lexcarb

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**Marit JAGTOYEN**

**Auto Exhaust Water Recovery System**

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 [**http://lexcarb.com**](http://lexcarb.com)

**Development of On-Board Water Recovery Unit for the Future
Combat System (FCS), HMMWV and the Tactical Quiet Generator**

**Executive Summary**

The primary goal is to develop a fully integrated and automated
prototype system for the collection, purification and storage of
potable water from the exhaust gases of military land vehicles.
A heat exchanger & refrigeration system is used to recover
water generated during the combustion process. The system is
designed to operate under desert conditions. A mesoscale heat
exchanger is under development at MesoSystems, Inc. This unit
would be smaller than conventional heat exchangers and could
eventually fit in the wheel arch of the HMMWV. The water cleanup
is performed using a purification train under development
consisting of an ultra-high efficiency glass fiber filter,
activated carbon and carbon fiber, zeolites and ion exchange
resins. The water purification canister design is challenging
since the water contains a mixture of organic and inorganic
acidic compounds. Currently, the water meets drinking water
standards with a TOC of < 2 ppm and in most cases is less
than 0.5 ppm, and a metal's content below EPA regulated limits.
Identification and removal of remaining TOC is the focus of
current research. For comparison most municipal water supplies
have a TOC of 2-3 ppm.

The successful development of a system that produces potable
water from vehicle exhaust and is small enough to be of military
utility will augment a unit's water supply and reduce its
dependence on the supply infrastructure. This will lead to a
more mobile, deployable, and flexible force. The technology will
also provide water to small units in water scarce environments.
The system will provide safe, lifesaving, drinking water in
disaster relief and emergency applications. It could also
provide recreational vehicles in water scarce environments with
a critical survival tool...

But don't ask Jagtoyen, who can often be seen driving a red
Hum-Vee around town, to chug a bottle of her diesel water just
yet. There are still traces of two unidentified compounds in the
otherwise pure water. They're probably harmless, she said, but
so far she's only sipping.

![](exhstwatr.jpg)

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**PATENTS**

**US6581375 (B2)**   
**Apparatus and Method for the Recovery and
Purification of Water from the Exhaust Gases of Internal
Combustion Engines**

Inventor: JAGTOYEN MARIT; KIMBER GEOFFREY M   
Applicant: LEXINGTON CARBON COMPANY LLC   
Classification:  - international: B01D53/26; C02F1/28;
F01N3/00; F01N3/02; F01N3/04; F01N3/28; F01N5/02; C02F1/42;
F01N7/02; B01D53/26; C02F1/28; F01N3/00; F01N3/02; F01N3/04;
F01N3/28; F01N5/00; C02F1/42; F01N7/00; (IPC1-7): F01N3/00;
B01D53/26; B01D53/94; C02F1/28   
- European: B01D53/26D; C02F1/28D; F01N3/00B; F01N3/02;
F01N3/04B; F01N3/28D; F01N5/02   
 Also published as:  WO02059043 (A3) // 
WO02059043 (A2-corr) //  WO02059043 (A2) // US2002148221
(A1)

**Abstract ---**  An apparatus and method of use with
internal combustion engines, such as used for land vehicles, for
the on-board recovery and purification of water. The source of
water is from the vehicle's exhaust, where it is collected by
condensation. The water recovery system consists of a device for
cooling the exhaust so as to condense out the water, such as a
counter-current flow heat exchanger in combination with a
chiller (a refrigerant-cooled heat exchanger), which cools the
exhaust below its dew point. Exhaust condensate is collected at
the outlet of the chiller. These cooling devices may be coupled
with the vehicle's air conditioning system. The condensed water
then flows through the water purification portion of the present
invention. The water purification system can rely upon solids
filtration and different forms of activated carbons and
activated carbon fiber composite materials which can be used in
combination with ion exchange resins to provide a water
purification train which is integrated with the water recover
unit on board the vehicle. The water can be purified to have a
TOC of less than 2 ppm to meet EPA drinking water standards, as
well as Department of Defense tri-service requirements for
long-term consumption as specified in TB Med 577. Potable water
can be produced at a rate of approximately up to 0.7
gallons/gallon fuel utilizing a HMMWV diesel engine. This allows
production of about 15 gallons per day of potable water on-board
the HMMWV (based on consumption of about 30 gallons of fuel per
day).

