Any chance we could get links to high resolution images of figures 1 and 3?

Edit: I see they are in the PDF so never mind...

This is a fantastic post BTW!

Vehicle Characteristics. This analysis shows that light personal vehicles perform far better than heavy ones. Vehicle and infrastructure embodied energy were not considered, and such an inclusion would make light vehicles appear even more attractive. Since people tend to travel individually when possible, and energy resources are becoming increasingly scarce with respect to demand, it would appear that personal vehicles of the future will be very light by today’s standards. High performance vehicles also tend to be compact and streamlined. Commercial airliners perform well because people are willing to crowd themselves in an aerodynamically optimized fuselage for fast, long distance travel. The greatest gains in performance may be obtained by redefining vehicle use mode, tare weight, shape and dimensions, rather than changes to vehicle motor or fuel system.

One can see how far vehicle manufacturers have to go in this respect when one takes a quick look at GM 2010 models.
Consumer demand still dictates a certain degree of comfort and safety that keeps vehicle weight high.

http://www.gm.com/vehicles/results.jsp?bodyStyle=12&bodyStyle=13&bodySty...

Hey there, My name is Isaac, I'm not from these parts. I have some questions and see that this is the place to ask them.I see that there is almost a dangerous amount of brain-power on this site. I love it. I am not an engineer or physicist,tho' I work as a freelance consultant for different fields, so I do have some understanding of things...anyways..

If water based mud is provides the strength when it stops moving and starts to settle or " gel " , and it is a slurry mixture, and realistically not much different than cornstarch and water, in terms of particle equidistant positioning in the fluid, could it be considered to be a Non-Newtonian fluid..?

If the only way to rapidly overtake opposing pressure, is by producing stronger opposing pressure in a 3 dimensional space, that is really about density VS density...? It is what allows the rapid transit of waves, the rate of travel is determined by opposition of the intensity of the wave to the density of the fluid., ...the law of inverse proportion....?...I apologize if I do not make sense here, lol.

If H2S stress cracking is a common problem with sour oil, and the flow from this deposit has a high sand/particulate content from the surrounding shale/sand that's possibly been acting like a cnc water-jet on the surface of the inner diameter of the casing, does this make it prone to failure.

I saw by reading one of yesterday's posts, that there is space left as a void in-between the casing and the concrete used to line the bore. Does that mean that stratigraphic pressure that normally helps provide structural integrity to the contents of the wellbore, ie : the casing, ..is not there..?

If a stressed pipe is structurally reinforced by pressure applied from the outside, and it keeps stress-cracks in the plastic zone from creeping, but there is a void outside the casing, then it would make it more prone to fail from the inside when greater pressure is applied...?

A 3 mile column of mud with 2 concrete plugs, set no more than 200' from the mudline is the norm for plugging and abandoning a well..?

What happens if a 3 mile column of mud pops the casing at these depths...? If an established fluid column is given space to move at the bottom, and releasing the bottom pressure ( by a new void created by casing failure )breaks the " gelled " structure of the mud at the bottom of the column..and this 3 mile column of mud suddenly applies gravity waves to the reservoir..is that what will produce a massive " kick " ?

Just for the sake of knowing..There are other types of minerals that they have not mentioned that are actually heavier than Barium Sulfate

Possible substitutes for barite, especially in the oil drilling industry, include other similar minerals, such as celestite (strontium sulfate, and iron ore. A German company is producing synthetic iron ore (hematite) which is proving a good substitute for barite.

Also, I understand that this type of alloy can flex 6 degrees for every 10'...is that true..?

And,lol...sorry, Has anybody taken into consideration the Ursa-Princess waterflood project, or the East Independence Hub projects...?...they are joint BP collaborations in the same area that the Horizon blowout....WIKO Flowserve pumps is all I will say about that matter., ...I have some more on my blog..

