Showing posts with label Zenn. Show all posts
Showing posts with label Zenn. Show all posts

Monday, July 20, 2009

EEStor Article

This is an excellent article on the EEStor program to produce an ultra capacitor battery. It is easy to read and work through the issues which have been difficult to unearth to date.

I would like to make a couple of comments. The core working component is a sphere coated with a thin layer of aluminum. It could not be any simpler. Their contribution has been to size down to nanometer scale. That way they are able to approach physical limits of charge concentration while also maximizing available surface area. So far so good.

Rather importantly, third party participants can observe demonstrations of the characteristics of the spheres even one at a time. That makes a convincing proof of concept long before anyone sees real product.

Further work as reported on permeability confirms issues from scaling attempts.

Before you attempt a battery, you must prove the sphere element itself. It is unimaginable that this has not been successfully accomplished.

The second issue revolves around actual fabrication of a device that performs as demanded. It is here that I am at least hesitant. I will be until I see a proof of concept battery performing as expected. They believe they have a protocol that will do the job. My own expectation is not quite so optimistic but I do expect to soon see a working device short on performance. That is not a bad thing

After that, it is all about perfecting the manufacturing process.

When the first flat screens came out, the manufacturing cost was a few hundred dollars each. The problem was three out of four did not work at all so they had to be sold in the thousands. I expect as big a problem with this technology initially.

And yes, at this time too little is been said about safety itself. It may have a natural dampening feature, but that would be simply lucky. More likely it produces an expanding cloud of explosive vaporized aluminum. In any case this is still R&D and we have a lot of time for crash tests.


Who Killed the Electric Gas Tank?

Posted by
JoulesBurn on July 15, 2009 - 11:09am
Topic:
Alternative energy
Tags: eestor, electric car, ultracapacitor [list all tags]

A few months from now, or perhaps 5-10 years from now, we will know whether or not EEStor can make good on its promise to sell a electrical storage device capable of propelling a reasonably-sized automobile down a freeway for a couple hundred miles before needing a recharge. There are some indications that they are making progress and that this could happen, but there are many reasons to remain skeptical. In this post, I will wade into these waters -- and then get out quickly. Will EEStor revolutionize motor transportation and more? Will it even work?

The human quest for energy is an interesting topic. Mostly by burning things, we have transformed our relationship with the planet and each other. It has been said that we are addicted to oil, but it is more the case that we are addicted to what harnessed energy can do. As it is learned that some utilization of energy is not sustainable for environmental reasons, or for lack of supply, the natural response is to search for other ways of doing the same activity but with another energy supply. And conventional economics promises us that something will come along.

In modern times, one of our sacred rights (or rites?) is the ability to drive a 1-2 ton vehicle up to a fuel station, fill it up without spending a fortune or more than a few minutes of time, and then drive around at 70 miles per hour without worrying about needing more fuel for awhile. A car with a battery and an electric motor, for whatever reason, didn't bring us to this present state of mind. But take away the gasoline (or diesel), and the dream lives on -- even better, because maybe we can skip the trip to the gas station and refuel the car at home. Zenn Motor Company makes and sells electric cars, and they are clearly
appealing to those with this dream:

Imagine a car that was whisper quiet at highway speeds, could go for hundreds of miles and left no trail of emissions behind. This car would never need to visit a gas station, and would top off its ‘tank’ within a few minutes.

The car is electric…and it’s powered by a revolutionary energy storage system: EEStor’s EESU (Electrical Energy Storage Unit). To put this into perspective, imagine a car that enabled guilt-free driving, eliminated dependency on foreign oil and that completely changed transportation as we know it.
Ah yes, "guilt-free driving". I won't get into that right now.

What is the EEStor EESU?