**References Cited [Referenced By]**   
**U.S. Patent Documents**

1653603 December 1927 Schroder   
2071868 February 1937 von Lude   
2310767 February 1943 Durr   
2479766 August 1949 Mulvany   
3408289 October 1968 Gustafson   
3985648 October 1976 Casolo   
4263263 April 1981 Vaseen   
4374028 February 1983 Medina   
4430226 February 1984 Hegde et al.   
4656831 April 1987 Budininkas et al.   
4725359 February 1988 Ray   
4813632 March 1989 Woodhouse   
4863637 September 1989 Matsumoto et al.   
5174902 December 1992 Shubert et al.   
5256268 October 1993 Goto et al.   
5607595 March 1997 Hiasa et al.   
5795843 August 1998 Endo   
5857324 January 1999 Scappatura et al.   
6030698 February 2000 Burchell et al.   
6398965 June 2002 Arba et al.   
**Foreign Patent Documents**

 WO 00/04977  Feb., 2000  WO

**Other References**

Jagtoyen, et al., U.S. Army SBIR Contractor's Scientific and
Technical Report (Report A002 and A003), "Activated Carbon Fiber
Composite for On-board Water Recovery Unit," (SBIR Topic A97090)
May 19, 1998..

**Description**

**TECHNICAL FIELD**

The present invention relates to an apparatus and method for
the recovery and purification of water from the exhaust gases of
internal combustion engines, such as those used in land transit
vehicles, (e.g., cars). More particularly, an on-board, portable
device produces potable water from vehicle exhaust gases.

**BACKGROUND OF THE INVENTION**

Several devices have been utilized over the years to attempt to
provide a feasible system for producing potable water from
vehicle engine exhaust. These attempts have been generally
unsuccessful.

Combustion of diesel, kerosene, gasoline, LP gas or other
fossil fuels in an internal combustion engine produce water
vapor, which is expelled with the exhaust gases. The present
invention allows for the recovery of that water to provide a
source of water for potable and other uses. The engine exhaust
emissions vary as a function of fuel type and composition, as
well as the fuel:air ratio, the type of engine and mode of its
operation, and also factors such as ignition timing, cylinder
design and fuel additives. Although the relative concentrations
of various exhaust components may change depending on the mode
of engine operation, generally the nature and content of exhaust
remains within a predictable range. It would be useful to be
able to capture this water vapor and turn it into drinkable
water, particularly for military operations or travel in hostile
environments (e.g., desert areas).

The concentration of water vapor in exhaust gases of either
gasoline or diesel engines or turbines ranges up to about 10% by
volume. Upon cooling the exhaust gases below its dew point, i.e.
about 100.degree. F., water begins to condense. Some gases
present in the exhaust, such as oxygen, nitrogen and hydrogen,
do not condense. The other exhaust components, such as
hydrocarbons, sulfur dioxide, nitrogen oxides, carbon dioxide
and particulates and suspended solid matter, other dissolved
organic and inorganic matter (including metals), contaminate the
condensed water by dissolving in or condensing with the water
vapor and must be removed to obtain a potable water product. The
treatment apparatus for the recovery of potable water from the
engine exhaust must condense the water vapor, remove the
particulates, and purify the water produced therefrom.

Vehicle exhaust gases and the condensed water produced
therefrom are very corrosive. The untreated water that is
recovered from the exhaust has a pH of about 3 and, in
combination with high temperatures, corrosion easily occurs in
pits and crevices of a heat exchanger, ducting and ancillary
equipment used to condense it. High exhaust temperatures and the
elevated ambient temperatures that prevail under desert/arid
conditions exacerbate the rates of chemical attack on materials.
Hence, the selection of materials for the components is
extremely important.

Attempts to recover drinking water from exhaust gases of
vehicles have heretofore been unsuccessful because the
purification of the water was not considered technically and
commercially feasible (i.e., the apparatus was too large, the
impurities were too high and/or the process was too expensive).