Ok, that's all, thanks for taking the time to answer.

http://mentaljudo.blogspot.com/

Lighter and smaller vehicles makes sense to me. How much more efficient can IC engines get? I imagine we have reached the limits of improving such technology. Would converting to light duty diesel engines/fuel help us in terms of refining? If heavier inputs become the norm for our nations refineries, would it make sense to switch to produce diesel instead of gasoline? Or do we lack such refining capacity? And, or would it be too expensive to replace the gas motor passenger fleet with diesel engines?

I suppose the ultimate goal is to get away from all ffs for transport.

We lack the political will power to plan for decline, adopt depletion protocols as Heinberg would say. We desperately need to change course with respect to our energy consumption here. I fear many the changes we make will be forced upon us rather than planned for, in the near future.

Here is a list I compiled on the energy efficiency of various modes of transport, measured in pmpg (person-miles per gallon of gasoline). Fairly similar to the one above, except that I measure the pmpg of freight vehicles differently (I equate 4000 lbs of cargo to one person, since that's the avg. weight of a consumer vehicle today when all the big SUVs etc are factored in).

http://truecostblog.com/2010/05/27/fuel-efficiency-modes-of-transportati...

Looking at the chart, I noticed that faired bikes have over 3 times the speed of a racing bike for the same energy expended. So for the same sweat and given that I don't have any traffic stops, that means I could get to work in 1/3 the time as I do now. Sign me up if this is true. (Even though I will eventually get flattened.)

BTW, new road bikes above a certain price-point have much more efficiency and durability than the old clunkers of a few years ago. Don't get an old used Schwinn bike unless that is the only thing you can afford. GD&R

That's the current record holder (PacCar II 5'385km/l)

PS:
about Energy Measurement:
1J = 1Nm
1N = 0,102kg * 9,81m/s^2 (i.e. the weight of approx 100g on earths surface)

thus 1J equals dropping 100g (a small apple) for 1m on our planet

I now routinely walk to work and back, or public transit to work + walk home.

My carrying capacity is maybe 5%, as I have my work laptop in a soft briefcase :)

Walked 20miles this week: One round-trip walking on Monday and Wednesday, and on Thursday I only walked home after public transportation to work.

My ride is not green at all. It is red.

Jeff,

You've analyzed the MPG of electric vehicles using the average utility mix of generating sources. I think a better choice would be the average mix at night, when most vehicles would charge. This will increase the share of wind and nuclear significantly.

More importantly, EVs are uniquely suited for a synergistic pairing with intermittent wind production, as EV charging can be scheduled dynamically for periods of maximum wind generation. Thus, EV's actually support wind power buildout.

I think it would be fair to assume that EVs are charged using wind and nuclear almost exclusively. That will make them fare much better in your analysis.

-------------------------------------

You point about people needing exercise is a good one. Still, I think the 9:1 ratio of FF inputs to food kilocalorie outputs needs a bit more emphasis, as it's a real, and very large, factor.

-------------------------------------

When it comes right down to it, any kind of electric transportation is far, far better than any other kind of transportation with regard to either CO2 emissions or oil consumption. Electric bikes are better than electric cars, but the difference between the two is much smaller than the gulf between them and everything else.

My ride is not very green. It is an older large pickup truck. It would be nice to have a smaller hybrid or high mileage vehicle to do most of my driving when the pickup truck is not needed.

However, my miles driven footprint is fairly small, maybe 100 miles per week. In my previous career my average was closer to 100 miles per day on workdays, maybe 500 miles per week.

Obviously driving higher mpg vehicles is better, but so is driving less miles.

500 miles @ 30 mpg = 16.67 gallons of gas

100 miles @ 15 mpg = 6.67 gallons of gas

What about the energy required to build new high mpg vehicles to replace older low mpg vehicles when they are only driven a few miles per week? How long does it take to recoup the energy expenditure to build the new vehicle?

Not trying to rationalize my situation driving a low mpg vehicle, less driving with better mileage would be better for sure. Building websites is my second job and I'm working to make that my main job which would mean driving even less miles.