The aforementioned EESU is essentially a capacitor which is designed to be charged up and then slowly drained to power an electric vehicle, similar to a battery or fuel cell. In the simple model below, an external voltage is applied across two conducting plates separated by a small distance, usually with a dielectric or insulator in the gap. Charge flows until the voltage across the plates equals the applied voltage.

http://www.theoildrum.com/files/capacitor.gif

Figure 1. Charging a capacitor

The charge that is dislocated per volt applied is termed the capacitance. With the external voltage is removed, the charge remains. Place an external load across the plates, and current will flow through the load (providing power), with the voltage available decaying with time.

http://www.theoildrum.com/files/capacitor_def.gif


The energy stored by the capacitor is thus a function of the specifics of the capacitor and the voltage to which is is charged. Typical capacitors found in electronics store very little charge (or energy) compared to what is needed to power devices (not to mention cars) in continuous operation. There would seem to be two options a) find new capacitor technology with a higher capacitance, or b) ramp up the voltage. At first glance, it would seem logical to take the latter route, as the energy stored increases with the square of the voltage. As we will see, it hasn't work out that way in practice up to the present. Most research and development has focused on new materials.

Before continuing, it might be helpful to highlight a few terms used to characterize capacitance:

Capacitance Terms

dielectric: another term for an insulator, which emphasizes the fact that it polarizes in response to an external electric field (as when placed between the plates of a capacitor connected to a voltage source)
permittivity: a measure of how much a dielectric can be polarized (i.e. how it responds to an electric field)
dielectric constant: the permittivity of a material divided by that of free space (therefore, dimensionless)
The capacitance is determined by the geometry of the two plates, the distance between them, and the electrical properties (permittivity) of the gap material. For large plates relative to the separation distance, the following approximation can be used:

http://www.theoildrum.com/files/capacitance.gif

To make capacitors with large values of C, the most common approach is to (dramatically) increase the area. One way to do this is to employ porous materials with intrinsically large surface areas. The term
ultracapacitor is usually used to characterize such devices which are designed to store a lot of charge. One common type of ultracapacitor, electrochemical double layer capacitors, utilize high surface area materials and also the charge-storage properties of the interfacial region between the surface and an electrolyte in solution. An internet search will reveal a wealth of information about recent developments in ultracapacitors.

Why the Fuss About EEStor?

What has raised much cash and many eyebrows are the stated specifications for the EESU:

52.22 kW-h of energy storage, or 188 MJ
Weight of 281.56 lbs, or 127.71 kg

31,351 capacitors stacked and connected up in parallel, each with dielectric layers of 9.732 micron thickness

Each capacitor layer consists of alumina-coated composition-modified barium titanate (BaTiO3) powder sandwiched between two thin poly(ethelene terepthalate) layers and aluminum electrodes. The BaTiO3 has relative permittivity (dielectric constant) of 21,072 and the overall dielectric permittivity (including PET layers and alumina coating) is 18,543.

Total capacitance of 30.693 Farads, and total volume of 2.628 cubic feet.

Temperature stable to 85°C and voltage stable to 5000 V, with 0.1% discharge over 30 days
One million recharge cycles from 0-3500 volts and back again
Can be charged in 3-6 minutes
Manufactured by screen printing and sintering

The above information was obtained from the
patent which was granted to EEStor, Inc. in December, 2008 (EEStor has applied for more). The key material, alumina-coated composition-modified barium titanate powder, is made in a process described in a patent application by the same inventors. The modified powder is then mixed with about 6% PET and binder and suspended in nitrocellulose resin and solvent for use as a screen printing ink. The surrounding PET and aluminum layers are also formed via screen printing. Put the layers down in succession, baking in between until golden brown. Let cool and then serve.

One thing that catches one's attention is the excessive number of significant digits in the figures. What is apparently the case is that the configuration of the overall EESU is designed to match the energy storage density used by the battery in the Tesla. Measured capacitance values for a proof-of-concept unit (100 layers) were then used to determine the overall requirements for the full unit. The values for energy storage, volume, and weight translate to energy densities of 1.47 MJ/kg and 2.52 MJ/liter, a 2-3 fold improvement over lithium batteries, but still wanting when compared to gasoline (~45 MJ/kg and 33 MJ/liter). (Note that, because an internal combustion engine is much less efficient than an electric motor, the comparable values will be perhaps 20% of these figures.)