**SUMMARY OF THE INVENTION**

In brief, the present invention relates to a method for
recovering potable water from the exhaust gases of an internal
combustion engine, comprising the steps of: (a) cooling said
exhaust gases so as to cause water to condense from said gases
(for example, utilizing heat exchangers); (b) passing said water
through one or more particulate filters having a maximum pore
size of from about 0.1 to about 10 microns; (c) passing said
water through one or more activated carbon beds (a preferred one
sequentially combining a wood-based carbon having a majority of
pores in the range of from about 17 to about 40 .ANG., with a
coal-based water-treatment carbon having an average pore size of
from about 6 to about 20 .ANG.--the wood-based carbon preferably
made by phosphoric acid activation and treated to minimize the
amount of phosphorous released into the water); and (d) passing
said water through one or more ion exchange resin beds (a
preferred one being a mixed bed of highly acidic and strongly
basic type 1 ion exchange resins with low organics and
particulate contaminants with high cation and anion exchange
capacity).

Optionally, a buffer such as sodium bicarbonate or a base such
as sodium hydroxide may be added to decrease water acidity. The
sodium bicarbonate may also improve the taste of the water.
These additions may be carried out before either the carbon
filtration or the ion exchange resin filtration steps.

This system can provide potable water having TOC less than
about 0.5 ppm, an inorganic content less than about 2 ppm, and a
pH between about 6 and about 8. The potable water can be
produced at a rate of at least about 0.5 gallons of water per
gallon of engine fuel combusted.

The present invention also includes an apparatus for recovering
potable water from the exhaust gases of an internal combustion
engine comprising a means for connecting said apparatus to the
exhaust portal of said engine (preferably via the catalytic
converter); a means for cooling the exhaust gases so as to cause
the water in said gases to condense; a means for collecting said
water and channeling it to a purification system which comprises
one or more particulate filters having a maximum pore size of
from about 0.1 to about 10 microns, one or more activated carbon
beds, and one or more ion exchange resin beds; and means for
collecting the water which has passed through said purification
system.

More specifically, this invention relates to a portable
apparatus and the method of recovery and purification of potable
water from vehicle exhaust gases. Water can be produced at a
rate of at least about 0.5 gallons/gallon of diesel using a 6.5
liter diesel engine with a compression ratio of 21:5:1 and a
Brake Mean Effective Pressure (BMEP) of about 300 psi, as is
standard issue in a HUMVEE, or "HMMWV" United States armed
forces vehicle, while having only a small (i.e. <7%) effect
upon the engine performance of the vehicle. A combination of
particulate filtration to remove solids, treatment by activated
carbon to remove organic compounds and some inorganics, and
treatment by ion exchange resin to remove ionic species, provide
effective removal of toxic and other contaminants to produce
potable water having a purity which exceeds the EPA drinking
water standards, as well as the DOD TB MED 577 tri-service water
quality standards for long-term consumption.

The activated carbon material used in the instant invention
removes essentially all of the organic contaminants, even though
some are present at concentrations in the ppb range. The water
purification step involves passing the water condensed from the
exhaust gases having a high concentration of Total Organic
Carbon (TOC) materials of from about 50 to about 250 mg/L and a
pH of about 2.8, through a particle filter and an activated
carbon filter to obtain TOC levels in a range of from about 3 to
about 100 mg/L. The resulting product is then passed through an
ion exchange resin to remove metals, inorganic, acidic, and
remaining organic contaminants. The filtered water samples have
a TOC content below detectable limits (BDL) which is 0.5 mg/L
for current EPA drinking water regulations and as low as 0.1
mg/L in some instances. This is a significantly lower TOC than a
control sample obtained from the local municipal water supply
(2.6 mg/L). Moreover, the filtered samples did not contain any
of the hazardous organics mentioned in the EPA's drinking water
rules.

The present invention recovers potable water from engine
exhaust by manually or automatically diverting a desired portion
of the exhaust gas stream to the water recovery system. The
exhaust gas is preferably first passed through the vehicle's
catalytic converter. The catalytic converter generally contains
catalyst consisting of platinum metals, transition metals or
mixtures and oxides deposited either on alumina extrusions or
honeycomb-type monolithic supports. The catalytic converter
needs to be at a certain temperature to completely oxidize the
hydrocarbons present in the exhaust. This normally requires
temperatures of from about 700.degree. to about 1200.degree. F.

