vanteckvrb.com says: The statements regarding Squirrel and Cellenium are somewhat misleading. Whilst it may be true that they own cell stacks, the critical element is the Vanadium pentoxide electrolyte; this technology as well as the world licensing rights are owned by Pinnacle VRB.
Good info on current development:
http://www.pinnaclevrb.com.au/second.html
These people hold the rights to the VRB-battery
Related: The
Pinnacle Mining Vanadium Battery deal
Also INTERESTING:
Search
the web for Vanadium Redox Battery there could be something new!
Please view THE OFFICIAL VANADIUM BATTERY WEB-PAGES
Vanadium
Mining ... Swedish
experiments
Comparision between Lead-Acid, VRB and Flywheel energy
storeage:
http://www.telepower.com.au/PVwork98.PDF
Local VANADIUM BATTERY PHOTOS (much faster page than http://www.ceic.unsw.edu.au/centers/vrb/ )
INFO ON OTHER BATTERIES and good info on Electirc Cars: http://www.avere.org/working/en/traction.html
I too have compiled information, it is right here and here and here and here
Here some more links and scraps of
infromation ...
The
Vanadium battery in australian electric people-mover-vehicles !!
A picture of the
JAPANESE 200kWh VB is NOW OFFLINE: http://www.sumiden.co.jp/RandD/field/ener/English/redox.html
if you can read japanese, please tell me what they say here
DEAD LINKs
Interesting comments from the
greedy (Vanadium-) mining people are here
... here ... here
... here ... here
and here
DEAD LINK Hwang,
G. and Ohya, H. -- membrane researchers
DEAD LINK this
german guy knows about the vanadium battery technology, but the only
reference to it is on this page...on the bottom ... in german. He is talking
about how useless other battery technologies really are, and doesn´t expand on
the vanadium battery..(BORING, but here for completeness)
More items from the scrap book...
Liquid electricity pumped
as the fuel of the future
By RICHARD MACEY
Revolutionary technology
allowing electricity to be stored in a
liquid may be on the market
within 18 months following a deal signed last week between the University of NSW
and a former mining company.
The technology may
eventually allow electric cars to be refuelled at future versions of today's
petrol stations, doing away with the need to routinely replace bulky batteries
or
spend hours recharging them
from power mains.
The vanadium redox battery is
the result of 15 years' research by Professor Maria Skyllas-Kazacos, of the
university's School of Chemical Engineering and Industry Chemistry.
Dr Malcolm Jacques, the
managing director of Pinnacle, a Melbourne-based company which has bought the
patents to commercialise the technology, said the batteries would be far more
efficient and reliable than conventional lead-acid batteries.
The new battery stores power
in tanks of vanadium sulphate dissolved insulphuric acid. Found in Western
Australia, vanadium is a metal used to make stainless steel.
Dr Jacques explained that when
a vanadium battery runs down, the owner merely has to drain the discharged
liquid and refill the tank.
"You can think of
electric cars, forklifts and airport tugs," he said.
"Once you run out of
electricity, you would pull into a filling station and pump in fresh
liquid."
The initial demand would be to
power farms, Aboriginal communities, mines and remote equipment such as
communications relay stations, with the batteries storing electricity
produced by wind or solar
generators.
"They would displace
diesel generators, which would be good news for environment."
Dr Jacques said vanadium
batteries could abolish the need for building expensive power stations that have
to be big enough to meet a town's needs for a few peak hours every day but are
then turned down as demand declines.
Dr Jacques hoped the first
vanadium batteries for use in remote regions would be available in 18 months.
They would be dearer to buy than lead-acid versions but, with no corrosion, they
would last longer.
They would be cheaper over
their life cycle, lasting five to seven years. With lead-acid you would be lucky
to get two years," he said.
Dr Jacques said the
batteries could become a major export earner for Australia, with a world market
for industrial batteries "in the order of $10 billion a year".
JOURNAL OF THE ELECTROCHEMICAL SOCIETY
Volume 143, Number 4
April 1996
ELECTROCHEMICAL SOCIETY LETTERS
L86Thermal Stability of Concentrated V(V)
Electrolytes in the Vanadium Redox Cell M.
