Hybrid News

Filed under: EV/Plug-in, Chevrolet, GM, Green Daily

Now that we’ve seen at least a blurry vision of the Chevy Volt’s exterior and a Photoshopped front end (above), how about hearing a bit more about the inside, specifically the batteries? According to GM’s master of ceremonies vice chairman, Bob Lutz, the lithium ion battery packs that are powering the Volt mules around GM’s test tracks are “performing flawlessly.”

We heard already that GM has picked a battery supplier, and this has got to be good news for either A123 systems or LG Chem/Compact Power Inc. Lutz continued: “It’s almost scary we are not seeing any problems with the batteries.”

There is one big potential flaw, though: price. Durability and longevity predictions are showing that the batteries will work as hoped, but in their cost projections, GM is expecting each and every Volt will need a new battery pack while it is under warrenty. Thanks to Dave T.

[Source: Kicking Tires]

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Original post by Sebastian Blanco

Filed under: Emerging Technologies, EV/Plug-in

Stanford University Materials Science Asst. Prof Yi Cui had developed what is claimed to provide a breakthrough in electrical energy storage. Instead of having an anode comprised of a solid mass of silicon and carbon, Cui and his research team have developed one based on a bundle of silicon nanowires. The limiting factor of traditional designs is that the as the silicon absorbs the lithium ions during charging, it swells and then contracts during discharge. Over time this causes the anode to crack, reducing the battery’s capacity. The work done by companies like Altairnano and A123 is based on the same principle of using nano-sized materials that can absorb the lithium ions and have room to expand. Cui is claiming his nanowire design can improve the battery storage capacity by a factor of ten. The photo above shows an anode before and after charging at the same magnification.

[Source: Stanford News]

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BOLD MOVES: THE FUTURE OF FORD Step behind the curtain at Ford Motor. Experience the documentary first-hand.

Original post by Sam Abuelsamid

Filed under: EV/Plug-in, Hybrid, Mitsubishi

In May 2007, Mitsubishi Motors announced that they would be collaborating with Mitsubishi Corporation and battery supplier GS Yuasa on the development of large format lithium-ion batteries for automotive applications. The three companies have now created a joint venture to pursue this work. The new company is called Lithium Energy Japan and the plan is to begin production at a volume of 200,000 units annually in 2009. The company hasn’t announced publicly what type of chemistry they are using for their batteries.

[Source: Mitsubishi Motors]

Establishment of “Lithium Energy Japan”
- GS Yuasa, MC and MMC Establish Joint Venture Company to Produce Large Lithium-ion Batteries -

December 12, 2007 - GS Yuasa Corporation (President Makoto Yoda, Head Office Minami-ku, Kyoto), Mitsubishi Corporation (President Yorihiko Kojima, Head Office Chiyoda-ku, Tokyo), and Mitsubishi Motors Corporation (President Osamu Masuko, Head Office Minato-ku, Tokyo) began collaboration last May to set up a joint venture company to manufacture large capacity and high performance lithium-ion batteries. On December 12th, 2007, “Lithium Energy Japan” was officially established.

In recent years there has been greater urgency throughout the world to deal with environmental and energy problems, such as the depletion of crude oil and other fossil fuels, and global warming brought on by increasing greenhouse gases. Much focus is being placed on the use of alternative energies and raising energy efficiency. In particular, there is a need for technologies that can convert alternative energies into power and electricity, so that these new sources of energy can ultimately replace fossil fuels, upon which we are largely dependent. As a device essential to the practical application of such technologies, the proliferation of large lithium-ion batteries is expected to greatly increase from hereon.

Commercialization of these batteries began in the mid-to-late 1990s by GS Yuasa. Their applications gradually increased, and companies began building up greater market experience and track records in related business. In order to more widely apply these batteries in automotive (including electric vehicles) and industrial fields, we will need to further upgrade their performance and quality, and manufacturing costs will also need to be greatly reduced through mass-production.

GS Yuasa possesses advanced technologies in large lithium-ion batteries and is striving to broaden their applications. Meanwhile, Mitsubishi Corporation intends to enter the battery manufacturing business and aims to create other related businesses as well. Finally, Mitsubishi Motors Corporation is working to promote greater use of electric vehicles, which is the ultimate in environmentally-friendly automobiles. Through their mutual interests, the three companies came together to invest in this new joint venture. Their intent is to apply their comprehensive strengths in vertical value chains, covering natural resources, materials, development, manufacturing, sales, and the identification of new applications, and take advantage of their powerful synergy to advance this business.

The latent potential of large lithium-ion batteries has already been demonstrated across a wide spectrum of applications. Greater proliferation of these technologies through all-purpose applications will be key to realizing a ‘new society’ - i.e. a society in which we are better capable of dealing with environmental problems. As the first step towards achieving this ‘new society’, “Lithium Energy Japan” aims to take a leading role in global industry, and steadily begin mass production of large lithium-ion batteries. Through the development, production, and sales of these batteries, the new company will demonstrate how environmental technologies can be incorporated into society and accelerate the use of these technologies as well, including electric vehicles, plug-in hybrid vehicles, and energy recycling systems.

