Glen Kertz - algae BioFuel

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**M. Glen KERTZ**

**Algae BioFuel**

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**"Vertigro" --- Closed vertical growth system produces
algae biofuel, 100,000 gallons / year / acre.**

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[**http://www.valcent.net/s/Home.asp**](http://www.valcent.net/s/Home.asp)

[**http://cc.pubco.net/www.valcent.net/i/PDF/CorporateProfile.pdf**](http://cc.pubco.net/www.valcent.net/i/PDF/CorporateProfile.pdf)


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[**http://www.valcent.net/s/Ecotech.asp?ReportID=182039**](http://www.valcent.net/s/Ecotech.asp?ReportID=182039)

**HDVB**   
**High Density Vertical BioReactor**

The Holy Grail in the renewable energy sector has been to
create a clean, green process which uses only light, water and
air to create fuel. Valcent's HDVB algae-to-biofuel technology
mass produces algae, vegetable oil which is suitable for
refining into a cost-effective, non-polluting biodiesel. The
algae derived fuel will be an energy efficient replacement for
fossil fuels and can be used in any diesel powered vehicle or
machinery. In addition, 90% by weight of the algae is captured
carbon dioxide, which is "sequestered" by this process and so
contributes significantly to the reduction of greenhouse gases.
Valcent has commissioned the world's first commercial-scale
bioreactor pilot project at its test facility in El Paso, Texas.

Current data projects high yields of algae biomass, which will
be harvested and processed into algal oil for biofuel feedstock
and ingredients in food, pharmaceutical, and health and beauty
products at a significantly lower cost than comparable
oil-producing crops such as palm and soyabean (soybean).

The HDVB technology was developed by Valcent in recognition and
response to a huge unsatisfied demand for vegetable oil
feedstock by Biodiesel refiners and marketers. Biodiesel, in
2000, was the only alternative fuel in the United States to have
successfully completed the Environmental Protection Agency
required Tier I and Tier II health effects testing under the
Clean Air Act. These tests conclusively demonstrated Biodiesel's
significant reduction of virtually all regulated emissions. A
U.S. Department of Energy study has shown that the production
and use of Biodiesel, compared to petroleum diesel, resulted in
a 78.5% reduction in carbon dioxide emissions.

Algae, like all plants, require carbon dioxide, water with
nutrients and sunlight for growth. The HDVB bioreactor
technology is ideal for location adjacent to heavy producers of
carbon dioxide such as coal fired power plants, refineries or
manufacturing facilities, as the absorption of CO2 by the algae
significantly reduces greenhouse gases. These reductions
represent value in the form of Certified Emission Reduction
credits, so-called carbon credits, in jurisdictions that are
signatories to the Kyoto Protocol. Although the carbon credit
market is still small, it is growing fast, valued in 2005 at
$6.6 Billion in the European Union and projected to increase to
$77 Billion if the United States accepts a similar national
cap-and-trade program.

Valcent's HDVB bioreactor system can be deployed on non-arable
land, requires very little water due to its closed circuit
process, does not incur significant labor costs and does not
employ fossil fuel burning equipment, unlike traditional
food/biofuel crops, like soy and palm oil. They require large
agricultural acreage, huge volumes of water and chemicals, and
traditional farm equipment and labor. They are also much less
productive than the HDVB process: soybean, palm oil and
conventional pond-grown algae typically yield 48 gallons, 635
gallons and 10,000 gallons per acre per year respectively.

**Vertigro :![](Vertigro.jpg)**
**...   HDVG :**![](HDVG.jpg)

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**Videos**

**Vertigro :**   
[**http://cc.pubco.net/www.valcent.net/i/misc/Vertigro/index.html**](http://cc.pubco.net/www.valcent.net/i/misc/Vertigro/index.html)

**High-Density Vertical Growth :**   
[**http://cc.pubco.net/www.valcent.net/i/misc/HDVG/index.html**](http://cc.pubco.net/www.valcent.net/i/misc/HDVG/index.html)

Energy Policy TV - Transportation Channel: Algae to be Refined
...   
Hawes, 2007/09/29, Toyota Europe. Algae to be Refined Into
Cost-Effective, Non-Polluting Biodiesel, Kertz, 2007/09/26,
Valcent Products ...   
[**http://video.energypolicytv.com/displaypage.php?vkey=c4d7336496819a46a1b6&channel=Transportation**](http://video.energypolicytv.com/displaypage.php?vkey=c4d7336496819a46a1b6&channel=Transportation)

Vertical Algae biofuel Growing (see description and invest) on
...   
Videos / Vertical Algae biofuel Growing (see description and
invest) ...
http://www.scribemedia.org/2007/11/15/glen-kertz-valcent-vertigro-algae-biofuel/
...
  