The conditions of the catalytic converter are important to the
quality of the produced exhaust condensate. They can
significantly affect the amount of particulates and TOC in the
condensate. It has been determined that the lifetime of the
catalytic converter (for purposes of this invention) is
preferably less than about 50,000 miles, more preferably less
than about 40,000 miles to produce water with the lowest TOC.

Another important factor is the temperature inside the
catalytic converter, which depends mainly on the operating
conditions of the vehicle. At low speeds or low vehicle engine
loads, the temperature in the exhaust is lower than about
500.degree. F., which is not sufficient for the catalytic
converter to fully oxidize the hydrocarbons present in the
exhaust. It is preferable that the temperature be at least about
500.degree. F., preferably at least about 600.degree. F., or
more preferably at least about 700.degree. F. in order to
produce exhaust condensates with as low TOC as possible. In
order to produce the highest quality drinking water, the exhaust
gases are passed through the catalytic converter and vented
through a bypass valve when the temperature in the catalytic
converter is below the desired operating range. When the
temperature of the catalytic converter reaches its operating
range, the bypass valve is closed and the treated exhaust gas
flows through the catalytic converter to the water collection
unit.

The first part of the water collection unit is heat exchange.
The heat exchangers used in the present invention can be
manufactured from aluminum coated with Heresite, stainless steel
(SS), inconel, ceramics, or graphite, preferably stainless
steel, inconel or ceramic. The initial cooling generally takes
place in either an air to gas heat exchanger or a
counter-current gas to gas heat exchanger. For the air-gas heat
exchange system, the exhaust gas is cooled to about 20.degree.
F. above ambient temperature. The exhaust may then be further
cooled in an air conditioner cooled condenser. In the most
likely application scenario, the ambient "desert" temperature is
above the exhaust gas dew-point. Thus, ambient air cooling alone
will be insufficient to condense any water at all. A source of
cooler heat exchange fluid is required and this is most
conveniently provided by refrigerant at 30-80.degree. F., or
more preferably 30-50.degree. F., from a typical automotive
air-conditioning system. The non-condensable gases from the
exhaust are vented and the condensed water is pumped or passed
by gravity through a particle filter, activated carbon filer and
ion exchange resin column for removal of acidic, metallic,
inorganic and remaining organic components and is then sent to a
storage tank where it can be disinfected if storage is required
for prolonged periods of time. Optionally, a small amount of
sodium bicarbonate may be added to the water before carbon or
ion exchange filtration. This buffers the water, raising its pH
so that it will not attack the filters, particularly the ion
exchange resins. It may also improve the taste of the water.

Key issues in putting together the water recovery system is the
design of a system which fits in a standard vehicle and does not
reduce significantly the efficiency of the engine, the removal
of particulates and dissolved contaminants which affect taste
and odor and can be hazardous to human health, the production of
a high enough volume of water to be competitive with
alternatives (e.g., carrying a large volume of water), and the
ability to work in the high temperature and acidic environment
of the exhaust system.

The present invention addresses these issues and will be more
fully understood from the following detailed description of the
invention.

**BRIEF DESCRIPTION OF THE DRAWINGS**

**FIG. 1** is a schematic of an exemplary water collection
phase of the process of the present invention, using an air-gas
heat exchanger.

![](a1.jpg)

**FIG. 2** is a schematic of a water collection phase of the
present invention, using a counter-flow heat exchanger.

![](a2.jpg)

**DETAILED DESCRIPTION OF THE INVENTION**

The process of the present invention is comprised of two parts:
the water collection phase during which the water is condensed
from the exhaust gases, and the water purification phase during
which particulates, organics and other contaminants are removed
in order to make the water potable.