Overview of Lithium Energy Japan
1. Corporate Name Lithium Energy Japan
2. Establishment December 12th, 2007
3. Location of Headquarters 1, Inobanba-cho, Nishinosho, Kisshoin, Minami-ku, Kyoto, Japan
4. Capital 500 million yen at establishment; to reach 4 billion yen through increased investment in April, 2008 (planned)
5. Investors GS Yuasa Power Supply Ltd. (wholly-owned subsidiary of GS Yuasa Corporation) 51%, MC 34%, MMC 15%
6. Business Development, Manufacturing & Sales of Large Lithium-ion batteries
7. Production scale 0.2 million units / fiscal year 2009
8. Executives - President
Katsuyuki Ono
Managing Director,
GS Yuasa Corporation
- Director
Teruhiro Hatanaka
General Manager, New Business Promotion Dept., Large-scale Lithium-ion Battery production Division, Industry Business Unit,
GS Yuasa Power Supply Ltd.
- Director
Masanori Kitamura
General Manager, Corporate Strategic Planning Division,
GS Yuasa Corporation
- Director
Hiroshi Imagawa
Senior Vice President, Automotive-Related Business Innovation Office, Innovation Center, Business Innovation Group,
Mitsubishi Corporation
- Director
Toshinaga Kato
General Manager, Motor Vehicle Domestic Operation Unit, Motor Vehicle Business Division, Machinery Group,
Mitsubishi Corporation
- Director
Tohru Hashimoto
Vice Corporate General Manager, Development Engineering Office and MiEV Product Executive,
Mitsubishi Motors Corporation
- Auditor
Syunsuke Kusuyama
Full-time Corporate Auditor,
GS Yuasa Corporation
- Auditor
Yoshihito Yoshizawa
Business innovation Group Controller,
Mitsubishi Corporation
9. URL http://LithiumEnergy.jp

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BOLD MOVES: THE FUTURE OF FORD Step behind the curtain at Ford Motor. Experience the documentary first-hand.

Original post by Sam Abuelsamid

Filed under: EV/Plug-in, Hybrid, Green Daily, Th!nk (Think)

At EVS23, AutoblogGreen had a chance to speak with the chairman of Ener1, Inc., Charles Gassenheimer, about his company’s batteries and the future of Enerdel’s lithium-ion batteries in automotive applications. He told us then that “We think 2008 is going to be a very exciting year for us.” Now we know one reason why.

Yesterday, Gassenheimer told Fox Business News that his company’s batteries will be on the market by the end of 2008. From what we know so far, it’s likely that Th!nk will have the first vehicles featuring an Ener1 lithium ion battery inside (see links below).

According to a press release sent out by Ener1, here are Gassenheimer’s comments to Fox:

Our batteries have already been tested by the United States Advanced Battery Consortium, which is General Motors, Ford and Chrysler. We are the only battery company today using this Lithium-ion technology, which has met or exceeded all of the Big Three’s requirements, especially and most importantly best-in-class in safety. We have already announced a commercial contract with Think Electric Vehicle in Norway. It’s the largest electric vehicle company in Europe. You will see our batteries in their cars by the end of 2008 (read the rest after the jump).

In the race to bring lithium-ion to the masses, Ener1 is not waiting around. Now, let’s see what happens when these cars are on the road, preferably with us in the driver’s seat.

Related:

• Ener1 first to integrate lithium-ion battery into HEV
• Ener1 shuffles management in preparation of battery commercialization
• Everything you ever wanted to know about Ener1’s batteries
• Ener1 and Th!nk sign the largest contract for lithium-ion batteries in automotive history

[Source: Ener1, Inc.]

Dec 12, 2007 06:00 ET

Ener1, Inc. Chairman Tells Fox Business News Company’s Lithium-ion Battery Will Be in Cars by End of ‘08

FORT LAUDERDALE, Fla., Dec. 12 /PRNewswire-FirstCall/ — Appearing Tuesday on Fox Business News, Charles Gassenheimer, chairman of Ener1, Inc. (BULLETIN BOARD: ENEI) , an alternative energy company, said that the company will bring its automotive Lithium-ion battery to market by the end of 2008.

“Our batteries have already been tested by the United States Advanced Battery Consortium, which is General Motors, Ford and Chrysler,” Mr. Gassenheimer told viewers of the Fox morning broadcast “CEO Corner.” “We are the only battery company today using this Lithium-ion technology, which has met or exceeded all of the Big Three’s requirements, especially and most importantly best-in-class in safety.”

“We have already announced a commercial contract with Think Electric Vehicle in Norway,” Gassenheimer added, referring to a $70 million development and supply agreement signed in October. “It’s the largest electric vehicle company in Europe. You will see our batteries in their cars by the end of 2008.” the Ener1 chairman told interviewer Alexis Glick.

Mr. Gassenheimer said that the size of the market for Lithium-ion power sources for electrical transportation, including hybrid, plug-in hybrid, and pure electric vehicles will burgeon in the next decade. The new technology provides consumers an immediate positive return on investment in purchasing a hybrid electric vehicle, while the nickel metal hydride batteries currently in use require a payback period of seven to ten years to cover the hybrid premium.

“This is really a supply problem,” Mr. Gassenheimer commented to Fox, adding that the few U.S. companies currently involved in manufacturing Lithium-ion automotive batteries, rather than competing directly against each other, are collectively building a new industry. He says that Japanese automaker Toyota now accounts for 90 percent of the battery market for electrical transportation and that U.S. industry must rapidly catch up or risk ceding a major share of the new car market to foreign carmakers.

The Ener1 chairman notes that energy legislation now moving through Congress that would mandate a minimum 35-mpg standard in new cars has provided strong impetus to American carmakers to adopt more fuel-efficient technologies.

“Much of the world now, including Detroit, grasps that more efficient internal combustion engines and biofuels such as ethanol will not bring about the major environmental improvements and freedom from foreign oil that the times demand,” Mr. Gassenheimer said. “That the Lithium-ion battery is the Holy Grail is now a given, and we and others have proven that it’s a fully realizable technology for revolutionizing automotive transportation.”

About Ener1, Inc.