[**http://technorati.com/videos/youtube.com%2Fwatch%3Fv%3D\_ToojK\_MJd0**](http://technorati.com/videos/youtube.com%2Fwatch%3Fv%3D_ToojK_MJd0)

Energy Policy TV - Biofuels Channel: Algae to be Refined Into
Cost ...   
Currently playing... Algae to be Refined Into Cost-Effective,
Non-Polluting Biodiesel, Kertz, 2007-09-26, Valcent Products ...
  
[**http://video.energypolicytv.com/displaypage.php?channel=Biofuels&vkey=c4d7336496819a46a1b6**](http://video.energypolicytv.com/displaypage.php?channel=Biofuels&vkey=c4d7336496819a46a1b6)

YouTube - Algae Biofuel Innovation Discussed on KTAB-TV   
Glen Kertz, plant physiologist and President of Valcent ...   
[**http://www.youtube.com/watch?v=VYURCN7o-Mk**](http://www.youtube.com/watch?v=VYURCN7o-Mk)  
YouTube Video Box | Glen Kertz Discusses Algae Biofuel on Happy
...

YouTube - Glen Kertz Discusses Algae Biofuel on Happy Hour   
Glen Kertz, president of Valcent Products, www.valcent.net ...   
[**http://youtube.com/watch?v=8hOR0RuD4DE**](http://youtube.com/watch?v=8hOR0RuD4DE)

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[**http://www.cnn.com/2008/TECH/science/04/01/algae.oil/index.html#cnnSTCVideo**](http://www.cnn.com/2008/TECH/science/04/01/algae.oil/index.html#cnnSTCVideo)

**Algae: 'The Ultimate in Renewable Energy'**

**Miles O'Brien**

  (1  April , 2008 ) ANTHONY, Texas (CNN) -- Texas
may be best known for "Big Oil." But the oil that could some day
make a dent in the country's use of fossil fuels is small.
Microscopic, in fact: algae. Literally and figuratively, this is
green fuel.

Plant physiologist Glen Kertz believes algae can some day be
competitive as a source for biofuel.

"Algae is the ultimate in renewable energy," Glen Kertz,
president and CEO of Valcent Products, told CNN while conducting
a tour of his algae greenhouse on the outskirts of El Paso.

Kertz, a plant physiologist and entrepreneur, holds about 20
patents. And he is psyched about the potential algae holds, both
as an energy source and as a way to deal with global warming.

"We are a giant solar collecting system. We get the bulk of our
energy from the sunshine," said Kertz.

Algae are among the fastest growing plants in the world, and
about 50 percent of their weight is oil. That lipid oil can be
used to make biodiesel for cars, trucks, and airplanes. 
Watch how pond scum can be turned into fuel >>

Most people know algae as "pond scum." And until recently, most
energy research and development projects used ponds to grow it.

But instead of ponds, Valcent uses a closed, vertical system,
growing the algae in long rows of moving plastic bags. The
patented system is called Vertigro, a joint venture with
Canadian alternative energy company Global Green Solutions. The
companies have invested about $5 million in the Texas facility.

"A pond has a limited amount of surface area for solar
absorption," said Kertz.

"By going vertical, you can get a lot more surface area to
expose cells to the sunlight. It keeps the algae hanging in the
sunlight just long enough to pick up the solar energy they need
to produce, to go through photosynthesis," he said.

Kertz said he can produce about 100,000 gallons of algae oil a
year per acre, compared to about 30 gallons per acre from corn;
50 gallons from soybeans.

Using algae as an alternative fuel is not a new idea. The U.S.
Department of Energy studied it for about 18 years, from 1978 to
1996. But according to Al Darzins of the DOE's National
Renewable Energy Lab, in 1996 the feds decided that algae oil
could never compete economically with fossil fuels.

The price of a barrel of oil in 1996? About 20 bucks!

