CAFE Electric Aircraft Symposium Set For May 1

On Fri, 8 May 2015 21:28:24 +0000 (UTC), Skywise
wrote:

Larry Dighera wrote in
news


I was thinking it might be necessary to heat the LH2 so that it could
keep up with the fuel demand of the fuel-cell producing the power to
produce the motive thrust.

Stop refridgerating it? LH2 is -423F/-253C.


That brings up an interesting opportunity for an electric power plant:
superconductivity. This liquid hydrogen fuel concept is beginning to become
more interesting... http://en.wikipedia.org/wiki/Superconductivity

Larry Dighera wrote in
:

On Fri, 8 May 2015 21:28:24 +0000 (UTC), Skywise
wrote:

Larry Dighera wrote in
news


I was thinking it might be necessary to heat the LH2 so that it could
keep up with the fuel demand of the fuel-cell producing the power to
produce the motive thrust.

Stop refridgerating it? LH2 is -423F/-253C.


That brings up an interesting opportunity for an electric power plant:
superconductivity. This liquid hydrogen fuel concept is beginning to
become more interesting...
http://en.wikipedia.org/wiki/Superconductivity

I really think you are completely missing the problem.

It takes energy to do these things. It is not a source of
energy.

It takes energy to make the hydrogen because it doesn't exist
in it's free state naturally on Earth. Currently, most hydrogen
is produced from natural gas, with CO2 as a byproduct.

It takes energy to compress it, or liquify it.

It takes energy to refridgerate it to such low temperatures.
and to keep it there.

Where is all that energy going to come from?

And you will never ever EVER get out of LH2 the amount of energy
that went into producing it.

It's a simple numbers game. Balance the books. You're in the red.

On the other hand, if you do find an alternate SOURCE of energy,
one that is so cheap and plentiful and does minimal or no harm
to the environment, then maybe you can look at things like LH2 as
a medium to store and use energy (after solving the CO2 problem),
and all the losses in it's production won't matter because the
actual SOURCE of energy is so cheap and plentiful you don't mind
wasting a bit of it.

Nuclear is the only source of producing mass quantities of energy
that I know of, but it has it's own inherent risks and challenges,
most of which I think are solvable except for the public relations
side of it. But, it does not emit CO2 which is the major argument
regarding fossil fuels.

Fusion reactors have been a decade away for the past 5 decades.

There aren't enough rivers to dam, and it harms ecosystems.

Wind is intermittent and too little. And kills birds.

Solar is viable, but only works during the day. It can be scaled
to compensate along with appropriate electricity storage mechanisms
to offset night and cloudy days. Perhaps Tesla's house battery is
a step in this direction? However, solar cells are still too
expensive to force people to switch. Folks can't see CO2. They
can't feel .2 degrees Celcius. But they CAN see the numbers on
their credit card bills.

Which brings up another point. The energy problem is as much a
human psychology problem as it is a technical problem. To put it
bluntly, the vast majority of people don't give a F.

Brian
--
http://www.earthwaves.org/forum/index.php - Earth Sciences discussion
http://www.skywise711.com - Lasers, Seismology, Astronomy, Skepticism
Sed quis custodiet ipsos Custodes?

On Mon, 11 May 2015 20:57:57 +0000 (UTC), Skywise
wrote:

Larry Dighera wrote in
:

On Fri, 8 May 2015 21:28:24 +0000 (UTC), Skywise
wrote:

Larry Dighera wrote in
news


I was thinking it might be necessary to heat the LH2 so that it could
keep up with the fuel demand of the fuel-cell producing the power to
produce the motive thrust.

Stop refridgerating it? LH2 is -423F/-253C.


That brings up an interesting opportunity for an electric power plant:
superconductivity. This liquid hydrogen fuel concept is beginning to
become more interesting...
http://en.wikipedia.org/wiki/Superconductivity

I really think you are completely missing the problem.

It takes energy to do these things. It is not a source of
energy.

It takes energy to make the hydrogen because it doesn't exist
in it's free state naturally on Earth. Currently, most hydrogen
is produced from natural gas, with CO2 as a byproduct.

It takes energy to compress it, or liquify it.

It takes energy to refridgerate it to such low temperatures.
and to keep it there.


Photovoltaic powered electrolysis of H2O would be my choice to produce
hydrogen. It might even power the compressor and condenser to liquefy it also.
Other than the energy used to make the solar cells, there is no energy cost and
no byproducts. Making this practical will take some ingenuity, but
theoretically, I'd suppose it is possible.


Where is all that energy going to come from?

And you will never ever EVER get out of LH2 the amount of energy
that went into producing it.


With free solar power, that isn't much of an issue.