Ener1, Inc. (BULLETIN BOARD: ENEI) is an alternative energy technology company that is developing 1) lithium ion batteries for hybrid electric vehicles (HEV) at its 80.5% owned EnerDel subsidiary through corporate ventures and strategic partnerships with Delphi, ITOCHU and EnerStruct, 2) commercial fuel cell products through its EnerFuel subsidiary, and 3) nanotechnology-based materials and manufacturing processes for batteries and other applications at its NanoEner subsidiary. For more information, visit http://www.ener1.com/ or call 954-556-4020.

Safe Harbor Statement

This release contains forward-looking statements within the meaning of the Federal Private Securities Litigation Reform Act of 1995 conveying management expectations as to the future based on plans, estimates and projections at the time the statements are made. The forward-looking statements contained in this press release involve risks and uncertainties, including, but not necessarily limited to: the Company’s ability to achieve the milestones upon which the funding from its controlling shareholder is conditioned; EnerDel’s ability to succeed as a supplier of batteries to the hybrid electric vehicle and other markets; Ener1’s ability to successfully develop and market proposed lithium battery, fuel cell and nanotechnology-based products and services; the degree of competition in the markets for lithium battery, fuel cell and nanotechnology-based products and services; Ener1’s history of operating losses; EnerFuel’s ability to complete the development of and sell the surveillance camera; the lack of operating history for the development stage Ener1 businesses; the need for additional capital; the dependency upon key personnel; and other risks detailed in filings made from time to time with the Securities and Exchange Commission. These risks and uncertainties could cause actual results or performance to differ materially from any future results or performance expressed or implied in the forward-looking statements included in this release. Ener1 undertakes no obligation to publicly update or revise any forward-looking statements, whether as a result of new information, future events, or otherwise.

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BOLD MOVES: THE FUTURE OF FORD Step behind the curtain at Ford Motor. Experience the documentary first-hand.

Original post by Sebastian Blanco

Filed under: EV/Plug-in, Hybrid, Chevrolet, GM, Saturn

Prior to the opening of the LA Auto Show this week, AutoblogGreen sat down with Denise Gray of General Motors to talk about batteries. Denise is the director of Hybrid Vehicle Energy Storage Systems and oversees all the battery development going at GM for vehicles ranging from the new Two-Mode hybrid SUVs to the Chevy Volt.

AutoblogGreen: Why don’t we get started with the current status of battery development for the E-flex program. Bob Lutz recently mentioned in an interview you have received the first pack from CPI. Where do things stand right now?

Denise Gray: Well, just to step back a little bit in the May-June timeframe, we got our contracts together, we worked with our two chosen suppliers CPI and Continental and we have been working those programs feverishly. We have come up with designs that are buildable, if you will, for our first mule build, or our first bench build that is probably the more proper name, what that design should be composed of and CPI delivered that on October 31. I was over in the lab, in fact, when they called and said, “Hey, they are here. They are at the grounds. Come on. But our security guys routed them to a different gate, so they will be here in ten more minutes.”

So it was kind of like waiting for the birth of a baby. They brought it in, they had their big truck they brought it in. We had our forklift. The guys went and got it and I said make sure you handle it very well, so it was brought in.

Check out the rest our conversation after the jump to learn about how GM determines the state of charge of a battery and the current status of the PHEV Saturn Vue.
DG: I was actually at CPI that Monday prior to the Wednesday that they delivered to also see it there and to understand how they had progressed as well, and judge its readiness to come over to our lab.

So it is in the lab, the teams, the GM and CPI team had been working collectively in the lab since that time doing our characterization, making sure that we can monitor all of the voltage and currents from each cell, making sure that as we go through our safety handling of the battery that all of the necessary things are working, because again, there’s lots of energy, lots of power. I don’t want to have anybody at risk with this first bench pack, so we were walking through with our checklist of things that we want to make sure things works with these sensors, that we have got these thermal couples. They are all working. The redundancy that we have to have in our lab to test these parts are in place and the team has actually got it on the cycler now.

The contactors are closed and we are beginning methodically and charging and checking to make sure everything is correctable. We will work through that in the next couple of weeks to a point where we feel comfortable before we will go and do deep discharges and charging up and going through different kind of systems.

ABG: Now, this first pack, is the packaging of the pack the same as what you are going to put in to the first mules, or is it more of just an open set up for bench testing?

DG: No, I think it will be capable of putting into a mule, but not completely capable. There are still going to be things that you don’t want to do if you will because it is made for the bench. There are structural things that are not completely production intent, so I don’t expect for this thing to go through a battery of Belgian blocks and heavy vibrations and that kind of thing, but I think it will be decently able to be used to go into a vehicle eventually for mule integration type test.

ABG: And when do you think that you will get the first units that you will actually put in the vehicles. When do you expect that to happen?

DG: We have got a roll out over the next couple of months with the packs coming in from CPI, some additional packs coming in from Continental. Over the next six months, there is a roll out of a pack this week and another pack that week. We are going to use this pack for this and that kind of thing, so it is really ramping up now with the first one on October 31 and over the next month or so there will be packs coming in from the different suppliers to facilitate different needs.

ABG: The first pack that you have, is that essentially complete? Does it have a cooling system and everything?

DG: The cooling system is in. We don’t have a coolant flowing through it and there are still some things that we want to check out and make sure that all of the points are very well tapped, so there are no leaks and that kind of thing so the cooling system is intact. But we don’t have coolant flowing through it yet because that is another part of the checkout and making sure those pieces are in place. We can actually operate it without the cooling system actually active at this point in time.

ABG: If it’s sitting on a bench, you could air cool it and as long as you are not cycling it too aggressively, it probably would not be a problem.

DG: So there lots of learnings, right now, even without the cooling system working.

ABG: When do you expect to get the first packs from Continental?