Government scientists experimented with algae in open ponds in
California, Hawaii, and in Roswell, New Mexico.

But that involved a lot of land area, with inherent problems of
evaporation and contamination from other plant species and
various flying and swimming critters. Darzins said NREL switched
from algae research to focus on cellulosic ethanol. That's
ethanol made from plants like switchgrass and plant stover --
the leaves and stalks left after a harvest -- but not edible
crops such as corn and soybeans.

Valcent research scientist Aga Pinowska said there are about
65,000 known algae species, with perhaps hundreds of thousands
more still to be identified.

A big part of the research at the west Texas facility involves
determining what type of algae produces what type of fuel. One
species may be best suited for jet fuel, while the oil content
of another may be more efficient for truck diesel.

In the Vertigro lab, Pinowska studies the care and feeding of
algae for just such specifics. She said even small changes in
the nutrients that certain algae get can help create a more
efficient oil content.

And she said a knowledge of algae's virtues goes way back.

"Even the Aztecs knew it was beneficial; they used it as a high
protein food," said Pinowska.

The other common commercial use of algae today is as a health
food drink, usually sold as "Spirulina."

**I'm too sexy for my pond**

And who knew that single celled plants could be such "hotties"
when it comes to sex? Kertz said it's a real "algae orgy" under
the microscope.

Some algae reproduce sexually, some asexually, while many
combine both modes. In some green algae the type of reproduction
may be altered if there are changes in environmental conditions,
such as lack of moisture or nutrients.

Intriguing details like that keep Kertz and other scientists
searching for more and different algae. While dusty west Texas
may not be the best hunting grounds, he said he is always on the
lookout for samples in puddles, streams or ponds.

Locating algae processing plants intelligently can add to their
efficiency. Locating algae facilities next to carbon producing
power plants, or manufacturing plants, for instance, the plants
could sequester the C02 they create and use those emissions to
help grow the algae, which need the C02 for photosynthesis.

And after more than a decade hiatus, the U.S. government is
back in the algae game. The 2007 Energy Security and
Independence Act includes language promoting the use of algae
for biofuels. From the Pentagon to Minnesota to New Zealand,
both governments and private companies are exploring the use of
algae to produce fuel.

But Al Darzins of the National Renewable Energy Lab said the
world is still probably 5 to 10 years away from any substantial
use of biofuels.

"There's not any one system that anyone has chosen yet.
Whatever it is has to be dirt, dirt cheap," said Darzins.

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**Patents**

**[ HTML ]**

**European Patent Office** **http://v3.espacenet.com**

**Plant Growing Room**   
**US6173529**   
**2001-01-16**   
The growing room includes a closed loop track suspended above
the floor and extending throughout the room. A plurality of
racks are movably supported on the track by a motorized mover
system. The racks include a frame for supporting a plurality of
growing sheets for supporting and growing the plants. The
growing sheets are made of a translucent material and include a
plurality of growing cells formed by affixing a plurality of
lengths of membrane material to the sheet at predetermined
locations. The growing cells are gas permeable, liquid
impermeable, and translucent.

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**Plant Growing Room**   
**US6122861**   
**2000-09-26**   
The growing room includes a closed loop track suspended above
the floor and extending throughout the room. A plurality of
racks are movably supported on the track by a motorized mover
system. The racks include a frame for supporting a plurality of
growing sheets for supporting and growing the plants. The
growing sheets are made of a translucent material and include a
plurality of growing cells formed by affixing a plurality of
lengths of membrane material to the sheet at predetermined
locations. The growing cells are gas permeable, liquid
impermeable, and translucent.

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**Plant Growing Room**   
**US5664369**   
**1997-09-09**   
The growing room includes a closed loop track suspended above
the floor and extending throughout the room. A plurality of
racks are movably supported on the track by a motorized mover
system. The racks include a frame for supporting a plurality of
growing sheets for supporting and growing the plants. The
growing sheets are made of a translucent material and include a
plurality of growing cells formed by affixing a plurality of
lengths of membrane material to the sheet at predetermined
locations. The growing cells are gas permeable, liquid
impermeable, and translucent.