As of now, there is a lot of scattered information including this patent and previous filings as well as some apparent verification of some aspects of the manufacturing and materials by supposedly independent experts. There is also some investors and some negotiated agreements with partners, most prominently
Zenn cars (see the news item bar on the home page), and Lockheed Martin. A lot of initial reaction is detailed in an issue of MIT Technology Review from January 2007. Reactions by everyone else run the gamut from giddy true belief to skepticism to accusations of fraud. For some interesting reading, check out the following discussions:

The EEStory.com, with occasionally heated discussions and some poetry

Wikipedia
entry for EEStor and a talk page with lots of angst

A
timeline detailing the play-by-play.

Sort of a game of "choose your F word" (fact, feasible, fantasy, fallacy, fiction, fraud, ...). But unlike other controversies that get batted about endlessly, this one would seem to have a clear endpoint: either EEStor can make it or they can't. Of course, a negative result might take awhile, as exemplified by the example of cold fusion research twenty years from the initial media splash. In that case, the dream that abundant energy can be obtained quite easily has kept research alive, despite the absence of either clear evidence or a plausible physical explanation. In contrast, some ideas that "should" work take awhile to become reality because of engineering difficulties. Conventional fusion-based electricity generation and high-temperature superconductors probably fall into this category. Which is the case with the EEStor capacitor?

The Road Less Taken

The principle material used in the EESU, barium titanate, has been of interest for along time. If you have access to the bound set of the Feynman's Lecture Series (1963), you will find it discussed in depth in Volume 2, Chapter 11. Barium titanate is a common material for both capacitors and actuators (a related application where an applied voltage deforms a material, allowing precise movement of objects).
This article provides a good background on the utility of barium titanate as a dielectric in capacitors in general and in multilayer capacitors in particular. EEStor's improvement over what is currently available is an increase in the voltage to which the capacitor (or a stacked set of capacitors) can be charged to. Thus, though the target capacitance of 30 farads listed above is not particularly high in the world of ultracapacitors, by assuming a large voltage, the energy that can be stored goes up considerably (with the square of the voltage). What is the downside, and why doesn't everybody just design for a higher voltage? First, high voltages (3500 volts) in many situations would not be practical. Second, the capacitor has to withstand the voltage applied (i.e. not break down). But there is one more problem: the simple formula for energy stored in a capacitor assumes that the permittivity of the dielectric is constant. In practical application, there exists the phenomenon of dielectric saturation.

Getting Saturated

A material with a high permittivity means that it distorts in response to an external electric field. This can be just a displacement of the electrons with respect to the nuclei, or it can include relative displacements of the nuclei. In the case of electrochemical double layer capacitors, it also includes relative positions of ions and solvent near the surfaces. Perovskite oxides (which includes barium titanates) have high permittivities because they can, in effect, store a lot of energy by distorting when an electric field is applied. But there are limits to the amount of distortion possible; with increases in voltage above a certain point, permittivity begins to decrease, with large changes in voltage moving less and less charge. Companies have spent a lot of money trying to develop capacitors which do not have this limit, but without success. (See
http://bariumtitanate.blogspot.com/2009/04/intelligibility-of-eestors-re...)

Skeptics have
politely mentioned this "feature" of dielectrics in discussions for awhile now, but EEStor and Zenn have recently put out PR which says that independent permittivity tests on EEStor's barium titanate powders have shown that they support their claims. Their patent clearly suggests that dielectric saturation is not observed for their samples. Much of the recent debate is thus about whether this is really plausible, based on a review about is known about BaTiO3 from prior research or first-principles calculations. One unabashed enthusiast (I'll call him "true believer", or TB) has reported that (according to Zenn and/or EEstor) their materials are in a particular phase (paraelectric) which does not exhibit dielectric saturation at these voltages. However, there is a paper published which indicates that dielectric saturation does indeed occur in the paraelectric (cubic) phase. Meanwhile, TB from above has contacted the independent tester and found that the voltage used in the test was 1 volt, but that measurements were made at multiple temperatures and there was no observed temperature dependence to the permittivity. And according to a source of TB, temperature dielectric saturation always accompanies the voltage kind. Maybe they perhaps have some phase that hasn't been seen before. Even more interesting is TB's blog post with interview snippets with other researchers in the field. This snippet is from a discussion with Dr. Eric Cross of Penn State:

B: So your view is EEStor is possibly on to something but the information they have released is not a good body of evidence from which to draw any conclusions.

EC: I would go along with that yes. I think they have something interesting and they may not know that they have a tiger by the tail.

B: Meaning that the complexity may lie ahead for what they are working on?

EC: I think that's true. One needs to understand in detail what one is doing. This is an area of extreme interest at the moment. I can't say more about it.

B: It's of extreme interest just because of the applications, right? Not because there's some sort of breakthrough? I do not understand.

EC: I think these people are scientists and I think they have made an interesting discovery but their explanations of what they have discovered are not reasonable...which is not to say that what they have discovered is not itself reasonable. That I won’t say any more about it.

A Peaceful Queasy Feeling

As I have looked into what is known about the EEStor technology, and read as much as I could stand, I have gone back and forth as to whether I believe they have indeed created a dielectric material which has the necessary properties to make the EESU function as promised. It's hard for me not to root for these guys, as there is something noble about someone striving for 20 years to bring one's ideas to fruition. The problem is that, while creative ideas and persistent attention to detail in engineering can solve almost any problem, you are sometimes stuck with what nature hands you. That they came up with a secret recipe which has eluded so many others sure seems very unlikely -- but not impossible. Will it work? Ask me tomorrow.

At this point, the only people who really know what their technology is and whether they have something that can really be brought to market soon is EEStor (and they probably don't either). Everybody else (including Zenn, until they get one in hand) is relying on partial information. But if EEStor succeeds, it will be an amazing scientific and engineering achievement by a couple of people with limited resources.
Seem Warm To You?

But what if it works? Before it can be used in automobiles, many other questions remain -- although many of these apply to electric cars in general. Where will the electricity for this really come from in the next few years? Charging infrastructure? Safety? Assorted colors?

Some of these I will reserve for another article. But I will consider here the issue of safety, which is given scant mention in the EEStor patent.

None of the EESU materials used to fabricate the EESU, which are aluminum, aluminum oxide, copper, composition-modified barium titanate powder, silver-filled epoxy, and poly(ethylene terephthalate) plastic will explode when being recharged or impacted.

The inherent danger is not necessarily the risk of explosion, but simply the sudden release of 52 kilowatt-hours of energy if the capacitor self-discharges. As shown in this illustration from the patent,

http://www.theoildrum.com/files/eestor.gif

the individual energy storage units (capacitors) are connected in parallel such that, at full charge, a potential of 3.5 kV sits across each of the 31,351 units of 10 microns thickness. Although the dielectric breakdown voltage is sufficiently high such that leakage current is low, there is a finite probability that a stress fracture from impact due to an accident or a manufacturing defect propogated as the EESU ages results in electrical breakdown in one of the units. If this occurs, all of the energy stored in the EESU (52 kilowatt-hours) could potentially be released in a very short period. It is somewhat disingenuous to stress the large amount of energy which can be stored in the device and the rapidity of charging and discharging without acknowledging the downside of these.

In a rapid electrical breakdown of the device, the stored energy would essentially result in the instantaneous generation of a vast amount of heat. For example, the EESU is made primarily of barium titanate, which has a
heat capacity of 434 J/kg-K. The 52 kW-hr released will heat the 280 lb unit to about 3400°C. Of course, it would probably start heating up everything around it before it got that hot. One ton of steel (with about the same value for heat capacity) would heat up to 460°C. Best to get out fast.