DG: They are scheduled sometime around the end of the year, and that date is still being defined and we are still working through the readiness of that pack for delivery.

I think the first pack was the most important and getting the hardware and so we could see what it is looking like and we can actually do our own testing to make sure that our assumptions were correct. I think this exercise that we have been undergoing over the last couple of weeks have taught us what we want the next packs to do.

It might modify the timing quite frankly based on what we are learning here. I don’t have to quickly get this in, I can let them do a little bit more finessing of the design, so my timing is going to be really a function of what else I need to learn to determine if I want them to keep it longer or to release it earlier to me, so that is kind of variable right now. It is kind of how I have got this going.

ABG: Getting a little bit more technical, one of the issues dealing with battery packs for hybrids and electric vehicles is monitoring the state of charge to maximize the life span and safety of the pack. You want to cycle it between a certain charge and discharge level, can you talk a little bit about how you estimate the state of charge of a battery pack?

DG: Actually that is done in-house. We are not asking the suppliers to provide that level of design from them. We are actually developing that in-house.

ABG: The control software?

DG: The control software as well as - all I am asking the suppliers to do is to provide me information, current, voltage, temperature. Then my scientists and we have been doing this for the past year, it is just not from the E-flex we have been having lots of learnings on nickel metal hydride where my scientists characterize the behavior of the different chemistry. We characterize and model that. We then develop an algorithm that models the battery that we can then put into our software. I am asking for information from the battery pack, current, voltage, temperature and those kind of rudimentary parameters and then my organization determines what the state of health is. What is the state of charge for that battery.

So we use that knowing how we want to use it in the vehicle so that we can provide its state of charge, state of health. The level of, the depth of discharge that we want to use it based on how we understand that chemistry and how we also want to use the overall energy in the vehicle.

So that is all done in-house.

ABG: The reason I asked, in the old days before we had nickel hydride batteries for consumer electronics with alkaline cells and things like that, as they discharge, the voltage you got from the battery would drop gradually over time. With nickel hydride batteries, in particular, the voltage tends to stay relatively constant until they are done and then it just kind of drops off, so for batteries like that, what sorts of things would you look at to determine the state of charge of the battery. Obviously, the voltage by itself is not sufficient, how would you determine the state of charge?

DG: Well, there are tests that we run outside of the normal - we call them characterization test and every chemistry, be it lithium iron phosphate or be it manganese spinnel, we characterize that chemistry when it comes to current and voltage and overall performance under hot conditions, cold conditions and just its performance through the depth of discharge kind of test, so we run a battery test in order to understand how to characterize that chemistry, and then from there, we recognize where the fall off zone is, and everybody knows, for iron phosphate for example, the curve is somewhat flat in certain areas and with manganese spinnel, it is a little bit different. It is a little bit easier.

For nickel metal hydride, it has a curve where you can understand where it is at as well, so we do a battery of tests outside of actually real-time from a vehicle perspective, so we do that outside, we get lots of samples from the suppliers. We do that characterization, samples over a wide variety of lots to make sure that we understand the variation, and we go through and model that, and that helps us to understand where that knee of that curve actually is going to occur and we make sure we stay away from that if you will so that our useful life is somewhere other than that point.

ABG: So even though the curve tends to be more flat than what you would get with an older style battery, there is still enough of the change there over time that you can measure that and see where it is going.

DG: In fact, I got an email, I was walking out to the parking lot two days ago and I ran into my engineer who is actually doing that modeling, and I said, “How is it coming with the different chemistries?” and he said, “I think I got it.” And so they have continuously trying to get more and more resolution in that curve so that we can clearly detect its state of charge, how it is going to operate in a different condition and that is being modeled and it is something that our organization has internally.

ABG: How different are the characteristics of, say, the iron phosphate batteries from A123 versus the types of cells that you are getting from CPI? What type of chemistry does LG chem use?

DG: Manganese spinnel.

ABG: So how different are those in terms of their characteristics?

DG: There are some very similar characteristics, and there are some, obviously like I mentioned that the iron phosphate is a lot more flat of a curve if you will. Those have been the only perceivable differences.

ABG: When you have got a flatter curve, like with the iron phosphate, would you do things like for example, factoring in the time? If you have charged it, factor in how long it has been running?

DG: Well, if I tell you I will have to kill you.

ABG: I guess that is a little bit too much to ask.

DG: There are many kinds of things, there are tricks that we have and there are different kinds of models to allow us to get better resolution of that to use different parameters in order to get a better feel for what that flat spot of that curve is.

ABG: Another question that you may or may not be able to give me an answer to, are the battery packs consistent enough from one to another that you can have one model and would not necessarily have to calibrate to a specific pack or would you have to calibrate each pack and get some characterization for each individual pack?

DG: No, our goal is to have a model that is chemistry dependent as opposed to pack dependent and we will go through a lot of development, a lot of sample, a lot of confirmation to try to get a good bandwidth, to catch the variation and the CPI chemistry versus the A123 chemistry. We will go through them. We will do that today. We will go through getting a big enough sample size of the chemistry and then validate if our models still applies and we will do that continuously throughout this entire development cycle and then there will be particular things that we have put in calibration that are going to be more vehicle specific if a vehicle-a configuration vehicle number one with these kind of tires versus vehicle configuration two with this different kind of tire, wants a different performance, then there will be some calibration factors that we will modify in order to get that application specific kind of characteristic, but our goal is to have the core algorithm applicable to a particular chemistry.

ABG: On a slightly parallel path, what about the Saturn Vue plug in, the two-mode plug in, how is that program coming along?