Skyllas-Kazacos,
C. Menictas, M. Kazacos
----
from: http://www.che.utexas.edu/nams/jms_Nov.html
(no text though, just the title..)
Preparation of sulfonated composite
membrane for vanadium redox flow battery
applications, pp. 35-45
T. Mohammadi, M. Skyllas-Kozacos*
School of Chemical Engineering, The
University of New South Wales, Sydney, 2052, Australia
-------------
http://www.solarex.com/ PV solar
with inbuild inverter!
From owner-EV@SJSUVM1.SJSU.EDU Sun
Jan 28 13:18:47 1996
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Date: Sun, 28
Jan 1996 02:00:08 -0800
Sender: Electric Vehicle Discussion List
Reply-To: Electric Vehicle Discussion
List
From: Automatic digest processor
Subject: EV Digest - 26 Jan 1996
to 27 Jan 1996
To: Recipients of EV digests
Subject: Vanadium Redox Battery
[The following article was extracted from Energy Focus - 1995]
The vanadium redox flow battery was
developed by Professor Maria
Skylass-Kazacos and her team at the
University of New South Wales, Australia.
It is a low cost, low environmental
impact battery that has a superior deep
cycling life and can be mechanically
refuelled in minutes.
Today's lead acid batteries, commonly
used to start cars, store energy in
solid electrodes while the vanadium
redox battery stores energy in a liquid
electrolyte solution of vanadium
pentoxide dissolved in sulphuric acid.
The electrolyte can be charged or
discharged by pumping it through the
battery
stack and either supplying electric
power to the stack or taking power from
the stack. It can also be
recharged by having the spent electrolyte pumped
out and a fresh charge of electrolyte
pumped in.
The spent electrolyte can then be
recharged in another battery with
electricity
from the mains or from renewable energy
sources.
This raises the opportunity for the
establishment of refuelling stations so
that electric vehicles could exchange
their electrolyte and then continue on
their way with no more delay than if
refuelling with petrol or diesel.
The vanadium redox flow battery
technology is protected under a number of
patents and further patent applications
are in progress.
To date, two commercial licenses have
been granted by Unisearch Ltd for the
commercialisation of the vanadium redox
battery in stationary energy storage
applications. One is the Thai
Gypsum Products Public Company.
A consortium comprised of Mitsubishi
Petrochemicals and Kashima Kita Power
Corporation of Japan plans to construct
and test a 300 kW vanadium battery
system by 1996 and commission a 2,000 kW
demonstration load levelling system
in the Tokyo area by 1999.
An energy density of 80 to 100 Wh/kg
could be achieved in the next 5 years,
which will allow the battery to power
electric vehicles. Recent tests on
a golf buggy in Australia have proved to
be most encouraging so far.
For further information please
contact Wal Lamberth of Unisearch Ltd, the
commercial arm of the University of New
South Wales, Australia.
Phone +61 02 9385 5401
+++++++++++++++++++++++++++++++++++++++++++++++++++++
Dallas Stott (Dallas_Stott@eol.ieaust.org.au)
Integrated Energy Management Centre
PO Box 349 Moonah Tasmania 7009
Australia
Phone +61 02 716429 Fax +61 02
733420
Daihatsu Charade, 1200kg, 14 x 6V, 1221B
Curtis, Made in Australia
"Leaders in Energy Management
Services for a Better Environment"
+++++++++++++++++++++++++++++++++++++++++++++++++++++
The telephone number of UNISEARCH the marketing people for the Vanadium Battery is +61 2 3855401 (Wal Lamberth w.lamberth@unsw.edu.au)
Here another list of literature, compiled by Alan T.