There are
possibly ways to deal with this risk, but preferably not the Ford Pinto strategy. In any case, an extensive testing phase is warranted to assess both damage and age-related risk for a catastrophic self-discharge event. Crash-test dummies are cheaper than lawyers.
Disclaimer: I own no stock whatsoever

Tuesday, February 10, 2009

EEStor's Promise

We have reported extensively on the EEStor ultra capacitor battery here, but also have made no particular note of the scope that the technology holds for improvement. The technology relies on producing a matrix of small spheres of active material coated with aluminum and held together in an active binder. The fine details, we do not know and they are not at this point our business.

But we can say something. They targeted a particle size able to provide sufficient energy density to store enough energy to drive a light electric vehicle a distance of 300 kms.

This implies that any improvement in particle size will improve energy density by the cube of the magnitude of its improvement.

It appears reasonable that a first generation improvement could well produce a device that is superior by a factor of ten through one thousand. This is a huge upside. It also suggests that the potential for the technology is almost unlimited, or at least until we hit the real bounds of the particle protocol. They may have started at the technical limits although none of us believe that.

A thousand-fold improvement, which I suspect is feasible, is a revolution in energy storage.

The point is that improvement is merely an improvement in particle size. That is a rather believable research target. The rest is surely troublesome but likely very achievable.

So we all have a lot riding on EEStor’s energy storage technology.

A next generation overcomes the current issue of vehicle weight, just as the first generation overcomes the issue of vehicle range. I must imagine that a third generation will overcome the issue of power for long haul trucking and heavy equipment.

No other energy storage technology holds this promise. It would be nice to have information on what the theoretical limits actually are. You can be sure that we will eventually test them.

Monday, January 5, 2009

EEStor from Ecogeek

This short simple item from Ecogeek will help make the EEStor concept a little easier, although it says nothing about the real issues.

I notice commentators whining about the litany of missed delivery dates as if this actually casts doubt on what they are attempting. This is very extreme product development and very difficult. It they were actually meeting so called deadlines, I would be expecting a sham. Most folks cannot change a tire on time and on budget and this is a hundred times more problematic where you are creating a micron sized particle, that is coated no less and then using it to fabricate an electron absorbing layer of these powders and plastic binder.

It is the type of thing that is likely a bitch to do as a one off in a custom rig, whereas a piece of cake in a very expensive production line. Imagine a plasma screen done as a one off! You would be lucky to get proof of concept.

We are still been told very little how this works but we are certainly told what they can do and it is clearly important.

http://www.ecogeek.org/images/image/eestorpatent.jpg


EEStor Gets Patent on Breakthough Mystery Device

Written by Hank Green
Friday, 26 December 2008

Personally, I'm very excited that lithium ion batteries are finally getting advanced enough to find homes in automobiles. But a small company called EEStor is promising "Electronic Storage Units" that will be ten times lighter, hold ten times more power, and cost half as much as lithium ion batteries.

What's more, they'll be able hold enough power to drive a car for 300 miles, charge in less than five minutes (at charging stations, not at home outlets) and will be able to charge and recharge an infinite number of times.

If true, this isn't just great news for the auto industry...it's great news for consumer electronics and the power industry as well. The question is...is it true?

Well, one obstacle was overcome today, when EEStor was finally awarded a
patent (PDF) on its technology. But a patent can be awarded for technology that doesn't work or isn't viable...they do it all the time. But now, at least, EEStor will be able to control the device if it turns out to be feasible.

It also opens up the window for all of us to look in on their mysterious chemistry a bit. According to the patent the device is a sort of capacitor that actually contains 31,353 separate capacitors in parallel. These nano-capacitors are basically a ceramic powder suspended in a plastic solution, and we're not going to pretend we understand why they can soak up so many electrons.

The patent does point out that any number of these nano-capacitors can be used in parallel, depending on the needs of the application. So, yes, if they begin manufacturing these things for cars, it won't be long before they're in your laptops and cell phones as well.

