DuPont Recruits 500 Farmers for Non-Food Biofuel Project
Next year DuPont plans to complete one of the first and biggest commercial-scale cellulosic biorefineries in the world, which will make biofuel from corn stalks and leaves at this Nevada, Iowa construction site. (Source: DuPont)
Biobutanol sounds like a good alternative to Ethanol and Gasoline. E85b, which replaces the gasoline component with biobutanol seems like a good first step. Also, producing biobutanol from glycerol could leverage existing biodiesel production and turn one byproduct into a useful fuel. More development is needed, but it sounds promising. I look forward to reading your article.
Dave, I'm well aware of fuel mix needs. That wasn't my point: my point is that to be hamstrung by regulations alone, as your comment implied, is absurd. My other point is that we could learn from what goes on in other countries in the world, if we weren't quite so xenophobic. (Ironic, considering how most of us come from somewhere else.) And redesigning fuel systems to deal with ethanol can be done. It's also possible, as we've covered several times, to make biofuel that doesn't require any engine redesign.
@Ann: Unfortunately, it's not just a matter of revising regulations. Most cars (and trucks, and motorcycles, and snowbobiles, and lawnmowers, and outboard engines...) don't run well on gasoline that contains more than 10% ethanol. There are also problems with material compatability: steel and aluminum components corrode, rubber o-rings shrink, etc.
Redesigning fuel systems to accomodate gasoline with an ever-increasing ethanol content is a challenge, although it can be done. (Obviously there are vehicles already out there that can run on E85). But then there's the question about what to do about all of the vehicles that are already on the road.
Biobutanol is one possible alternative; it can be blended up to 16% with gasoline, compared to 10% for ethanol. It also has some other advantages over ethanol. I'm hoping to finish an article about this in the near future.
I couldn't agree less on the idea of producing less biofuel. That would be extremely shortsighted and shooting ourselves in the foot. Instead, we should revise the regulations. The EU and other countries/regions have similar regulations, they also went through an economic dive, and they might serve as models for what to do, if the legislators in this country can't figure it out themselves.
Something that's being ignored here is that the 2007 Clean Energy Act mandates the useage of minimum annual volumes of biofuels. That is, the U.S. must consume, by law, a certain amount (currently somewhere around 15 billion gallons) of biofuels per year. The mandated amount is set to increase every year until 2022.
On the other hand, regular gasoline containing more than 10% ethanol by volume can't be sold in most of the U.S. (and most automotive OEMs would like to keep it that way, because higher quantities of ethanol can wreck havoc on fuel system components).
What this means is that we'd better be using at least ten times as much gasoline per year as the mandated amount of ethanol -- otherwise we can't meet the requirement while still keeping the total below 10%. This is called the "blend wall."
Unfortunately, the amount of gasoline consumed is determined by the state of the economy, which (as you might have noticed) took something of a dive soon after the 2007 law was passed. The biofuel mandates were never revised to take this into account.
I don't know the exact numbers, but I think we are extremely close to hitting the "blend wall," if we haven't hit it already. So producing more biofuels right now seems like an extremely bad idea, even if they are being produced from non-food feedstocks.
Any use of non-food product to make fuel can really only be a net benefit to the US. Local farmers in my state of Virginia do have trouble is discarading the remnants from a corn harvest. Often times these items end up discarded in the field and turned back in which is not always good for the soil.
I'm referring to "Thermodynamics of the Corn-Ethanol Biofuel Cycle" by Tad W. Patzek. I do not have the data to say one way ethanol is thermodynamically profitable or not. I only point out that Mr. Patzek states in his paper that various data were from the '80s and '90s. He also chose a point in time, 1973, to base his production costs for nitrogen fertilizer even though based on his numbers those processes have become much more efficient later. In 1973 the energy requirements were 47 MJ/Kg compared to 34 MJ/Kg in 1991 where the data ended. Based on the trend we might see significantly lower energy requirements by 2012.
According to Mr. Patzek, we should stop growing corn for food or fuel. How we grew corn 30+ years ago isn't sustainable.
Thank you for your response to the paper in question. I was not aware that some of the data were old. Are you saying that these deficiencies are enough to flip the energy balance so corn ethanol is thermodynamically profitable? That the sum of fossil fuel imputs ends up less than the enthalpy value od the alcohol product?
Just for the record, my number for the efficiency of PV was just 15% in order to allow for the deficiencies you named. Is that still too "good" to be realistic, especially when compared to the ~1% for photosynthesis (which also suffers from coludy days)?
Having worked in the remewable energy industry I sympathize with your friends who have had lousy results with small wind turbines. Unfortunately not all renewable energy products are built to the best reliability standards.
Thanks for the response. I read the paper you mentioned. Unfortunately, Mr. Patzek's paper uses 20 to 30 year old estimated data. He also assumes that various chemicals are used, which may not be the case. Also, modern farming methods significantly reduce both soil erosion and the need for some herbicides as well has cutting fuel costs by reducing the number of passes needed to farm the fields. He quotes corn subsities paid to 10% of farmers, which he states were not made public. It would be difficult to check that information. In short, his paper seems a bit biased in my opinion.
Current PV technology is capable of reaching 40% efficiency, however that is under ideal conditions and optimal light exposure as well as using stacked PVs. Dual-axis tracking mechanisms help a lot, but rainy/cloudy days are still a problem. Two people I know have adopted wind/solar power for their homes. They use geothermal heating as well. Unfortunately, their wind generators require constant repairs. Even with solar power to supplement their wind power they have only achieved 34% and 21% of what their respective systems were designed to produce. Maintenance costs have negated any cost savings from producing their own electricity. Maybe someday small wind and solar will make sense, but we're not there yet, so we're at the mercy of the utility companies for now.
It's good to hear from someone on the scientific side of this, j-allen! Viability arguments for and against the crop-based production of fuel aside--I think all the debate over this is exactly why it's good a reputable company like DuPont--with a long history of manufacturing a wide range of products--is taking the lead on this.
Instead of sifting through huge amounts of technical data looking for answers to assembly problems, engineers can now benefit from 3M's new initiative -- 3M Assembly Solutions. The company has organized its wealth of adhesive and tape solutions into six typical application areas, making it easier to find the best products to solve their real-world assembly and bonding problems.
Many of the materials in this slideshow are resins or elastomers, plus reinforced materials, styrenics, and PLA masterbatches. Applications range from automotive and aerospace to industrial, consumer electronics and wearables, consumer goods, medical and healthcare, as well as sporting goods, and materials for protecting food and beverages.
Engineers trying to keep track of the ever-ballooning number of materials and machines for additive manufacturing and 3D printing now have some relief: a free searchable database with more than 350 machines and 450 different materials.
At JEC Europe Dow Automotive introduced a new ultra-fast, under-60-second molding cycle time for its commercial-grade VORAFORCE 5300 epoxy resin matrix for carbon composites. It's aimed at high-volume automotive manufacturing.
Focus on Fundamentals consists of 45-minute on-line classes that cover a host of technologies. You learn without leaving the comfort of your desk. All classes are taught by subject-matter experts and all are archived. So if you can't attend live, attend at your convenience.