DG: It is going pretty good. It doesn’t get the big fanfare, but we actually have packs in the lab now and we have got packs of it a while ago, actually late summer time in the August time frame, we began getting bench packs, bench packs are here in Warren (Michigan), in my lab as well as packs out in Milford (Michigan, the GM Proving Ground where vehicles are tested) because we have got not just what the battery team has to do to make sure that everything works fine, but the rest of the control system and the rest of the control system happens out at Milford, so those packs have been delivered from both suppliers. Those suppliers are Johnson Controls-Saft as well as Cobasys/A123, so we have got work happening in both of those areas. We have got the same kind of modeling of the behavior of those chemistries, working through those as well and we have got some good model work happening and we have got some very good characterization that is occurring, so that one is progressing right on schedule as well as there is still a lot to learn, but yet both are progressing. So we get a lot of activity happening.

So those are running. They are cycling in the lab. They are actually in our environmental chambers, so they are a couple of months ahead of the E-flex one, but that is how our program started. That was started in January and this one started in the June time frame.

ABG: Okay. Thanks so much for talking to us today.

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BOLD MOVES: THE FUTURE OF FORD Step behind the curtain at Ford Motor. Experience the documentary first-hand.

Original post by Sam Abuelsamid

Filed under: EV/Plug-in, Hybrid

It appears Continental Automotive may be the first major company to start series production of automotive lithium ion batteries. According to an interview in German Magazine Auto Motor und Sport, Continental CEO Manfred Wennemer announced the company would start series production of automotive lithium ion battery packs in 2008. The article doesn’t say who the cell supplier is or what customer the packs are intended for.

Continental is partnering with A123 Systems as one of two supplier teams producing prototype battery packs for the Chevy Volt program. When Mercedes-Benz announced their mild hybrid system at the 2007 Frankfurt Motor Show, they stated that it would use lithium ion batteries although they didn’t say who the supplier would be. Wennemer said initial production volumes be in the thousands rather than hundreds of thousands, but they expected it to grow quickly.

[Source: Auto Motor und Sport]

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BOLD MOVES: THE FUTURE OF FORD Step behind the curtain at Ford Motor. Experience the documentary first-hand.

Original post by Sam Abuelsamid

Filed under: EV/Plug-in, GM, AutoblogGreen Q & A, AutoblogGreen Exclusive

At the Consumer Electronics Show in Las Vegas this week we were able to catch up again with Denise Grey, the Director of Energy Storage Systems for General Motors for another update on battery developments on the E-Flex program. As always, Denise filled us in as much as possible on what’s happening without giving away too many secrets.

ABG: Denise, let’s start off talking about the batteries for the E-Flex program. You’ve now received two battery packs from CPI. What’s the current status of testing on those packs?

Denise Gray: They’re currently being tested in my lab. We’re working through a number of different tasks found. US06, Milford, grade test as if you’re out here in Colorado or somewhere in the mountains. We’re running through those different tests to stress the battery to confirm our assumptions on if it will going to give us power and energy that we need. Confirm the range. Can we actually go 40 miles with the combination of the different schedules and so far so good.

Keep reading after the jump to learn about the thermal performance, the Conti/A123 packs and more.

Denise Gray: The data is looking pretty good that were in that same window of the simulation that we did. The actual test on an actual battery pack in a lab is showing very closely correlated to the data that we have from the simulation perspective.

ABG: How are the power and the energy output of the batteries looking?

Denise Gray: Things are looking good. We’re not on our final design yet. We are learning and, quite frankly, we really had to make some calls. Do you wait until the perfect battery is done? That gives you everything you need and then do testing or you take iteration 1, iteration 2, and you kind of keep inching your way to the final design. We chose to take the iterations because there is so much learning at the beginning. The power and energy is confirmed to what they have said, I would get with this iteration, yes. But we are not done to our ultimate goal of our overall power, energy, manufacturability, cold temperature performance yet.

ABG: There was a story that came out recently from an unnamed internal source on a site that shall also be nameless for the moment. It claimed that the CPI batteries were nowhere close to what was required as far as performance. Can you comment on that?

Denise Gray: No, they are per what we thought they were going to be for this particular iteration. We wanted to get it on the bench. So it is more biased toward power than the total energy, that is total energy under all different circumstances but we are giving the energy that we need under the various task conditions that we are currently have. So, I think that was bogus. It’s giving us what we think we’re going to get at this first design iteration.

ABG: How is the thermal performance of the batteries looking so far?

Denise Gray: So far so good and, ironically, in this first iteration of the design we actually ran it the without thermal system and quite frankly the temperature rise over the battery, a test that is part of what we run went under. It was very small, a couple of degrees of temperature rise. So, quite frankly, it is very surprising that it actually performed that well without any kind of thermal management system.

ABG: What about cold performance? Obviously, people who live in Northern climates would have concerns about driving a car like the Volt or any EV, because batteries tended to degrade in performance at cold temperatures. How is the CPI pack looking go so far?

Denise Gray: So far so good, although we have had our last design iteration when it comes to cold temperature. The trade off between power-energy, cold temperature and manufacturability. We’re still working through from a design iteration perspective that particular trade off, that three-legged stool trade off. We do suspect in our subsequent deliveries from CPI that we will get even closer to that ultimate goal of having that right trade off between those three parameters.

ABG: Do you have a target that you can share with us as far, what would be acceptable in terms of cold temperature degradation at minus 20, minus 30, and minus 40?

Denise Gray: We are not done yet. That story is not complete at this point, because quite frankly, we’ve got the optimization of the battery from a power-energy in cold temperature but you also have the optimization within the vehicle environment itself. And, quite frankly we are trying to get as much as we can get out of the battery and then once we understand what that limitation is and try to meld that into the vehicle trade off, because sometimes the vehicles can mask any kind of trade off you make with the batteries. So, that story is not complete at this point in time.