But the question of feasibility remains. They're already
behind on their scheduled delivery to Zenn auto company (who currently has exclusive rights to use the storage units.) But Zenn apparently remains confident that they will have a vehicle on the roads using the technology by 2009.

I, for one, certainly hope so. But if they do, it's going to mess up a lot of
other people's plans.

Friday, December 19, 2008

EEStor Patent Released

Here is the link to the EEStor patent released December 16th or two days ago. It clarifies a great deal and demonstrates a developing practice that fits the powdered and coated barium titanite protocol. The descriptions are also detailed enough to give one confidence in the numbers they are reporting.

It appears that they have actually made this device and it is working at the levels advertised. They may even have the manufacturing process settled down enough to make a bunch and to expect some reliability. It appears robust enough to handle vibration easily.

Folks have been responding to the claim that there are over 30,000 parts, but this sounds more like 30,000 micron sized barium titanite particles. Silk screening layers of such, multiple times, is hardly onerous.

This clearly describes what one would expect as the manufacturing system. It all depends totally on the capacity of each particle to absorb and to also discharge energy. Everyone wants to see that demonstration. It the protocol works, this patent convinces me that they can deliver sooner or later. After this we will see incremental improvements that moderately improve the system over the years likely by decreasing the size of the particle and sharply increasing the particle density. Yes, it can get better.

Take your time to read the patent and I don’t mean just the abstract. There is a lot of useful detail laid out in the description of the manufacturing process. I scanned the initial summary on the history of battery development but you may find it useful.

The energy separation caused by the use of coated particles makes this device safe so long as discharge is as easily controlled. One would hate to find a molten electric wheel in your parked car.

If this technology comes through, and from reading the patent and simply accepting the work clearly indicated, it has come through, then we have a real practical and compact energy storage device to work with from now on that clearly facilitates the electric car.

Wednesday, December 10, 2008

EEStor Skepticism

The interest in the EEStor battery spurred more interest on my part. Certainly what they are doing is taking an established protocol for a working capacitor and applying thin film methods to achieve a superior product. On the face of it this will work to some degree. The question is then whether the claims made by the company are achievable over which there is a spirited debate. Assuming the company has good reason to make their claims and some comfort that it will be possible to manufacture the final product they are surely doing the right thing in taking this protocol to the extreme limit.

It needs to be done.

This is also opening the door to thin layer manufacturing, a technology begging to be perfected. I have felt that for decades. The unusual differences between different elements, compounds and geometries are hugely magnified when setting things up an atom at a time. A simple example of this is the usefulness of solid crystalline acids.

The EEStor battery is advertised as a sandwich of metal with barium titanate in between metallic conductors. They are working at minimizing the layer of barium titanate by producing a very fine powder. This is reasonable. It still feels like the beginning of a long and arduous journey rather than the downhill romp.

Imagine a materials toolkit that included layers of grapheme, and layers of metal glass easily worked with. Recall that various metal glasses have remarkable electrical-magnetic behaviors. Extracting an ultra capacitor out of that appears plausible. The difficulty is that we are slowly learning now to manipulate these materials, and they all cry for an outer space environment to achieve optimal manufacturing environments.

This is not answering the question of the plausibility of EEStor’s public claims. Yet the issues are apparent to all, and their partners would not let their names be associated with total hooy, thus we must give them the benefit of a doubt and also expect a fair share of missed time lines.

The immediate question is whether they have done enough to fabricate a working product that can give measurable results that are superior. If they can do that and talk about it then the skeptical will step back and provide ample running room.

It is surely too soon to expect spectacular power density but not too soon to expect competitive power density.
When I saw the first sample of a printed solar cell five years ago or so, its efficiency was perhaps 3%. Today they are rushing to market because they have likely hit the 10% threshold. Another decade and we will see 30% and we will all call it am over night success.

This protocol and the competing nanotube protocol replacing the metallic layers for ultra capacitors should travel the same development path.

I wonder if these manufactured layered particles are up to been suspended in molten aluminum and if that would then be an energy absorber?