The current status of development of advanced battery electric energy storage systems in Japan HIRAMATSU,T., KONDO,S., NAKAYAMA, T., OHTAKA,E., TAKAHASHI,S. Proc. Electrochem.Soc.88-11(1988) 1-8 Zinc-redox battery, a technology update HOLLANDSWORTH,R.P. Proc. Electrochem.Soc.88-11(1988) 224-240 Development of a redox flow battery SHIMIZU,M., MORI,N., KUNO,M., MIZUNAMI,K., SHIGEMATSU,T. Proc. Electrochem.Soc.88-11(1988) 249-256 Research and development of a 10kW class redox flow battery YOSHITAKE,M., TAKABATAKE,M., HAMAMOTO,O., HIRAMATU,T., KONDO,S. Proc. Electrochem.Soc.88-11(1988) 266-273 Flow batteries, present status and research areas MCBREEN,J. Proc. Electrochem.Soc.88-11(1988) 280-292 Investigation of the aqueous Fe-Cr redox flow cell. SHIMADA,M., TSUZUKI,Y., IIZUKA,Y., INOUE,M. Chem. & Ind., (1Feb88) 77-82 Catalytic electrodes for the redox flow cell energy storage device. YANG,C.Y. J.App.Electrochem., 12(1982)425-434 Chemical and electrochemical behaviour of the Cr(III)/Cr(II) half-cell in the iron-chromium redox energy storage system. JOHNSON,D.A., REID,M.A., J.Electrochem.Soc. 132(5)(May1985)1058-1062 Carbon fiber electrode for redox flow battery. INOUE,M., TSUZUKI,Y., IZUKA,Y., SHIMADA,M., J.Electrochem.Soc. 134(3)(Mar1987)756-757 Efficient vanadium redox flow cell. SKYLLAS-KAZACOS,M., GROSSMITH,F., J.Electrochem.Soc. 134(12)(Dec1987)2950-2953 New all-vanadium redox flow cell. SKYLLAS-KAZACOS,M., RYCHCIK,M., ROBINS,R.G., FANE,A.G., J.Electrochem.Soc. 133(5)(May1986)1057-1058
and for completeness sake here is Norbert's stuff again
The
Vanadium Battery Yes!
The Vanadium
Battery2
The Vanadium
Battery3
The Vanadium
Battery4
The Vanadium
Battery5 this page here
http://www3.electrochem.org/letters/Mar99/lett98-08-009.pdf
Evaluation of Precipitation Inhibitors for Supersaturated Vanadyl Electrolytes for the Vanadium Redox Battery While the saturation solubility of vanadyl sulfate in 3 M H 2 SO 4 is less than 2 M/ L at 10 C, 4 M supersaturated vanadyl sulfate solutions could readily be prepared. The vanadium redox battery, pioneered at the University of New South Wales (UNSW), 1- 5 has now reached the demonstration stage for solar energy storage and load- leveling applications. The energy density of the vanadi-um redox battery is determined by the concentration of vanadium ions in the electrolyte, this being a function of the saturation solu-bility of the different oxidation states that are formed during charg-ing and discharging in the positive and negative half- cell solutions. To increase the energy density above 25 Wh/ kg therefore, precipitation inhibitors were considered to stabilize supersaturated vanadium electrolytes for the vanadium battery. Potassium sulfate, on the other hand, is likely to act by forming stable potassium compounds with some fraction of the vanadium sulfate solution species, thus reducing the degree of supersaturation and stabilizing the solution against precip-itation. In the case of urea addition, similar results were obtained as for SHMP. The rate of precipitation of the vanadyl sulfate decreased with increasing urea content up to 5 wt % at which point no precip-itation was observed within the 90 day observation period. Effect of K 2 SO 4 addition on the precipitation rate of 4 M vanadyl sulfate in 3 M H 2 SO 4 at 4 C. Table I. Induction time (in days) for start of precipitation of VOSO 4 from supersaturated V( IV) solution at 4 C for various additives.
Keywords: adsorbing, density, Battery, function, Power, VOSO,
Electrochemical, acidic vanadyl solution, vanadium sulfate solution,
Supersaturated Vanadyl Electrolytes, stable supersaturated vanadyl, stabilize
supersaturated vanadium, vanadyl sulfate solutions, supe
Summary:
New and emerging energy storage technologies such as the vanadium redox battery and high- speed flywheel are considered as possible alternative energy storage systems in PV applications. PV systems are now used in a range of powering applications. These range from simple water pumping and remote gate control on farms, to highway traffic flow metering and railway control signaling, to remote- area homestead powering, to powering critical telecommunications networks, through to village lighting and power. Energy storage is a fundamental and critical part of any practical PV system, and involves the storage of excess PV- generated energy in a form suitable for use during periods of when the solar input is insufficient to support load demands. Traditionally, the lead- acid battery has been the technology of choice in PV- systems. This is primarily due to the comparative technical simplicity and the substantial capital cost advantage of the lead- acid battery over other possible energy storage technologies. However, the performance of the lead- acid battery compared to other components of contemporary PV- systems is varied, and on a life cycle basis, the lead- acid battery becomes a significant element of total system costs. Two new and emerging energy storage technologies currently under development - the vanadium redox battery (VRB) and the high-speed flywheel - are also considered as emerging practical alternatives to the lead- acid battery in many PV applications.