To suit my needs for speed, reliability and style I built an e-bike from scrap bikes and electrical conduit with a drive system from China. It is about 10 feet long, recumbent, springer suspension, low-slung and looks like a black chopper from a Mad Max movie. Sorry, no pics at the moment. It is called The Blackbird. People see it fly past like a low-flying SR-71 and simply cannot believe their eyes. I get stopped all the time for pictures and videos.

36 volts, paired LiFePO batteries for a total 30Ah. Range is about 40 miles without pedaling, perhaps 80 miles with. Including a nice sized trailer it replaces a car for 95% of the things I do, and I ride it about 1,200 miles a month to/from work and for pleasure and to do errands around town.

It charges in about 5 hours. The amount of power being consumed seems trivial. It is easy to believe that after the fixed cost of building the bike it is virtually free to ride it, apart from the amortized cost of battery replacement, which I calculate to $50/month for 1,000 miles a month. But I am probably really hard on the batteries.

More to the point: This machine that contains 5% of the materials and 1% of the labor and infrastructure that goes into building a Prius hybrid (which is held as the benchmark these days) provides 90% of the functionality if a Prius is being used mostly to move one person under 30 miles one-way to/from work on surface streets. I see this scenario play out constantly on my ride, you know who you people are. Plus I get exercise, and meet people, and enjoy the sights, and it only adds an extra hour to a 30 mile commute, an hour I would spend in the gym anyway to get the same exercise.

There is no reason for more people not to ride these things for commutes or errands at or under 30 miles one-way, 60 miles round-trip. I had to make this bike in my garage, but that could easily change if there was demand or incentives. GM should make these by the millions. They should be forced to do so.

The savings to society by this change in scale are nearly impossible to overestimate. Blackbird doesn't harm roads. Doesn't pollute the communities I ride through. Doesn't make any noise. Wouldn't kill anyone if I hit them. Doesn't take up a parking space. Doesn't require massive freeways or ubiquitous service stations or vast networks of charging stations. It charges like a laptop computer, in nearly the same amount of time. It is human-scale, humane, and a game changer in black and chrome. It is the distillation -- in metal -- of pure sex.

We need to get people out of personal cars. Period. The rest then takes care of itself.

One must be cautious about the widespread claim that it takes nine calories of fossil energy to provide one calorie of food energy to human beings. That may be true as an AVERAGE. But there vast differences in the inputs themselves, along with big differences in diet. A lot of rice-and-bean eating vegans tend to be self-locomoted, while grain-fed-marbled-steak lovers tend to rely on nineteen-foot-long, three-ton motorized codspieces branded with names like "F250" and "Avalanche" and "RAM Tough".

There is no way it takes nine calories of FF to put one calorie of wheat flour on the grocery shelf. And for people who use muscle-power to grow some food at home, the FF input for those foods is closer to zilch. Let's remember that throughout history we humans have often managed to produce more than enough food calories for ourselves without ANY FF inputs. Our main problem today is all the hungry machinery.

The result is a ratio of the benefits of vehicle use (payload mass, average speed and distance moved) to the cost, expressed in universal currency as thermal energy.

It is not intuitive why the product of mass, speed and distance should be the "benefit". Mass times distance seems to be directly related to "benefit", i.e. the benefit of moving a million tonnes of oil from port to port or the benefit of moving a 70 kg person from home to office.

However, speed tends to be more of a constraint and related to non-energetic considerations of the value of time. If the distance from home to office is fixed, then the modes of transportation to be considered are those that cover the distance in some reasonable number of minutes. A shorter time may be prefered, but I doubt that the value relationship is accurately represented by multiplying the kg-km by m/s.

Tri-hybrid Stealth, gets and estimated 200mpg and still travels over 100 miles per hour. The Stealth runs off electric, diesel and human power produced through pedaling.

http://trihybridstealth.com/WordPress/2010/07/06/team-stealth-plans-5000...

Three wheel vehicles seem to be leading the mpg race

http://www.dirigocar.com/

Solar/Human Vehicle

http://www.triveloproject.com/

with electric , the goal is Watt hours/mile
my favorite ..
http://www.evalbum.com/2311

Many colleges are working on efficiency ...

http://mechanicaldesign101.com/2010/05/30/2010-uci-energy-invitational-i...