ABG: What about the high temperature performance, the 110-120 degrees in place like this we’re in Las Vegas right now. In the summertime it gets pretty warm here. How do you expect the battery to perform in those conditions?

Denise Gray: Again, that trade off will come with the high temperature as well, because quite frankly we’ll have more of a range with lithium than we had with nickel. But yet there still will be a temperature trade off that we’ll probably won’t want to operate over a certain temperature so that we can make sure that we meet a life expectancy of the overall battery. So, we are not done with that aspect, so we’ve still got a lot of work to do.

ABG: Recently, I toured the E-flex Design Studio in Warren [Michigan] with Bob Boniface. And there was a lot of discussion about the aerodynamics of the Volt. They found that even at lower speeds, at city speeds, aerodynamics had much more effect on the range of the vehicle than mass. They could increase the mass a little bit with bigger battery or just heavier components, and have a less of an impact than the aerodynamics. Presumably, that is because by not burning off kinetic energy through aerodynamic drag; you can recapture that as regenerative braking. Do these lithium batteries allow you to capture energy faster and recapture more of the kinetic energy than you would be able to do nickel battery on the hybrids that we have today?

Denise Gray: From the performance yes, we have not really exploited how much difference though, quite frankly. I think our overall E-Flex strategy is going to take the battery usage and the capturing of the kinetic energy and restoring it from a capacity perspective. We will have more capacity period in the lithium than we had in the nickel. So that by itself we’ve got more capacity from a storage perspective. But, we have not, quite frankly, taken a deep dive into how much and when and how and then how does that turn into overall speed, but that does go in to that overall vehicular optimization, so a lot of work should be done in that area.

ABG: I think one of the limitations with the hybrid we have today with nickel batteries is the rate, with which the battery itself can absorb energy. I think at least with the A123 batteries, I’m not as familiar with the characteristics of the LG Chem batteries, but the A123 batteries are able to absorb energy at a higher rate if necessary. So, I was wondering if that will allow you to go beyond the point 0.3-0.35g of decel that you can get with regen. Maybe bump that up to 0.5g of regen decel.

Denise Gray: Definitely, this is one of the things that we are going to be looking at.

ABG: Getting into the A123 batteries, the Conti/A123 packs, you’ve yet to receive your first one there. What is the current status of that?

Denise Gray: January timeframe. Yes, that activity is happening over in Berlin. So obviously, the A123 and the Conti guys are working very closely. And I’m confident they will come through with a really good design. I think they have taken a little longer to get there. But, I think once they get there, once we get that first battery and I think we will be quite pleased with the progress that they made so far.

ABG: A123 showed the new cell design that they have developed at the EVS23 Show in Anaheim in late November or early December. It’s a prismatic cell now, rectangular cell as opposed to the cylindrical cells that they typically use in the most of their previous applications. Have you been able to test that cell yet, how does that compare, and what was the rationale for going to the rectangular flats cells as opposed to a round cell?

Denise Gray: A couple of activities here. One is from a chemistry perspective. We have tested the chemistry regardless of what the packaging is and they’re is still on their iterations as well. But so far so good as far as our energy and power that we need based on what they are today. As far as the overall format, the format offers additional flexibility when it comes to packaging. We’ve got lots of battery, lots of power and energy required and more prismatic gives you a little bit more packaging capability than the cylindrical cells themselves. As well as cooling there is more easier attained surface area to be able to deal with the cooling aspect of it as well. So, it offers some different flexibility opportunities.

ABG: And Jon Laukner mentioned the other day that the first mule vehicles have been built up and they are just waiting for packs to be installed. What kind of time frame are you looking at to actually move those packs from the bench into those vehicles?

Denise Gray: As soon as possible. I mean, you cannot get there fast enough but probably realistically it be the first quarter of this year. So, over the next month or so, I anticipate the packs moving from our laboratory to Milford to do check out from an integration perspective and then ultimately, into the vehicle for vehicular evaluations. So, first quarter of this year, I am sure we will have opportunity where we’ve got that activity going.

ABG: Is there anything else you want to share about what is going on?

Denise Gray: Yes, we are running this fast as possible. We got a number of different swim lanes all in parallel, from the cell, the battery pack itself, from electronics to the thermal, to manufacturing. How we are going to manufacture these things at high quantities with reliability and robustness and then we got all of the vehicle work happening, the vehicle control work is happening as well. So, there is a lot going on in order to be able to pull this off.

ABG: That control work is probably one of the biggest aspects of the whole project developing the electronics and software infrastructure to let all these various subsystems communicate and work together to optimize the range and performance and durability of the packs.

Denise Gray Yes, it is a huge effort, because you got to think this vehicle is going to operate differently than the previous vehicles, a non-EV, a non-extended range kind of vehicle. You think about the typical customer comes in, he starts up as he puts his key in, he turns the ignition, the engine starts up, and things get triggered off that sequence of how the traditional vehicle operates. And, so now with this vehicle things will be different and we’re still defining that difference so that we can really optimize the overall electrification of the vehicle. So you’ve got to twist your mind around a different kind of operating strategy. Your power molding is different now and that will really be a huge task.

ABG: All right, well thank you very much.

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BOLD MOVES: THE FUTURE OF FORD Step behind the curtain at Ford Motor. Experience the documentary first-hand.