Keywords: alternative, Devices, batteries, applications, associated, Australia, flywheel, support, Ltd, acid, VRLA battery technology, lead acid battery, acid battery varies, electrodes battery plates, acid battery technology, life VRLA battery, acid battery cost,
http://www.wiley-vch.de/contents/jc_2018/1998/1401_a.pdf
Summary: Illenberger: Thermodynamics of Vanadium Redox Flow Batteries 1401 Thermodynamics of Vanadium Redox Flow Batteries - Electrochemical and Calorimetric Investigations 14, D- 18051 Rostock, Germany Key Words: Electrochemistry / Redox Flow Batteries / Solutions / Thermodynamics Thermodynamic properties of the so- called All- Vanadium battery used as energy storage system and other va-nadium redox systems related to the All- Vanadium battery have been studied. No direct calorimetric measurements of the molar reaction enthalpy of the All- Vanadium battery reaction is possible, but the sum of the molar reaction enthalpies of the two dispro-portion reactions gives the molar reaction enthalpy of the All- Vanadium battery reaction. Redox flow batteries provide energy storage systems which have sufficient capacity and flexibility in order to guarantee a continuous availability of electrical energy. 2 Schematics of the electrochemical test cell EC= electrochemical cell, G= graphite plates, M= membrane, R= liquid reservoirs, P= liquid pumps, C= optical cell (cuvette), GF= optical glass fibers, UV-VIS= UV- VIS spectrometer and in the catholyte: VO 2 2H e , V 3 H2O . 3 The molar reaction Gibbs enthalpy DGi , the molar reaction entropy DSi and the molar reaction enthalpy DHi can be deter-mined from the cell voltages DEi 0 and their temperature 30) -226.0 0.5 kJ mol -1 DHII =DHIV -DHI -172.0 kJ mol -1 DHII =DHI +DHIII -170.5 kJ mol -1 DHII = 1 Illenberger: Thermodynamics of Vanadium Redox Flow Batteries 1409 Table 2 Electrochemical, calorimetric and derived thermodynamic properties of vanadium redox reactions at 298.15 K
http://www.sae.org/products/papers/1999-01-2616.htm
SAE Technical Papers Document Number: 1999-01-2616
Title: Development of Vanadium Redox Flow Battery System Meeting Where
Presented: Intersociety Energy Conversion Engineering Conference, August 1999,
Vancouver, BC, CANAD, Session: Storage Systems Author(s): Takeo S. Saitoh -
Tohoku University Akira Hoshi - Tohoku University
http://www.hookele.com/mt/forum/messages/552.html
POsted by: mailto:daniel@maui.net
NEW AUSTRALIAN INVENTION MAKES BATTERY STORAGE FOR ALTERNATIVE ENERGY SYSTEMS LONG-LIVED, RELIABLE AND NON POLLUTING.
Come learn more about this breakthrough.
We are inviting people who have shown a business and community interest in
creating renewable energy systems on Maui to a meeting at the Maui Electric
building, 210 W. Kamehameha Ave., Kahului, on Monday, June 14 from 5 to 6:30 PM.
Representatives from the County and Maui Electric will also attend.
A general manager from Kashima-Kita Electric Power Corporation and Mitsubishi
Chemical Corporation will be on Maui to make a presentation about a new, better
kind of battery system (invented by a woman professor at the University of New
South Wales in Australia).
This battery could be very important in practical storage of wind and
photovoltaic energy, even to store diesel generated power to help meet peak
utility needs. It also seems ideal for emergency back up power systems that must
replace failed utility power for hospitals, police, etc.