This paper shows why (we) transit advocates need to be very careful about their (our) claims. From an energy consumption standpoint, existing AMTRAK and urban bus services are not dramatically better than our existing automobile fleet – especially when these mass transit modes operate well below passenger carrying capacity (Table 1, fourth column: Person-MPG). This is not to dismiss the enormous land-use benefits of mass transit over the private auto, but claims that buses and trains are significantly more energy efficient (and less GHG intensive) than autos will undermine (our) credibility. That said, passenger rail in other countries is quite a bit more energy efficient than cars.

It is worth noting that air travel is pretty darn good on a Person-MPG basis. The “problem” with airplanes, so to speak, is that we can travel so far in such short periods of time! Well, that's not really true: being inanimate objects the airplanes aren't the problem; it is our lusts for speed and novelty, our desire to pack our life lists with impressive evidence of our worldly experiences.

One great thing about airplanes is that they require very little on-the-ground infrastructure relative to the number of people moved. Admittedly, airports themselves are massive things, but the planes need no roads or tracks between them. And those "betweens" are long!

Back to passenger rail efficiency in the USA; how much could it be improved if we revisited passenger car safety standards (which are probably 100 years old by now) along with evaluating what could be done with contemporary high-strength materials and modern design tools (CAD). Seems to me that existing passenger cars (which may be based on 50+ year-old designs) are God-awful heavy things relative to their human cargo.

Perhaps (probably) some European companies have already done this, and all we need to do domestically is copy them. Which requires setting nationalistic hubris aside, of course...

I mostly drive a '93 Dodge, Cummins powered pickup. It carries around my equipment and tools just fine, and averages 19 mpg. I used to use a minivan for the same job, and when loaded the same, got about 20 mpg, and it was the most fuel efficient minivan ever built.

However, I wore out the minivan at 220,000 miles. The truck, with 280,000 is going strong and will be for another 500,000 to 800,000 miles. Which conserves resources better? The truck, obviously.

Not only that, it's a pre-cat diesel, meaning the soot is large particle, mostly harmless, and biodegrades immediately. In other words, it's cleaner than the minivan.

Just got back from Rotterdam. I asked a rare cab driver how they managed to plan a city around bikes. He said first the Germans bombed them, then the allies bombed them until only two buildings were left standing. With all the new room they were able to incorporate the bike paths into the new development. So aside from blowing our cities level and starting over maybe we could shut them down and build more efficient cities down the road. Cities in Asia were often abandoned because they suitable for living. Just a thought.

Jeff - One question about the Table. The Column titled "Form" lists either "E" or "C" - at first I thought that this was Electric vs. Combustion, but that doesn't make sense... what do the letters stand for?

Great article.

1) it gave me this thought (background- we are likely to require container ships in the Santa Barbara channel to slow down to reduce pollution):
Ocean-going ships often (typically?) cruise at a speed like 20 knots, when roughly 12 knots provides much better fuel economy. YMMV... anyway in the case of tanker ships, slowing down may not save any energy at all and may in fact be worse. Why? Because the tankers crossing the ocean are part of a system, exactly like an oil pipeline.

So say we slow from 20 knots to 10. Say that saves half the fuel used to move the ship. That means just half as much fuel-cargo is getting through, and we have to double the number of tankers at work. Not only does that lose all efficiency gained, it might add embodied energy costs if new tankers have to be built.

Sorry if thats been discussed to death, but I learned not to always assume that lower fuel use is always more efficient.

2) a quibble: I think the Puffin is total vaporware and in fact cannot fly. According to me no battery on earth contains enough energy to power a VTOL larger than an RC copter. However those RC copters do fly, so maybe I am wrong in the absolute sense.