Original post by Sam Abuelsamid

Filed under: EV/Plug-in, Hybrid

Johnson Controls and Saft have a partnership to produce lithium ion batteries for automotive applications. Among other projects they are one of the two suppliers chosen for GM’s Saturn Vue plug-in hybrid program. Saft has also provided lithium ion battery packs for concept vehicles such as the Chevy Sequel and Ford HySeries drive Edge. The two companies are opening a new plant in Nersac, France to manufacture lithium batteries for a variety of car-makers including Mercedes-Benz, Chrysler and General Motors. The €15million plant has an initial capacity of 5,000 packs a year and will be able to scale up as demand increases. It is believed to be the first plant to be dedicated to automotive lithium ion batteries.

[Source: Financial Times]

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BOLD MOVES: THE FUTURE OF FORD Step behind the curtain at Ford Motor. Experience the documentary first-hand.

Original post by Sam Abuelsamid

Filed under: EV/Plug-in

If you’ve had a hankering for a full battery electric version of a MINI, PT Cruiser, Smart ForTwo or Toyota Yaris, the price tag just got a little more manageable. Lost Wages-based Hybrid Technologies has been doing EV conversions for a while now and apparently the cost of their lithium ion batteries has come down significantly so they are passing on the savings to the customer. Of course, this is no way meant to imply that any of their cars are inexpensive or affordable to the average consumer. The lineup now starts with an electrified Yaris at a mere $39,500. The battery-powered PT Cruiser has been slashed by $10,000 to a slightly less ridiculous $55,000. The MINI Cooper tops out the lineup at $57,500. If those price tags have not dissuaded you, you can check out the company and even place your order at the company’s website.

[Source: Hybrid Technologies, thanks to Nick for the tip]

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BOLD MOVES: THE FUTURE OF FORD Step behind the curtain at Ford Motor. Experience the documentary first-hand.

Original post by Sam Abuelsamid

Filed under: EV/Plug-in, Tesla Motors

One of the enduring issues related to battery-powered cars is what becomes of those massive batteries when they reach end of life? As one of the first companies to utllize large-scale lithium ion batteries, Tesla is addressing this problem even before they start series production. In the latest entry on the company blog, Kurt Kelly talks about the battery recycling plan including a description of the pack’s construction. The 6,831 individual cells are spread among 11 modules, each of which can be individually replaced if their capacity to hold a charge drops too low. Once modules or packs are declared no longer useful, Tesla has a recycling plan set up with KBI/Toxco. Tesla will ship expended modules to Toxco for dismantling and reuse, recycling. Kelly gives a full rundown of the process.

[Source: Tesla Motors]

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Original post by Sam Abuelsamid

Filed under: Emerging Technologies, EV/Plug-in, Hybrid, AutoblogGreen Q & A, AutoblogGreen Exclusive

The other day, Dr. Prabhakar Patil of Compact Power, Inc. was up in Vancouver, BC for the Auto FutureTech Summit. While AutoblogGreen wasn’t able to attend the show, we did get a hold of Dr. Patil on the phone for about 15 minutes to talk about CPI’s lithium ion batteries and get Dr. Patil’s perspective on what the future holds for electric drive cars. As many readers probably know, CPI is one of the companies delivering batteries to GM for the Chevy Volt, so Dr. Patil is in the center of the lithium ion world. CPI is also working with other automakers (details are still secret, unfortunately).

You can listen to Dr. Patil using the audio widget below and we’ll have a transcript of the discussion pasted after the jump later today.

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Original post by Sebastian Blanco

Filed under: Etc., Asia

The recent Tibetan independence demonstrations and the Chinese response have, in this Olympic year, turned the eyes of the world towards the “roof of the world.” There have been some who have called for the boycott of the Olympic games and Chinese products as a result of the harshness of the “crackdown”. Our own president has even gotten involved and has asked the Chinese Premier, Hu-Jintao, to hold talks between the the Dali Lama’s representatives and the Chinese government, though I suspect even the suggestion of such a rapproachment wasn’t warmly received.

What does any of this have to do with more-environmentally-sensitive transportation? Well, I came across this article recently that informed me that the source of much of the lithium in the batteries that power our laptops, cell phones and soon, our hybrid and electric cars, is mined at the Chabyer Salt Lake in the Tibetan Autonomous Region. This is the largest source of known lithium reserves in the world, according to the China-Tibet Information Center, and it has helped China become the largest producer and user of lithium ion batteries. Yes, we mine a lot of lithium here in the U.S. but that is used mostly for a host of other products.

In the process of mulling all this over during the past week I have read about the history of Tibet and its entanglements with other countries and contemplated the stances of the various “sides” involved. I haven’t reached anything approaching a firm conclusion but the process has been a beneficial learning experience.

In the end, I can only offer this information as an example of how our actions in this modern, tightly-connected world might affect people living in distant lands and how “treading lightly” might prevent that boomerang of karma from sneaking up behind us.

[Source: Green Energy News]

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Original post by Domenick Yoney

Filed under: EV/Plug-in, Hybrid

In an attempt to keep our readers up to date on the very latest developments in technology as it pertains to transportation and the lessening of our carbon footprints, we often burn the midnight oil and labor to understand technical papers until our brains cramp and ears bleed. OK, maybe I’m the only one with the ear thing but what I’m trying to get across is that we are not slackers (Not that there is anything wrong with that.) And it is in that spirit of brain-crampedness (and sore ears) we present you now with some of the latest news of breakthroughs
in the batteries that may one day power your hybrid or electric car.

We all know that our modern batteries do their thing (charge and discharge) by sending lithium ions back and forth between the anode (where the current comes in) and cathode (where the current goes out). This action is what eventually degrades your electrodes (anodes and cathodes). By improving the materials that bear this beating, scientists aim to increase the amount of energy batteries hold as well as the number of times you can recharge them. Hear about a couple of these efforts after the break.