Here are more details: The Vanadium Redox Battery appears to represent a major step forward in power storage: lower cost, relatively non-toxic, very long life (renewable), high storage capacity and ability to deliver power at high density. More info is available at: http://www.ceic.unsw.edu.au/centers/vrb/ and http://www.pinnaclevrb.com.au/second.html
I have been writing to the inventor, and received this reply:
>Dear Daniel,
> Thank you for the information - your application looks ideal for the
>vanadium battery and it would be a great thing for the environment if you
>could avoid burning diesel fuel for your electricity needs. I will pass on
>this email to Pinnacle, but also to Kashima-Kita Electric Power Corporation
>(subsidiary of Mitsubishi Chemical Corp) in Japan who are the licensees of
>the technology for Solar Energy storage in the USA. They have already
>installed a 200 kw/ 800 kWh load-leveling demonstration battery in Japan
>and are looking for an opportunity to build a larger unit. They also have a
>video showing their 800 kWh demononstration battery.
Professor Maria Skyllas-Kazacos
School of Chemical Engineering &
Industrial Chemistry,
University of New South Wales,
Sydney, 2052, AUSTRALIA
Phone: 61-2-9385-4335
Fax : 61-2-9385-5966
Website address:
http://www.ceic.unsw.edu.au/staff/Maria_Skyllas-Kazacos/Skyllas.htm
and the representative from Japan has also written:
>I am with Kashima-Kita Electric Power Corporation and
>also Mitsubishi Chemical Corporation and both companies have been
>developing the vanadium battery technology since 10 years ago and are
>entitled to develop and commercialize the vanadium battery business under
>the exclusive license of Pinnacle VRB, the technology successor of the
>University of New South Wales. Moreover, I am responsible for the planning
>and commercialization of the battery.
>
>In the meantime, I will happen to visit the States in the beginning of
>June. So, I can visit with you at Honolulu or Maui in the morning on June
>14, Monday or June 15, Tuesday on my way back to Japan, if it is acceptable
>to you. If you are interested in meeting me, please let me know your
>convenience by return.
>
>Best Regards,
>
>Akira Shibata, General Manager, V Battery Division,
> Kashima-Kita Electric Power Corporation
> and also, General Manager, R&D Coordination Department
> Mitsubishi Chemical Corporation
> Address ; 5-2, Marunouchi 2-chome, Chiyoda-ku, Tokyo 100-0005
> Japan
> Phone ; +81-3-3283-5833
> Fax ; +81-3-3283-5809
> E-mail ; ENG3199@cc.me.m-kagaku.co.jp
http://www.pc.chemie.tu-darmstadt.de/bunsen/abstracts/E9944.html
Berichte der Bunsen-Gesellschaft: Paper E 9944
Key Words: Electrochemistry / Redox Flow Batteries / Solutions / Thermodynamics
Thermodynamic properties of the so-called All-Vanadium battery used as energy storage system and other vanadium redox systems related to the All-Vanadium battery have been studied. An electrochemical cell has been constructed to measure the equilibrium cell voltages as function of the degree of charging in the temperature range from 278 K to 323 K. The first system studied is the disproportion reaction of VO2+ ions with the two half cell reactions VO2+ + H2O <=> VO2+ + 2 H+ + e- and VO2+ + 2 H+ + e- <=> V3+ + H2O. The second system is the All-Vanadium battery reaction with the two half cell reactions VO2+ + H2O <=> VO2+ + 2 H+ + e- and V3+ + e- <=> V2+. The third system is the disproportion reaction of V3+ ions with the half cell reactions V3+ + H2O <=> VO2+ + 2 H+ + e- and V3+ + e- <=> V2+. The molar reaction Gibbs energy, the molar reaction enthalpy, and the molar reaction entropy of each system has been obtained from these data. Additionally the molar reaction enthalpy of the two disproportion reactions and of the reaction V2+ + 2 VO2+ + 2 H+ <=> 3 VO2+ + H2O has been measured directly by titration calorimetry. The results agree with those obtained from the electrochemical data for the disproportion reactions. No direct calorimetric measurements of the molar reaction enthalpy of the All-Vanadium battery reaction is possible, but the sum of the molar reaction enthalpies of the two disproportion reactions gives the molar reaction enthalpy of the All-Vanadium battery reaction. Comparison with the electrochemically determined molar reaction enthalpy of the All-Vanadium battery reaction shows good agreement indicating satisfying thermodynamic consistency of the whole procedure.