In the water collection phase, the hot exhaust gases are cooled
causing the water vapor in the exhaust to condense. This may be
accomplished by any known cooling mechanism, but is generally
done using heat exchangers, cooled by a combination of one or
more of the following fluids: ambient air, refrigerant e.g.
Freon, or chilled exhaust gas. Prior to entry into the
collection phase, the exhaust is preferably passed through the
vehicle's catalytic converter to fully oxidize the hydrocarbons
in the exhaust to the fullest reasonable extent.

In the water purification phase, the water from the collection
phase is treated to remove impurities and make the water
potable. This generally is accomplished by passing the water
through a particle filter, an activated carbon filter, and an
ion exchange resin filter.

Each of these steps will be described in detail below.

**1. Water Collection System**

Any condensing means known in the art can be used to collect
water from the hot exhaust gases. Two possible exemplary
alternative mechanisms will be described for the water
condensation system. This does not exclude other systems based
on ceramic, graphitic, inconel or other heat exchanger-based
systems.

**A. Exhaust Condensation by Air-Gas Heat Exchange Combined
with Chiller**

The estimated average temperature of the exhaust at the tail
pipe is normally up to about 800.degree. F. The bulk of the
cooling of the exhaust is performed in an air-cooled heat
exchanger made either from aluminum coated with Heresite,
stainless steel, inconel, titanium, ceramic, mesophase pitch,
foam or graphite. The intercooler used in this example is
normally used to cool charge air after turbo-compression in
large truck engines. The particular intercooler used in these
experiments may be obtained, for example, from Thermal Control
Technologies Corporation of Prescott, Ariz., but can also be
obtained from a range of manufacturers. The intercooler core is
35.5" wide and 30.75" high and has a thickness of 2". It
consists of aluminum rectangular section tubing with finned
inserts both on the process and service sides. This core is
modified to reduce corrosion by coating with Heresite, a
commercial process which results in a phenolic resin coating
that is only thousandths of an inch thick and has only a minimal
effect on heat transfer. Two 16" diameter 12 volt DC fans pull
ambient air at up to 6,000 scfm through the intercooler. This
heat exchanger cools the exhaust gases down to within about
50.degree. F., and usually within about 20.degree. F., of
ambient temperature, which may be below the dew point of the
gas. If further cooling is necessary (e.g., in a desert
environment), the exhaust gases are further cooled by
refrigeration, utilizing the engine-driven compressor from the
vehicle's air conditioning system (see below). The water is
collected in a container, which may optionally contain a
demister to prevent fine aerosol water droplets from escaping
with the exhaust air. These components can, for example, be
mounted on the rear bed of a HMMVW vehicle.

As described above, a chiller, i.e. another heat exchanger, is
optionally mounted after the intercooler. One such chiller is a
GM Van Rear AC Chiller #1254-3631 which can be installed inside
the water collection vessel to save space. The chiller is sealed
in the inlet to the vessel so that all exhaust gases must pass
the Heresite-coated fins, allowing more cooling of the exhaust
gases. The coolant is piped from the front of the vehicle to the
rear into the chiller via flexible lines installed under the
vehicle along the frame rails and entering the bed of the
vehicle through a hole cut into the floor. Optionally, thermal
insulation can be added to the chiller vessel. Also optionally,
a fan shroud can be added to cover the outlet air side of the
intercooler in order to duct the colder air exiting from the
second fan down to the hot end of the intercooler. FIG. 1 shows
a schematic of an on-board water recovery unit utilizing an
air-to-air heat exchanger in combination with a chiller to
recover exhaust condensate.

In the Figures, T denotes a temperature sensor and P denotes a
pressure sensor in the apparatus used to carry out the present
invention. These pressure and temperature sensors are used to
monitor the process of the present invention on an ongoing basis
to optimize its performance.

A fan may be used to suck air into the heat exchanger.
Moreover, a duct may be placed at a forward or elevated position
of the vehicle in order to capture air which has not been
subjected to engine heat.

**B. Exhaust Condensation by Gas-Gas Counter-Current Flow Heat
Exchanger Using Chilled Exhaust as Cooling Medium**

An alternative system for water recovery includes a
counter-current flow heat exchanger, which uses the
chiller-cooled exhaust as cooling medium. This heat exchanger
can be manufactured in stainless steel (particularly 304 SS),
inconel, titanium, ceramic or graphite. If it utilizes narrow
(<1 mm) meso channels and ultra thin walls (<0.1 mm), it
may be small enough to install under the vehicle or in a wheel
arch because it does not need a supply of cool ambient air (as
opposed to the air-gas exchanger described above). This does not
preclude the desirability of additional heat loss by locating
the exchanger in a cool area or by the use of a small amount of
fan-blown ambient air.

