The article says that the prototype vehicles carry about 5kg H2 at 10,000 psi. Assuming the tank is at a balmy 80F, that hydrogen occupies about 24gallons (basic PV = nRT calc). The article also says that a kg of H2 is roughly equivalent to a gallon of gasoline, so that's about 5 times the volume of ordinary, liquid, atmospheric pressure gasoline, just for fuel.
And that's just the hydrogen. What about the pressure vessel? And all of the ultra-high pressure lines and pressure regulation and risk of sitting on a bomb?
It's cool that we're experimenting with this technology but I can't see it being anything but a niche application for a long time to come. Petroleum prices have to get redonkulously expensive before this tech becomes even remotely attractive for a common user.
Windhorn, Six months for an FMEA on one component? Either they are: a.) evaluating it on a molecular level, or b.) doing it part time with a weekly FMEA committee meeting, or c.) Milking the project most strenuously. I can see that there could be 40 pages of report, but it is unomaginable that the FMEA could take that long, if the team understood the product beuing evaluated. If it was a team of "avaerage" engineers that had never seen the product previously and had never worked to gether before then it might take a lot more time. But why in the whole world would a team be selected for an FMEA that did not understand the product intimately. OUr team that worked so (apparently rapidly) knew and understood every aspect of the product completely, prior to our first time spent on doing the FMEA. There is no other raional way to approach such an important project.
WilliamK writes: "And air pollution comes from many sources and getting rid of all of them will reduce our standard of living to staying in caves and eating rocks. OK, that is an exageration, I know, but I am also aware that there are a whole lot of people, some who are actially well meaning, who want to force us into some utopian realm by taking away most of our freedoms, which include driving away from them in our carbon-based fueld automobiles."
Funny, when I do the math, removing 3.2M deaths and many times that illnesses/injuries from fossil fuel pollution, frees up about $3T to be added back into the global economy to improve the quality of life on this planet ... which is almost enough to pay the entire cost of needed high temp reactors.
If we simply stop producing gasoline/diesel cars/trucks, then other than a small number of collectors vehicles, everything else can be phased out to H2/EV hybrids in two decades or so by natural attrition. Providing H2 conversion kits at a low subsidized cost, will entice even a significant number of car collectors to upgrade, just so they can drive them everyday, without having to find gasoline/diesel which will start to get scarce/expensive with lower volume use.
I don't see any reason to come knocking at your door, asking for your car keys.
WilliamK writes: "But you will find that nobody dies from atmospheric CO, but rather from enclosed space incidents."
So? what's the point? Carbon monoxide poisoning is the most common cause of injury and death due to poisoning worldwide
And it affects an unborn child significantly worse, because the CO binds to their blood in significantly higher percentages, to the point that it means the death or injury of the child, while the mother is just sick from it. Which is a statistic that probably isn't being kept.
All electric homes and shifting to an H2 fuel gas based transportation are two ways to avoid over 20,000 deaths each year world wide, and a significant number of brain and organ injuries for those with near death concentrations.
This isn't the biggest reason for becoming a fossil fuel free planet, unless you are one of the 50,000 or so affected by this each year.
I have nothing against nuclear power plants, I think that they are a god idea but they certainly need to be designed to survive multiple systems failures. BUT that should not be that much more effort, an FMEA for the complete plant would probably take a team of engineers less than a week. It would certainly be time and effort very well spent and could never approach 1% of the cost to build the plant. So if the power plants can be built using a bit of common sense, with the politicians kept at bay for the duration, we could have a good chance at atomic power to replace the coal fired kind.
But you will find that nobody dies from atmospheric CO, but rather from enclosed space incidents. And a lot of people die from fires, which really can't be blamed on fossile fuel.
And air pollution comes from many sources and getting rid of all of them will reduce our standard of living to staying in caves and eating rocks. OK, that is an exageration, I know, but I am also aware that there are a whole lot of people, some who are actially well meaning, who want to force us into some utopian realm by taking away most of our freedoms, which include driving away from them in our carbon-based fueld automobiles.
I've posted a number of sources to review for US deaths/injury, and world wide death/injury .... some are below ... which easily total more than world wide nuke power related death/injury.
See the following links for US deaths, which are far from zero, plus the other links I provided reciently. Us deaths are significant, world wide are higher. There are particulate related deaths/injury, and chemical related deaths/injury.
This article states: http://www.worldwatch.org/air-pollution-now-threatening-health-worldwide "In the U.S., air pollution causes as many as 50,000 deaths per year and costs as much as $40 billion a year in health care and lost productivity."
The article www.nrdc.org/health/kids/ocar/chap4.asp states: "Which states "A recent study estimated that approximately 64,000 people in the United States die prematurely from heart and lung disease every year due to particulate air pollution".
http://www.countercurrents.org/cc191212.htm states: Worldwide, a record 3.2m people a year died from air pollution in 2010"
The article en.wikipedia.org/wiki/Carbon_monoxide_poisoning states: "In the United States, approximately 200 people die each year from carbon monoxide poisoning associated with home fuel-burning heating equipment. Carbon monoxide poisoning contributes to the approximately 5613 smoke inhalation deaths each year in the United States. The CDC reports, "Each year, more than 500 Americans die from unintentional carbon monoxid"
Pat, it sounds like you are closer to that technology than I am. What sizes and resulting weights are a subject for a detailed computational investigation, since anything else is a guess. Some folks guess very well, but in that area I would need to do all of the math. Good engineering practice dictates that when one does not know, one researches and finds out. But for a hydrogen fueld car, even after you have the best size gas bottle and working pressure all calculated, the serious issue of avoiding leaks is still there. Keeping a hydrogen system intact in a lab environment takes some effort, but in a car that shakes and vibrates it could be much more challenging. That is the basis for my conclusion that it may not be worth the effort.
Some people, it seems, just don't understand that not everything that can be done can be done satisfactorily and with a reasonable amount of effort. But perhaps there could be some reasonable means to provide hydrogen fuel for all vehicles and power generation and heating applications, as our departed blogger suggests. Or possibly not.
It is still not clear that "many are dying from fossile fuels", at least not around here, in the US. So without agreement about that basic premise the rest of the argument becomes rather "secondary". The two people who I knew who died from fossile fuel use died because of motor vehicle accidents, not especially related to vehicle emissions.
In an age of globalization and rapid changes through scientific progress, two of our societies' (and economies') main concerns are to satisfy the needs and wishes of the individual and to save precious resources. Cloud computing caters to both of these.
For industrial control applications, or even a simple assembly line, that machine can go almost 24/7 without a break. But what happens when the task is a little more complex? That’s where the “smart” machine would come in. The smart machine is one that has some simple (or complex in some cases) processing capability to be able to adapt to changing conditions. Such machines are suited for a host of applications, including automotive, aerospace, defense, medical, computers and electronics, telecommunications, consumer goods, and so on. This discussion will examine what’s possible with smart machines, and what tradeoffs need to be made to implement such a solution.