While this is an interesting post indeed, we need to really think about the value of:

Human Happiness and Quality of Life / Eth

Or:

Human Happiness and Quality of Life / Mass * Speed * Distance

Unless we look at the problem of the survival of Civilization at the cliff of Peak Oil, Rising Population, Shrinking Topsoil and Water flows in these terms ponderings of the like of this post will do nothing real to reduce our addiction to high flows Eth per capita. The article here may tell us (falsely) that its cool to jet about because we get such a great mileage from it. But that is a moot argument indeed if traveling these huge distances in absolute terms is causing a huge amount of Eth flow (which is a limited resource) for what may be just another trip to Disneyland.... While a family elsewhere took their backpacks and went for a camping trip in the nearest bit of beautiful nature...

The greater the force on the chain of bicycle the greater the friction. To increase the efficiency of a bicycle, the chain must be removed or designed to either keep the friction constant or reduce it.

I have a nice Trek road bike. Carbon fiber, Dura Ace, Rolf wheels...the works. The thing about it? It eats tires like crazy on these city streets. People are slobs! I have to swerve around so much broken glass. I've since upgraded to some heavy duty tires, tubes (heavier) and they seem to be holding out better, for now.

If i was starting from scratch i'd go with a basic mtn bike, with semi slicks. I'd skip disc brakes (i have them on a mtn bike, seem overrated). I'd also shoot for steel (vs AL), although with suspension AL works fine. I'd also spend as much as i had to on a GOOD seat. Nothing worse than your pieces going numb.

There's some narrowed focus in some parts of the discussion above.

Primarily, "safety" is narrowly defined to be absence of bodily injury. Unless you think a heart attack is "safe", the consequences of not getting enough exercise have to be factored into any safety analysis. So, given this, we must spend some time each week getting exercise in order to reduce the (quite high) risk of heart attack, stroke, diabetes, etc. Some forms of locomotion (notably, walking and cycling) also provide exercise. This complicates the accounting -- arguably, the first few hours of walking or cycling each week, should be regarded as exercise, not transportation, and thus you arrive at your destination in no time at all, if you cycle/walk to someplace you were going anyway. Similarly, the "fuel" charge for walking or cycling, up to the first few hours each week, should also not be charged to transportation, because safety requires that you get the exercise anyway, and exercise burns calories.

Given this slightly broader focus on safety, cycling becomes an incredibly efficient means of transportation.

Note that the number of US deaths from diseases-of-the-unfit is huge -- 616k from heart disease, 135k from stroke, 71k from diabetes. That's not counting cancers, some of which (colon cancer) have their risk reduced by exercise. Car crashes are not even 5% of this.

Obviously, we all die sooner or later, but later is nicer. Exercise reduces your yearly risk of death, and apparently reduces the cardiac disease mortality rate by 28%.

Obviously, this assumes a rational approach to mortality and risks, but I am sure everyone reading this has signed up for that :-).

Note that this does not say much about small cars versus large cars, or that we should junk our cars and ride bikes. What it does say is, if you are not getting enough exercise, and you are not incredibly worried about that, it is irrational to worry about the relative risks of small or large cars. And, further, it suggests that it is poor accounting to "charge" cycling and walking for fuel calories or transit time, up to the weekly quota of time/calories that we should be spending on exercise anyway.

Hey hey Jeff,

How do airships/zeppelins compare in this analysis? They were fuel efficient and carried a heavy payload but not very fast. I'm curious because zeppelins were economically successful until fixed wing aircraft matured. I would assume they will be competitive again when high fuel prices start impacting the aviation industry.

Also, as an aside, the large surface area seems promising for a solar powered PV/electric motor craft.

Thanks,
Tim

All this talk about cars!!

Whether gas or electric, the car is a travesty in the 21st century. To do more mobility with less mass requires grade separation. Put the vehicles on a fixed guideway, automate them (as in automobile). Return the surface to the people, not machines.

Now, one more consideration... Energy source. As pointed out here, EVs ... for a long time ... would mean coal. Anyway, since the vehicles are on a fixed guideway, we can put solar panels on the top and conveniently match supply (sunlight) to load (mobility is mostly a daytime activity). A little storage ... Maybe an order of magnitude less than EVs would require.