**FIG. 2** shows a schematic for a water recovery system
including a counter-current flow heat exchanger.

Refrigerating the exhaust gas already cooled to near ambient
temperature and having a relatively high water vapor partial
pressure is extremely attractive. For example, cooling the
exhaust gases to around 100.degree. F. involves a heat exchange
of around 50 kW (e.g., cooling from 600.degree. F. to
100.degree. F.), and possibly no condensation at all if the dew
point was 100.degree. F. A further extraction of 5 kW would drop
the temperature such that about 15 lbs/hr of water would
condense, i.e. a consequent massive increase in the efficiency
of the water recovery unit. Moreover, the use of a cooler can
reduce the size of the heat exchanger. The compressor and its
associated condenser may be shared with the vehicle's air
conditioning system or be an independent system. The compressor
can be driven by the engine of the vehicle and a switch can be
installed to control the compressor and maintain it in the
activated position whenever water recovery is desired to be
maximized.

An important consideration in selecting a heat exchanger is the
material of construction. Aluminum is inexpensive but if coated
with Heresite should not be used with temperatures exceeding
about 450.degree. F. Stainless steel is heavier and more
expensive but provides the durable corrosion resistant material
desired. Other alternatives include producing a heat exchanger
from ceramics; one such example is a unit similar to those used
in catalytic converters, although they need to be rendered
impermeable. Other possibilities include inconel, titanium or
graphitic foams.

**2. Water Purification System**

The collected water is filtered in several treatment stages,
which can be arranged in a purification train. The first stage
involves filtration of particulates from the exhaust condensate
using material having an appropriate maximum pore size (e.g.,
from about 0.1 to about 10 microns, preferably from about 2 to
about 10 microns), for example, glass fiber paper having a pore
size of from about 1 to about 10 microns. Millipore micron
filters with 0.1 micron average pore size made, for example, of
Teflon.RTM. can also be used. These will have a slower flow rate
than the glass fiber paper filters.

The second stage involves adsorption of organics and some
inorganics onto a bed of activated carbon. The carbon can be
either granular activated carbon (GAC), activated carbon fibers,
or composites of activated carbon granules and/or activated
carbon fibers. Another form of carbon may be a composite or
block of activated carbon containing granular or powdered carbon
with a binder. Yet another option is to utilize an activated
carbon fiber composite containing powdered activated carbon
immobilized within the structure. These materials will prevent
bed movement during operation. Examples of such carbon materials
are disclosed in PCT Published Application No. WO 00/04977,
Jagtoyen et al., published Feb. 3, 2000, incorporated herein by
reference.

The activated carbon adsorbent is an important component of the
present invention. The main portion of the acidic compounds and
other organic compounds are removed by the activated carbon.
"The carbon must have a wide range of pore size distribution;
one way to do that is by using two different adsorbent
carbons."One carbon is, for example, a coal-based granular
activated carbon sold commercially for water treatment. The main
porosity is due to pores having an average pore size of from
about 6 to about 20 .ANG.. The second carbon bed contains wide
pores (mesopores) to remove large organics. This carbon has some
narrow micropores in the range of from about 6 to about 12
.ANG., and significant mesoporosity with pores of from about 17
to about 40 .ANG., and some wider mesopores in the about 40-120
.ANG. range. These numbers are based on pore size distribution
analysis by N2 adsorption using the Density Functional Theory
(DFT). This carbon can be, for example, a wood-based carbon made
by phosphoric acid activation. "A carbon found to be useful in
the present invention is a Westvaco carbon that was treated so
that it does not release too much phosphorus into the water."

An alternative would be to use an activated carbon fiber
composite for the water treatment instead of the coal-based
carbon. This material has an open and permeable structure and
can be produced in single pieces to a given size and shape. The
activated composite can be made from isotropic pitch-derived
carbon fibers and exhibits novel properties including rapid rate
of adsorption and desorption, the ability to form specific
shapes of high permeability and strength.