These items are worth reading as they give a sense of what is taking place technically.

US 7033406 - Electrical-energy-storage unit (EESU) utilizing ceramic and integrated-circuit technologies for replacement of electrochemical batteries; Weir, et al. (April 25, 2006)

Abstract

An electrical-energy-storage unit (EESU) has as a basis material a high-permittivity composition-modified barium titanate ceramic powder. This powder is double coated with the first coating being aluminum oxide and the second coating calcium magnesium aluminosilicate glass. The components of the EESU are manufactured with the use of classical ceramic fabrication techniques which include screen printing alternating multilayers of nickel electrodes and high-permittivitiy composition-modified barium titanate powder, sintering to a closed-pore porous body, followed by hot-isostatic pressing to a void-free body. The components are configured into a multilayer array with the use of a solder-bump technique as the enabling technology so as to provide a parallel configuration of components that has the capability to store electrical energy in the range of 52 kWh. The total weight of an EESU with this range of electrical energy storage is about 336 pounds.

July 29, 2008

EEStor, Inc. has certification data from outside sources that purified aluminum oxide, in the range that EEStor, Inc. has certified, can have a voltage breakdown of 1,100 volts per micron. The target working voltage of EEStor's chemical processes is at 350 volts per micron. This provides the potential for excellent protection from voltage breakdown.

EEStor, Inc. has achieved success on one of its most critical technical milestones and that is the certification of the completeness of the powder crystallization of the constituents utilized in producing its CMBT powders. The percent of the constituents crystallized in the CMBT powders ranged from 99.57% to 100.00% with the average being 99.92%. This level of crystallization provides the path for the possibility of EEStor, Inc. providing the published energy storage for present products and major advancements in energy storage for future products.

EEStor, Inc. has certification data that indicates achieving powder particle of 1 micron and distribution along with the aluminum oxide particle coating assists EEStor, Inc. in meeting the energy storage stabilization over the temperature range of interest for key applications.

EEStor, Inc. published patent, application number 5812758, indicates the flexible matrix concept that could provide the potential of multiple technical and production advantages. One of the technical advantages indicated is assisting in providing polarization of the ultra capacitors. Polarization along with other proprietary processing steps provides the potential of a polarization saturation voltage required by EEStor, Inc. (MarketWatch; July 29, 2008)

Thursday, December 4, 2008

EEStor Ultra Capacitors

The buzz on this particular battery technology is high and is been led by the Zenn electric car promoters who are also providing cash. The details are in the Wikipedia article.

That they are finding slippage on goal posts is hardly a surprise. That anyone makes an issue of it is tiresome. And the creation of proprietary knowledge does tend to drive an over compensation on secrecy.

I seriously wish these folks would pack it in until they are invited to do a walk through in a defense factory and experience real security.

What matters is that these folks have caused something to happen at the lab level and they are now working on perfecting a manufacturing process.

The ultra capacitor battery is important and the apparent energy density is very competitive. It certainly explains Zenn’s involvement who know that it is no big trick to generate a light electric car or as I prefer to call them ‘autocarts’

Even today, the autocart has a very clear niche that we may be forced to mandate and establish in a hurry. It is going to be easier to produce fresh grid power quickly than produce new oil production in a hurry. And an ultra capacitor is a good start for automotive storage. It is naturally mobile although I cannot comment yet on weight. What is described is certainly superior to any known technology that I have seen.

One can appreciate Nanosolar’s silence until they had their tool up and running when you see the flak these guys are flying through.

The point is that they have made a big claim, have filed patents and attempting to convert their know how into a working production line. They can fail technically or for lack of money. They are progressing at what looks like a normal pace.

And recall that funding sources always ask for time lines that are unrealistic however well staffed you are as you leave the gate. In the end they accept visible progress.

http://en.wikipedia.org/wiki/EEStor

EEStor's Weir on ultracapacitor milestone

The stealthy energy storage developer's product is real and will meet specs, claimed passionate CEO Richard Weir in an exclusive interview.