It's a simple numbers game. Balance the books. You're in the red.

On the other hand, if you do find an alternate SOURCE of energy,
one that is so cheap and plentiful and does minimal or no harm
to the environment, then maybe you can look at things like LH2 as
a medium to store and use energy (after solving the CO2 problem),
and all the losses in it's production won't matter because the
actual SOURCE of energy is so cheap and plentiful you don't mind
wasting a bit of it.


Yep.


Nuclear is the only source of producing mass quantities of energy
that I know of,

If energy production is decentralized, mass quantities aren't required. Think
every home with rooftop photovoltaics.

Of course, that won't do for airline operations, but 250 megawatt solar
facilities are in operation in California and Nevada now:
http://investor.firstsolar.com/releasedetail.cfm?ReleaseID=793411, and even
the Air Force has a 14.2 megawatts installation:
http://www.cnet.com/news/air-force-base-in-nevada-goes-solar-with-14-megawatt-array/#!.


but it has it's own inherent risks and challenges,
most of which I think are solvable except for the public relations
side of it. But, it does not emit CO2 which is the major argument
regarding fossil fuels.


You believe the "inherent risks and challenges" are solvable, because they have
been woefully underestimated as have the costs.

The way I see the current state of nuclear is a lot like the oceans. When the
sea is calm, things are fine. But the sea has the potential for ENORMOUS
destruction, as born out recently in the Fukushima tsunami. Despite the sea
wall, the sea managed to cause massive destruction beyond what engineers had
estimated. And there's NOTHING to prevent an even larger tsunami from
occurring in the future.

The nuclear industry has voluntarily created a $12.6-billion insurance fund and
enacted legislation limiting their liability to that amount. The Fukushima
disaster is estimated at $500-billion. And after 29 years hundreds of square
miles of Chernobyl is still uninhabitable. Nuclear plants are continually
venting radio-active products into the environment during normal operation. And
in the event of a containment breach, the spread of radioactivity can be
alarming. Here's what happened as a result of the Chernobyl meltdown:

Chernobyl disaster effects
National and international spread of radioactive substances

Four hundred times more radioactive material was released from Chernobyl
than by the atomic bombing of Hiroshima. The disaster released 1/100 to
1/1000 of the total amount of radioactivity released by nuclear weapons
testing during the 1950s and 1960s.[88] Approximately 100,000 km² of land
was significantly contaminated with fallout, with the worst hit regions
being in Belarus, Ukraine and Russia.[89] Slighter levels of contamination
were detected over all of Europe except for the Iberian
Peninsula.[16][90][91]

The initial evidence that a major release of radioactive material was
affecting other countries came not from Soviet sources, but from Sweden. On
the morning of 28 April[92] workers at the Forsmark Nuclear Power Plant
(approximately 1,100 km (680 mi) from the Chernobyl site) were found to
have radioactive particles on their clothes.[93]

So, from my point of view, nuclear fission power is far too dangerous for
consideration as a "free" and "clean" power source. Just ask the residents who
have to pay to saw up, and haul away the entire San Onofre power plant. And
without a safe place to store the radioactive waste, it is just plane
irresponsible. And the potential for catastrophe has been under estimated by
several orders of magnitude, just like the potential of the sea.

But the military wants it, and the war profiteers are happy to oblige....


Fusion reactors have been a decade away for the past 5 decades.


How many years passed between the time Leonardo da Vinci conceived of the
helicopter and it's production?


There aren't enough rivers to dam, and it harms ecosystems.

Wind is intermittent and too little. And kills birds.


I recall living under the flight path of LAX in the '50s. You couldn't hold a
conversation at dinner time for the din of arriving B-707s. Today, I reside
very close to KSBA, and the airliners are significantly quieter than the GA
piston aircraft. Progress takes time...


Solar is viable, but only works during the day. It can be scaled
to compensate along with appropriate electricity storage mechanisms
to offset night and cloudy days. Perhaps Tesla's house battery is
a step in this direction? However, solar cells are still too
expensive to force people to switch.


Responsible people are switching voluntarily; no need to force them.

The price of solar panels is dropping all the time. Last I checked, it was
possible to purchase solar panels on eBay for ~$1/watt.


Folks can't see CO2. They
can't feel .2 degrees Celcius. But they CAN see the numbers on
their credit card bills.

Which brings up another point. The energy problem is as much a
human psychology problem as it is a technical problem.


The way I see it, it's more a matter of entrenched wealthy businessman
protecting their cash cows...


To put it bluntly, the vast majority of people don't give a F.

Brian

Fortunately, that is changing ...