Ber. Bunsenges. Phys. Chem. 102, 1401 (1998)
Content: Herbert Anton, bunsen@pc.chemie.tu-darmstadt.dehttp://www.federationgroup.com.au
Tel: +61+3+96541100 Fax: +61+3+96542388
Vanteck (VRB) Technology Corp 1650-999
West Hastings Street Vancouver, BC, Canada V6C 2W2 Tel:
1-800-773-7317
CAPITAL STRUCTURE Trading Symbol: CDNX : VRB Shares
outstanding: 26 million Insider Holdings: 13 million Estimated
Float: 13 million
52-Week High/Low: $2.25/0.75 Controlling Shareholder: Federation
Group Ltd (13m shares)
ENERGY STORAGE FOR UTILITIES & INDUSTRY The world’s solution to
Utility “BROWN-OUTS”
CORPORATE PROFILE
Vanteck Technology Corp. (CDNX: "VRB" / NASD Electronic Pink Sheets:
"VTTCF"), based in Vancouver, BC, Canada, is now the largest
shareholder in Pinnacle VRB Limited the company that owns the Intellectual
Property rights to the Vanadium Redox Battery (“VRB”). The VRB is an energy
storage technology, which has the potential to efficiently deliver commercial,
operational and environmental benefits for the world's electricity industry.
Originally conceived by NASA and later patented by the University of New South
Wales, Australia, the VRB is an energy storage technology that allows
electricity to be stored via rechargeable fuel cells using redox flow
technology. Unlike other Fuel cells, the VRB operates at room temperature and
operates at efficiencies of approximately 80%.
Electricity is difficult to store on a large scale. As a result, electricity
supply systems are built and operated so that production matches peak demand. By
using the VRB, it is possible to store large amounts of power during the low
demand periods and have enough power to supply back into the grid during the
peak periods without an increase in power production, thereby reducing costs,
brown-outs and improving efficiency.
The technology has been proven and tested in the Japanese market and is now
poised to spread to other parts of the world.
THE TECHNOLOGY
The VRB is most suited to stationary applications at the Generation,
Transmission, Distribution and end user levels. The VRB exhibits attractive
technical performance characteristics and cost competitiveness compared to other
conventional lead-acid and nickel-cadmium battery technologies typically used in
these applications.
Operational advantages of the VRB are:
· It has no life degradation from deep discharge and recharge
· Environmentally friendly
· Can operate with one or more electrical inputs and outputs at multiple
voltage levels.
· It can be charged and discharged simultaneously.
· The VRB storage capacity is scalable and flexible.
· No chemical degradation due to corrosion.
· Energy storage is accurately measured using a direct electrical reading (fuel
gauge).
· Provides power independent of the energy storage capacity.
· It is not limited by packaging constraints.
· Remains undamaged by fluctuating power demands.
To view a complete Power Point presentation, please link to: http://www4.tpg.com.au/users/joesmith/vrb.ppt
STRATEGIC ALLIANCES AND PARTNERSHIPS
Vanteck, through its African VRB business, has an alliance with Highveld Steel
and Vanadium Corporation of South Africa for vanadium supply and vanadium
electrolyte manufacturing. Highveld is a significant producer of vanadium and is
working with Vanteck on the electrolyte for its South African 250kw VRB
demonstration unit.
Vanteck’s other alliance partner in Africa is TSI-Eskom the South African
national power utility and the fifth (5th) largest power utility in the world.
INDUSTRY OVERVIEW
The problems experienced in the USA, as highlighted by the Californian power
crisis over the past few months, can to a large extent be assisted by the
adoption of a viable energy storage to provide, among other things
Uninterruptible Power Supply (UPS).
The world market for deep cycle, rechargeable, industrial storage batteries
exceeds $5 billion annually. Telecommunication companies are the largest users
of storage batteries for back-up power on grid connected DC powered systems,
such as switches, receivers and transmitters that must continue to operate in
the event of electricity grid failure. Such companies are also large users of
storage batteries for non-grid connected equipment located in remote areas.
The Power Quality Equipment and Services Market should reach $6.3 billion by
2007, up from $2.9 billion in 1997, according to BCC Research. This represents
an average annual growth rate (AAGR) of 8.1%.