperloop
enthusiasts and laying out the reasons they were not working within the
confines of reality, the very idea of Hyperloop enthusiasts exercising
intellectual caution seemed against the point of being a Hyperloop
dreamer in the first place.
Earlier that day over lunch, Will
Kerns, another employee at HTT, regaled me with his vision of how HTT
will completely re-imagine the station experience. Through all kinds of
futuristic ideas like full body security scans built into the tunnels as
you walk to your pod, Kerns said people will have the seamless
transportation experience we can barely even fathom today.
“The
best thing about working for a Hyperloop company is we are inventing a
whole new form of transportation,” Kerns gushed. “We can learn from the
mistakes of all other modes of transportation.”
I thought back to
Whitcomb’s remark that he thought the tubes should be square, not round,
because “I never liked the round tubes.” Or chemist Al Whaller’s idea
that the tubes should be filled not with air, but perhaps hydrogen or
helium, which are less dense and therefore offer lower resistance (never
mind that hydrogen is flammable and helium is very expensive).
Or
Geddes’s suggestion that the tubes be built at grade so they can simply
be picked up and moved to respond to demand. Or Whitcomb’s other remark
that Hyperloops will enable the NFL and NBA to “go global,” one of the
dozens of remarks or hypothetical benefits Hyperloops might offer that
were eaten up in bite-sized chunks before never being explained or
mentioned again.
What
all of these ideas have in common is they are merely that. Ideas,
barely vetted for any semblance of practicality, but thrown out in the
world based on perceived failures of what humans have thus far invented.
To the Hyperloopist, the past is failure, reality is a mistake,
and the future is success. Everything is on the table, and then taken
off the table and shot through a tube, at 700 mph, caution to the wind.
“We
already have this fifth form of transportation,” Whaller opined during
his talk. “It’s pipelines. We just haven’t extended it to people.”
Correction: Monday, September 9, 2019, 4:15 p.m. ET: A previous version of this story incorrectly spelled the Transpod presenter’s name. It is Ryan Janzen, not Jansen.
Correction: Tuesday, September 10, 2019, 4:12 p.m. ET:
A previous version of this story incorrectly referred to the Colorado
School of Mines as the University of Colorado School of Mines.
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