Cedar Park, Texas-based ultracapacitor developer
EEStor could be a step closer to shipping its first product, announcing the certification of production milestones and the enhancement of its chemical purification processes.

The secretive startup has made bold claims for the performance of its upcoming solid-state electrical energy storage unit, yet the company has some significant partners backing its claims, including Toronto-based electric vehicle maker
Zenn Motor (TSX: ZNN), Silicon Valley's Kleiner Perkins Caufield & Byers, and Bethesda, Md.-based Lockheed Martin (NYSE: LMT), the world's No. 1 defense contractor.

Richard Weir, president and CEO of EEStor, told the Cleantech Group his company's certification announcement is significant.

"It certainly allows us to meet present specifications and major advances in energy storage in the future," he said. "It'll meet the voltage, we say that, it'll meet the polarization, saturation, we say that."
EEStor is developing an ultracapacitor which it said will be longer lasting, lighter, more powerful, and more environmentally friendly than current battery technologies.

Texas Research International, acting as an independent laboratory, certified the level of crystallization in EEStor's composition modified barium titanate, or CMBT, powders at an average of 99.92 percent. EEStor said this puts it on the path toward meeting its goals for energy storage.

The company expects its ceramic ultracapacitor, which it said uses no hazardous materials, to have a charging time of 3 to 6 minutes, with a discharge rate of only 0.02 percent over 30 days. EEStor said that compares to more than 3 hours to charge a lithium-ion battery and a discharge rate of 1 percent over 30 days.

"It's all certified," said Weir. "No bullshit in this."

EEStor's milestone comes on the same day that San Diego-based competitor
Maxwell Technologies (Nasdaq: MXWL) announced a supply deal (see Golden Dragon Bus to use Maxwell ultracapacitors).

Maxwell shipped its Boostcap ultracapacitors to Xiamen, China's Golden Dragon Bus for use in diesel-electric hybrid buses in Hangzhou.

EEStor said the enhancement of its chemical purification processes is one of its most critical technical milestones, but EEStor has yet to release the results of permittivity testing, which will trigger the next milestone payment from Zenn. The automaker said permittivity is a measurement of how much energy can be stored in a material.

In a statement today, Zenn CEO Ian Clifford said the news "bodes well for EEStor's completion of its third party verified permittivity milestone and is a very strong affirmation of our investment in and the rapid progress of our business plan."

Zenn currently makes low-speed electric vehicles, shipping its first production vehicles in October 2006, but plans to roll out a highway-speed vehicle powered by EEStor's technology in the fall of 2009 (see
Zenn gearing up for EEStor-powered car).

Zenn has already made three milestone payments to EEStor totaling $1.3 million. Another $700,000 is payable after the permittivity testing, with a final $500,000 due when EEStor ships its ultracapacitors.

Separately, Zenn also holds 3.8 percent of EEStor after investing $2.5 million in the ultracapacitor company in April 2007. After EEStor's permittivity milestone, Zenn has the option to boost its investment to a range of 6.2 to 10.5 percent.

In 2005, Kleiner Perkins invested a reported $3 million in EEStor. The percentage of Kleiner's stake has not been revealed.

"We were invested in to put in a high-volume production line. I think this says we've made some very major strides to completing that," said Weir.

"The plant is going in right now in Cedar Park as we speak. And then we'll, of course, we'll always expand from there."

Lockheed Martin announced its contract with EEStor in January, saying that it plans use the ultracapacitors for military and homeland security applications (see
Lockheed Martin to use EEStor's ultracapacitors). The defense contractor did not release the financial terms of the deal.

Weir wouldn't disclose if EEStor is working with any other companies, saying only, "Once contracts are signed, I'm sure we'll have a news release on them."

EEStor's ultracapacitors were previously set to come out in 2007, but Zenn has since said that EEStor has committed to commercialization in 2008, with EEStor's first production line to be used to supply Zenn.

When asked for an update on that schedule, Weir said, "Good things should happen in a reasonable period of time."