The point is, ingenuity trumps oil. All this talk about the glorious high energy density of oil goes by the boards, as solar + electricity gets you where you want to go 1,000 X safer, with 50-100X less materials (because vehicles weigh less and are shared 10-20X per day.

Call it the Solar Highway.

Oh, and we can end the already real world war -- the one going on between people and their machines, with one million casualties a year worldwide (not to mention the millions injured).

Beyond oil = beyond cars.

Which motorcycle was used in these calculations?

There is a lot of difference between a roughly 40MPG BMW R1200GS and a roughly 70MPG Kawasaki KLX250. And those are not even the extremes among motorcycles without fairings. Add a fairing and another 5-10 MPG is feasible.

Additionally, what bike was used for the emissions calculations? A contemporary motorcycle with a catalytic converter (present on all road bikes in the USA AFAIK) will be roughly in line with most econocars.

`What keeps my family members and I in heavy vehicles is all of the other people in heavy vehicles, especially pickup trucks. And, there are are a lot of aggressive, bullying people driving them. A common outcome of car versus pickup collisions is that the pickup driver is uninjured and the car driver is killed or hospitalized. I figure our best insurance is to drive heavy vehicles. I imagine there are a lot of people that avoid lightweight energy efficient vehicles for the same reason I do.

If increased personal transport efficiency is to keep up with growth in demand for personal transport in Asia and total decline of FF supplies (oil for ICE and nuke/coal electric for battery) then a transport revolution has to be set into motion.

Say the number of "cars" or other personal transport units goes to two-three billion and oil/coal/nat gas goes to zero over 30 years. Realistically seen people and markets react to price or govt. incentive (or lack of subsidized fuel). So when the Chindian market for cars grows to a certain point (Current oil supply limit at any given moment) oil prices (preferred transport fuel) will go through the roof several times until people each time stop driving and then switch to dirferent more efficient transport, scrapping previous fleet. There will be a big mess and the technology companies and free markets cannot possibly keep up with all this rapid change on such a large scale if we get real declines in oil (3-5% per year decline) and then such massive growth in private car use in Chindia. Clearly Chinese govt. and similar will force high efficiency technology down companies throats periodically through mpg mandates or zero emissions mandates or forced car pooling or max car weights with taxes. Clearly technology is there but not on a massive scale needed or desired and the price mechanism decides the political/market pressure level to get things done. China is compact and could ban cars and go back to bikes if the govt. had an oil unavailability due to, e.g. US blockade (as USA needs all the oil) but USA has a serious infrastructure problem and could not do without cars so readily. Individual trapsor tis the problem and not the solution. Centralized/mixed living/business and localized supply of goods/services reduces transport needs radically obviating a soltuion to anow nonexistent problem. Tranpsort would then be by water for bulk goods or not at all. This solution is 30 years away if FFs are out of stock in 30 years.

Net energy reduction (3%/annum) x increased energy efficiency(3%/annum) x increased demand (3%/annum) will lose out more than likely as it won't be rationally planned. Hirsch report was right. We needed to change decades ago through a technocratic dictatorship. If we lose three % energy per year but equal that out by efficiency gains which are themselves killed by the jevons effect (increased demand for more efficient products) then there is no way to beat this one without breakdown. In a small closed system like e.g. Holland or Denmark where everyone just switches out their car for on a fixed schedule for a more efficient one as the local oil supply falls very gradually but everyone has a car already it would possibly work under govt. mandated system. However oil is on a price yoyo, deamnd can grow unlimited, nobody is mandating people to reduce usage, a perfect linear increase in efficiency through tech./rational business decisons to replace lost oil supplies cannot be assured, etc.

A car and a house far away with need to always get away and be somewhere else is just an ego trip. Walkable towns and cities are better. Bikes, trams perhaps best solutions until we get back to foot and horse transport and a smaller population globally over time.

How does your oil consumption compare to the average oil consumption in your state? http://www.statemaster.com/red/graph/ene_pet_con_percap-energy-oil-consu...