So, the use of LH2 to generate electricity with a fuel-cell to drive an
electrical motor that employs superconductivity seem a worthwhile course to
investigate for powering future aircraft. Granted there are currently
obstacles to achieving a viable system, but I don't believe physics precludes
it; only the development of the technology stands in the way.

On 5/14/2015 1:49 PM, Larry Dighera wrote:
It takes energy to make the hydrogen because it doesn't exist
in it's free state naturally on Earth. Currently, most hydrogen
is produced from natural gas, with CO2 as a byproduct.

It takes energy to compress it, or liquify it.

It takes energy to refridgerate it to such low temperatures.
and to keep it there.

Photovoltaic powered electrolysis of H2O would be my choice to produce
hydrogen. It might even power the compressor and condenser to liquefy it also.
Other than the energy used to make the solar cells, there is no energy cost and
no byproducts. Making this practical will take some ingenuity, but
theoretically, I'd suppose it is possible.


Sorry, but there is no free energy, and there is no totally clean
energy, not even solar. At present, there isn't enough solar energy to
go around. There isn't likely to EVER be enough solar energy to go
around, that's also true of wind and hydro power.

More importantly, if we divert solar energy from the grid to make
hydrogen, then we must make up the difference from somewhere else, which
means burning more fuel. So there is no advantage to diverting "clean"
energy towards something like producing hydrogen, whilst we are burning
coal (or whatever) to make grid power. Energy is energy! Wasting
energy is always a dirty thing to do, even if it's solar. And the
hydrogen energy cycle is inherently wasteful.

On Thu, 14 May 2015 14:14:43 -0400, Vaughn wrote:

On 5/14/2015 1:49 PM, Larry Dighera wrote:
It takes energy to make the hydrogen because it doesn't exist
in it's free state naturally on Earth. Currently, most hydrogen
is produced from natural gas, with CO2 as a byproduct.

It takes energy to compress it, or liquify it.

It takes energy to refridgerate it to such low temperatures.
and to keep it there.

Photovoltaic powered electrolysis of H2O would be my choice to produce
hydrogen. It might even power the compressor and condenser to liquefy it also.
Other than the energy used to make the solar cells, there is no energy cost and
no byproducts. Making this practical will take some ingenuity, but
theoretically, I'd suppose it is possible.



Sorry, but there is no free energy,


Agreed. I don't think that is at issue here.


and there is no totally clean energy, not even solar.


Aside from the waste products associated with the production of solar cells,
I'm not aware of any polluting products emitted by photovoltaic electricity
generation.


At present, there isn't enough solar energy to go around.


Mmmm... When it isn't cloudy, there's about 1KW per square meter. It would
seem, that if you've got the land area, there's more than enough solar energy
"to go around", at lease here in southern California. What makes you say that?
Are you saying, that there currently hasn't been enough solar energy generating
stations built to supply the entire nation/world?


There isn't likely to EVER be enough solar energy to go around,


Are you able to cite a credible source that supports that assertion? What
leads you to believe that?


that's also true of wind and hydro power.


Are you intimating that petroleum based electric generation is the sole
technology that is able to supply the world's needs?

Again, are you able to cite a credible source that supports your an opinion?


More importantly, if we divert solar energy from the grid to make
hydrogen, then we must make up the difference from somewhere else, which
means burning more fuel. So there is no advantage to diverting "clean"
energy towards something like producing hydrogen, whilst we are burning
coal (or whatever) to make grid power.


I wasn't suggesting that grid electricity be used to electrolyze H2O. I was
thinking that solar cells on the roof of a home might be employed electrolyze
water to produce H2 and O2 that would be stored, and used to produce
electricity at a later date.


Energy is energy! Wasting energy is always a dirty thing to do, even if
it's solar.


So, you're saying, that when the Sun is shining on bear earth, we are doing a
"dirty thing" by not capturing the solar energy? Or am I missing your point?


And the hydrogen energy cycle is inherently wasteful.


It is true that electrolysis of H2O is not too efficient yet. Until recently
fuel-cell technology hasn't been too efficient either (about 30%). but when I
visited the 2014 Consumer Electronics Show in Las Vegas, an automotive engineer
assured me that they had increased fuel-cell efficiency to 60%, so presumably
the art is making strides toward increasing efficiency. And, if/when H2 power
becomes more mainstream, I would expect the resulting increase in R&D funding
to continue that trend.

How efficient is distilling petroleum into gasoline/kerosene? How efficient
are internal combustion engines piston and turbine?

I appreciate your interest in the subject, but I'm at a loss to understand your
points. And without any supporting research studies or hard data, I'm unable
to put much credence in your unsupported assertions.

Please tell me more about what you KNOW about this subject.