The open structure of the composites combined with the
presentation of the reactive surfaces for adsorption or
catalysis in the form of narrow diameter fibers allows direct
access of the contacting fluid with minimal mass transfer
limitations, and very high rates of adsorption, desorption and
reaction. The contaminant removal is better than commercially
available filters for many compounds, particularly small organic
compounds, and the activated carbon filter also is uniquely
effective in that it removes waterborne pathogens with
efficiencies of 99.99% or better. This filter is described in
PCT Published Application WO 00/04977,Jagtoyen, et al.,
published Feb. 3, 2000. The carbon filters generally have a
minimum surface area of at least about 1000 m.sup.2 /g.

Another form of carbon may be a composite or block of activated
carbon containing granular or powdered carbon with a binder or
resin-based carbons. Yet another option is to utilize an
activated carbon fiber composite containing powdered activated
carbon immobilized within the structure. There will be no bed
movement during operation for the composites, hence no loss of
fines, degradation and potential for increased pressure drops in
the system over time.

Yet another type of carbon can be a surface-treated carbon
particularly optimized to remove polar organics from water.

In a preferred embodiment, an effective amount of sodium
bicarbonate is added to the condensate to counteract its
acidity. This may be done at any point in the process but is
preferably done prior to the carbon filtration step. The sodium
bicarbonate acts to buffer the water and to improve its taste.

The third stage is filtration through a bed of ion exchange
resin. A mixed bed of cation and anion resins can be used to
remove the inorganic contaminants, remaining organic compounds
that are polar in nature, acids, nitrates and metals. The ion
exchange resin bed removes all the detectable inorganic and
metal contaminants to below detectable limits. The resin is
preferably a mixed bed of strongly acidic and strongly basic
type 1 ion-exchange resins. They are of the ultimate purity in
terms of organics leaching and particulate contaminants. A
preferred ion exchange resin is Amberlite UP6040.RTM.,
commercially available from Rohm & Haas. In sample runs, the
flow rate through the resin was about 217 ml/min, which is about
42 bed volumes per hour. It is preferred that the flow rate
through the water purification system be from about 30 to about
50 bed volumes/hr.

A particulate filter is optionally added at the end of the
purification train to capture any carbon fines created during
filtration. Optionally, the water can be filtered through
another activated carbon fiber composite filter. Moreover, the
ion exchange resin can be sandwiched between two layers of
activated carbon filter composite material utilizing the
structural integrity of the composite to support the ion
exchange resin to prevent channeling and abrasion forming a
monolithic cartridge. Another option is to add a polymeric
pre-filter to remove oily compounds. Addition of sodium
hydroxide or sodium bicarbonate (or other non-toxic basic salts)
before any filtration in order to neutralize the water is a
possibility. Zeolites or clays or activated alumina can be used
to remove some acids and inorganics. After the purification is
complete, the water is stored in a 5-15 gallon container which
may or may not contain disinfectants Conventional disinfectants
(such as chlorine or mixed oxidants like the MIOX system) can be
used at their art-established levels.

The water produced by the present invention is potable,
satisfying the following maximum impurity levels: TOC of no
greater than 2 ppm, and EPA drinking water standards for all
organic and inorganic compounds and metals.

**EXAMPLES**

The following examples illustrate the process and apparatus of
the present invention.

Exhaust condensate was produced while driving a 1994
civilian-equipped Hummer, modified to practice the present
invention, using an intercooler coated with Heresite as heat
exchanger in combination with a chiller to condense water from
the exhaust. Data from different water production runs are shown
in Table 1. The average condensate yield was about 0.5 gallons
per gallon of fuel. A large sample of condensate which was
produced while driving at 60 mph, and had a TOC of 58.6 mg/L,
was used as the raw water for the water purification studies
reported below.

An example of a water purification train consisted of
particulate filters, two different granular carbons and one ion
exchange resin filter.