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**ELECTRONIC STIMULATION OF PLANTS**   
**US5464456**   
**Also published as: WO9501090**   
**1995-01-12**   
The invention relates to the electronic stimulation of plant
development. More particularly, it relates to the stimulation of
plant development through electrifying the environment around a
plant or part of a plant with an electrical field, preferably a
pulsed field. The present invention also relates to an
electronic method of stimulating the active membrane transport
systems of growing plants and harvested plant products in order
to promote growth and extend the shelf life of harvested
material. The invention is of particular interest as it relates
to shipment and marketing of cut flowers, greens and trees and
more particularly to methods and apparatus for handling,
shipping, and marketing of cut flowers.

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**Integument and Method for Micropropagation and Tissue
Culturing**   
**US5171683**   
**1992-12-15**   
An integument and related process for the micropropagation of
tissue and for the culturing of other organic matter is made of
a translucent and semipermeable membrane.

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**Automated System for Micropropagation and Culturing Organic
Material**   
**US5088231**   
**1992-02-18**   
An automated system for growing plant material includes an first
length of membrane material having a plurality of open growing
chambers and a second length of membrane material having a
plurality of growing chambers filled with the plant material. A
media preparation unit mixes measured amounts of individual
stock solutions for dispensing media into the open growing
chambers by a fill unit. A fill check scanner unit determines
that a sufficient amount of media has been dispensed within each
growing chamber. A sterilization unit sterilizes the media
filled open growing chambers which then pass to a cooling and
storage unit for cooling and storing the media-filled open
growing chambers until ready for planting with plant material.
The second length of plant-filled growing chambers are housed in
a plant culture room where the plant material is permitted to
grow. A growth detection scanner determines the extent of growth
of the plant material. Upon the plant material reaching a
predetermined growth, the plant-filled growing chambers pass to
a surface sterilization unit for surface sterilizing the
plant-filled growing chambers. A cutting opens the growing
chambers and the plant material is removed. The removed plant
material is passed through a cutting unit where the plant
material is cut into pieces. Each piece of plant material is
then planted into a media-filled open growing chamber from the
cooling and storing unit. A heat sealer closes the open end of
the newly plant-filled growing chambers. The newly plant-filled
growing chambers are then transported back to the culture room.
A tractor feed apparatus transports the lengths of growing
chambers throughout the automated system and a control system
synchronizes and controls the operation of each of the units and
tractor feed apparatus.

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**Automated System for Micropropagation and Culturing Organic
Material**   
**US4978505**   
**1990-12-18**   
An automated system for growing plant material includes an first
length of membrane material having a plurality of open growing
chambers and a second length of membrane material having a
plurality of growing chambers filled with the plant material. A
media preparation unit mixes stock solutions for dispensing into
the growing chambers by a fill unit. A scanner unit determines
that a sufficient amount of media has been dispensed within each
chamber. A sterilization unit sterilizes the chambers which then
pass to a cooling and storage unit until ready for planting with
plant material. The second length of plant-filled growing
chambers are housed in a plant culture room where the plant
material is permitted to grow. A scanner determines the extent
of growth of the plant material. Upon the material reaching a
predetermined growth, the growing chambers pass to a surface
sterilization unit. A cutting unit opens the chambers and the
plant material is removed. The material is passed through a
cutting unit where the material is cut into pieces. Each piece
of material is then planted into a media-filled chamber from the
cooling and storing unit. A heat sealer closes the open end of
the newly plant-filled growing chambers. The newly plant-filled
growing chambers are then transported back to the culture room.
A tractor feed apparatus transports the lengths of growing
chambers throughout the automated system and a control system
controls the operation of each of the units and tractor feed
apparatus.

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**INTEGUMENT WITH BREAKABLE INNER CONTAINERS**   
**WO9015527**   
**1990-12-27**   
Disclosed is an integument (10) having a gas-permeable outer
membrane (12) which is contaminant and liquid impermeable, and
which includes one or more internal containers (1). The internal
containers (1) can be opened from the outside of the integument
(10), to release their contents, without opening the integument
outer membrane (12) or breaching the integrity thereof. The
system is designed so that the outer membrane (12) houses a
biological product and the inner containers (1) house a bacteria
media, or other product which has an effect on the biological
product when the inner container (1) is opened. In an alternate
system, the biological product is housed in the inner container
(1) and the outer membrane (12) holds a product which affects
that biological product. The system can be advantageously
employed in micropropagation, seed growth or inoculation of
plant material, bacterial culturing, or crystal growth, as well
as in many other applications.