Tin is one of the materials thought to hold promise as an electrode because it theoretically should hold onto a lot of energy. Unfortunately, it breaks down easily from the passing of the lithium ions. Scientists at the Institute of Chemistry at the Chinese Academy of Sciences think they may have come up with a clever way around this by enclosing nano-sized bits of tin inside elastic hollow carbon spheres, as you can see in the photograph above. The way they accomplish this trick is a little complicated but here is a link to an article in Nanowerk that explains it all in painstaking detail. The result of all this nano-manipulation is an anode with a high specific energy capacity and good cycling performance. To top it all off the researchers believe “their results successfully demonstrate the power of the strategy of using elastic hollow carbon spheres as buffer and container and could be extended to other anode and cathode materials.” Exciting stuff.

The other news comes to us from this article in Technology Review about work being carried out at the Argonne National Laboratory. The over-achieving scientists there have made safety improvements, increased the power density and number of charge cycles lithium ion batteries with cobalt oxide electrodes can perform. Not only that, but they have already licensed the technology to a major materials supplier, Toda Kogyo of Japan. Their improvements were achieved by creating a new composite electrode with the cobalt oxide and an electrochemically inactive material. Although this should enable the battery to hold up to 30 percent more energy, the article claims that it is not able to discharge at rates high enough to make it useful for high- power applications such as hybrid and electric cars. Not yet anyway, so the work there continues.

[Source: Nanowerk / Technology Review]

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Original post by Domenick Yoney

Filed under: Emerging Technologies, EV/Plug-in, Hybrid, Japan

The automotive li-ion battery world got a little cozier today, with the news that Continental has purchased a 16 percent stake in the Japanese “battery specialist” (Automotive News Europe’s words) Enax. ANE says that the two companies will together develop “high storage batteries for automotive use.” The company’s official announcement on the new partnership says those batteries will be “lithium-ion cells especially for future hybrid and electric drives in automobiles” that will be safer, have a longer service life and provide better performance than today’s li-ion batteries.

Based in Tokyo, Enax was founded twelve years ago and is an independent think tank that has been working on li-ion automotive batteries for over ten years. The company has over 80 employees and had sales of $10.5m U.S. in 2006. Conti also works with A123 Systems on batteries for the Chevy Volt and with Controls-Saft Advanced Power Solutions.

[Source: Automotive News Europe (subs req’d)]

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Original post by Sebastian Blanco

Filed under: Emerging Technologies, EV/Plug-in, Hybrid

The company called Air Products, which deals in atmospheric gases and related matters, announced last week that it was awarded two patents (#7,311,993 and #7,348,103, and both called “Polyfluorinated Boron Cluster Anions for Lithium Electrolytes) for lithium-ion batteries. The patents involve Air Products’ fluorinated electrolyte salts called Stabilife, which the company claimed in a statement “have been formulated to stand up to the difficult conditions expected from next generation portable power applications as well as hybrid electric vehicles” when used in li-ion batteries. Stabilife apparently boosts the lithium electrolytes and an Air Products VP said the patents mean Air Products will play a role in developing materials for next-gen hybrid vehicles. We can only assume the PHEVs will be affected as well. Chemistry fans will want to read the press release after the jump for details on the “poly- fluorinated borane cluster anions” and more.

Press Release:

Air Products Awarded Two Key Patents for Lithium Ion Batteries

Stabilife(TM) Salts Provide Better Performance Under Adverse Conditions

LEHIGH VALLEY, Pa., June 17 /PRNewswire-FirstCall/ — Air Products (NYSE:APD) today announced it has received two United States patents covering usage of its Stabilife(TM) fluorinated electrolyte salts in lithium ion batteries. These salts have been formulated to stand up to the difficult conditions expected from next generation portable power applications as well as hybrid electric vehicles (HEV).

United States patents 7,311,993 and 7,348,103, both entitled “Polyfluorinated Boron Cluster Anions for Lithium Electrolytes,” protect improvements in lithium electrolytes used in lithium ion batteries.

“These patents will help Air Products develop the materials for next generation HEVs,” said Wayne Mitchell, vice president and general manager of Performance Materials for Air Products. “They are testament to the enabling characteristics of fluorinated materials for lithium ion batteries, as well as our company’s 30 years of experience working with fluorine compounds.”

Air Products’ Stabilife Salts are electrolyte salts based on the poly- fluorinated borane cluster anions, [B12FxH12-x]2. Stabilife salts have exhibited extraordinary thermal and hydrolytic stability that can allow for the use of safer, lower cost electrode materials, such as LiMn2O4 and LiFePO4, in large format lithium ion batteries. They also have expanded the operating temperature window of lithium ion batteries versus currently employed lithium electrolyte salts.

In addition, Stabilife Salts’ unique electrochemistry enables them to provide inherent overcharge protection to lithium ion batteries through redox shuttle chemistry. They are produced at a pilot plant housed within Air Products’ fluorine-based chemicals plant in Hometown, Pa.

More information on Stabilife Salts can be found at www.airproducts.com/stabilife .

Air Products (NYSE:APD) serves customers in industrial, energy, technology and healthcare markets worldwide with a unique portfolio of atmospheric gases, process and specialty gases, performance materials, and equipment and services. Founded in 1940, Air Products has built leading positions in key growth markets such as semiconductor materials, refinery hydrogen, home healthcare services, natural gas liquefaction, and advanced coatings and adhesives. The company is recognized for its innovative culture, operational excellence and commitment to safety and the environment. Air Products has annual revenues of $10 billion, operations in over 40 countries, and 22,000 employees around the globe. For more information, visit www.airproducts.com .

***NOTE: This release may contain forward-looking statements. Actual results could vary materially, due to changes in current expectations.

[Source: Air Products]

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Original post by Sebastian Blanco