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**INTEGUMENT AND METHOD FOR CULTURING AND GROWING ORGANIC
MATERIAL**   
**WO9015526**   
**1990-12-27**   
An integument (10) and related process for the culturing and
growing of living organic material (38). The integument (10)
includes a cellule (30) made of a gas permeable, liquid and
contaminant impermeable membrane (12) for completely enclosing
and sealing the culture (42) from biological contaminants in the
ambient environment. The membrane (12) allows gas exchange
between the living organic material (38) and the ambient
environment to provide enhanced growth and the prevention of
contamination.

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**AUTOMATED SYSTEM FOR MICROPROPAGATION AND CULTURING ORGANIC
MATERIAL**   
**WO9006058**   
**1990-06-14**   
An automated system (10) for growing plant material (122)
includes a first length of membrane (24) having a plurality of
open growing chambers (30) which are subjected to a fill unit
(70) for dispensing growth medium (92), a fill check scanner
(90), a sterilization unit (100), and a cooling and storage unit
(110). A second length of plant-filled growing chambers (30) is
subjected to a growth detection scanner (140) contained in a
plant culture room (130), and is then transferred to a surface
sterilization unit (320) and a cutting unit (280). Plant
material (122) is removed, subjected to a cutting unit (371),
and inserted into the media-filled chambers (30) of the first
length of membrane (24), which is then sealed by a heat sealer
(310). A tractor feed apparatus (50) transports the lengths of
membrane (24) throughout the automated system (10).

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**INTEGUMENT AND METHOD FOR CULTURING AND GROWING ORGANIC
MATERIAL**   
**WO8912385**   
**1989-12-28**   
**Also published as:  EP0418323 (A1)**   
An integument (50) and related process for the culturing and
growing of living organic material (74). The integument (50)
includes a cellule (72) made of a gas permeable, liquid and
contaminant impermeable membrane (12) for completely enclosing
and sealing the culture (74) from biological contaminants in the
ambient environment. The membrane (12) allows gas exchange
between the living organic material (74) and the ambient
environment to provide enhanced growth and the prevention of
contamination.

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**HUELLE UND VERFAHREN ZUR ZUECHTUNG VON ORGANISCHEM MATERIAL.**
  
**AT92247T**   
**1993-08-15**   
An automated system for growing plant material includes an first
length of membrane material having a plurality of open growing
chambers and a second length of membrane material having a
plurality of growing chambers filled with the plant material. A
media preparation unit mixes stock solutions for dispensing into
the growing chambers by a fill unit. A scanner unit determines
that a sufficient amount of media has been dispensed within each
chamber. A sterilization unit sterilizes the chambers which then
pass to a cooling and storage unit until ready for planting with
plant material. The second length of plant-filled growing
chambers are housed in a plant culture room where the plant
material is permitted to grow. A scanner determines the extent
of growth of the plant material. Upon the material reaching a
predetermined growth, the growing chambers pass to a surface
sterilization unit. A cutting unit opens the chambers and the
plant material is removed. The material is passed through a
cutting unit where the material is cut into pieces. Each piece
of material is then planted into a media-filled chamber from the
cooling and storing unit. A heat sealer closes the open end of
the newly plant-filled growing chambers. The newly plant-filled
growing chambers are then transported back to the culture room.
A tractor feed apparatus transports the lengths of growing
chambers throughout the automated system and a control system
controls the operation of each of the units and tractor feed
apparatus.

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**Integument for the Preservation of Organic Material**   
**IN172364**   
**1993-07-03**

**INTEGUMENTO,COMBINACAO CONDUTIVA AO CRESCIMENTO DE
CELULAS,EMBALAGEM DE INTEGUMENTO,PROCESSO DE CULTIVAR MATERIAL
ORGANICO,PROCESSO DE MICROPROPAGACAO E PROCESSO PARA A
PRODUCAO DE UM VEGETAL COM FOLHAS**   
**BR8807398**   
**1990-04-10**

**AUTOMATED SYSTEM FOR MICROPROPEGATION...**   
**CA2004325**   
**1990-06-01**

**GROWING STORAGE AND SHIPMENT CONTAINER**   
**CN1048010**   
**1990-12-26**

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**Glen KERTZ & VertiG**

![](bioreactor.jpg)![](kertz01.jpg)  
 

![](kertz1.jpg)![](kertz2.jpg)

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