The condensate was first filtered through laminated glass fiber
paper (maximum pore size 2 micron) which removed on average 55
ppm of solids. A 0.1 micron filter was used for polishing,
although this may not be required. Refiltering one batch through
a 0.1 micron filter removed less than 0.01 ppm solids.

C33 (Coal-based GAC): This bed was made using coal-based
activated carbon from the Calgon Corporation. The condensate was
run through the column at a flow rate of 20 ml/min or 3.7 column
volumes per hour. After 0.7 gallons, the TOC was reduced to 8.1
mg/L. The TOC remained between 7 and 8 mg/L, up to 9.4 gallons.
At 10.8 gallons, the TOC increased to 9.9 mg/L. After another
1.4 gallons, the TOC had dropped to 5.3 mg/L and remained low
for the rest of the treatment.

C34 (Wood-based GAC): After the water was purified through the
C33 bed, it was ran through the wood-based GAC bed at 13 ml/min
or 2 bed volumes per hour. When this carbon was used after the
Calgon carbon (C33), it dropped the TOC down to 3.0 mg/L after
1.3 gallons. When C34 was used after a combination of C33, R11
and R12 (discussed later), the TOC was reduced from 3.2 to 1.5
mg/L after 0.5 gallons and 2.4 mg/L after 0.8 gallons.

R11 (Ionac A-554 resin from Sybron Chemicals, Inc.): This resin
is designed to remove nitrogen compounds. When used after C33,
this resin actually increased the TOC from 5.3 mg/L to 7.4 mg/L
after only 1.3 gallons. But when used after C33 and C34, it had
no effect on the TOC (the beginning TOC was 3.0 mg/L and the
ending TOC was 2.8 mg/L).

R12 (Resin from Rohm & Haas): This resin, when used after
the carbon filtration (with or without R11), removes the
remaining contaminants from the condensate. The column height
was 24" and column diameter 1". The flow rate through the bed
was 218 ml/min or 42 bed volumes per hour. The optimum flow rate
for the resin can range from about 1-50 bed volumes per hour.

When R12 was used after the C33-C34 combination, it dropped the
TOC from 3.0 mg/L to less than the detection limit of 0.5 mg/L
(estimated to be 0.1 mg/L by the instrument). When R12 was used
again after the combination of C33C34R12C34, it reduced the TOC
to 0.6 mg/L. After the combination of C33C34R11, the TOC was
reduced to less than the detection limit of 0.5 mg/L (estimated
to be 0.3 mg/L by the instrument).

TABLE 1 Water Collection Results Water Amounts (lbs/mile) Yield
Dew Calc. Miles Fuel in outlet per gal pt. Dew pt. Temp. Dew pt.
Temp. Water Cons actual total - diesel air in exhaust IC out
chiller Chiller Run # Collect. (mpg) in fuel air in total in
yield yield (gal/gal) (.degree. F.) (.degree. F.) (.degree. F.)
out (.degree. F.) out (.degree. F.) Steady 50 mph runs 102 84.9
14.9 0.55 0.06 0.61 0.35 0.26 0.63 29 94 76 61 52 103\* 84.7 15.5
0.53 0.04 0.57 >0.23\* <0.34 >0.44 18 97 75 <80 52
115\* 84.8 14.0 0.59 0.06 0.65 0.31 0.33 0.50 32 99 139 77 75
Steady 60 mph runs 104 146.9 12.5 0.65 0.04 0.69 0.39 0.30 0.59
17 102 86 74 54 105 84.8 12.9 0.64 0.09 0.73 0.36 0.37 0.56 39
102 106 76 80 106 81.4 12.8 0.64 0.05 0.69 0.38 0.31 0.58 25 103
101 78 77 107 84.8 12.9 0.63 0.10 0.73 0.26 0.47 0.41 42 103 93
88 80 108 84.8 13.1 0.63 0.04 0.67 0.34 0.33 0.53 18 102 94 76
76 110 84.8 12.0 0.68 0.03 0.71 0.34 0.37 0.48 13 103 115 83 76
111 84.8 13.4 0.61 0.04 0.65 0.33 0.32 0.54 22 99 105 76 71 113
12.3 12.8 0.64 0.07 0.71 0.44 0.27 0.67 35 103 105 72 79 114
74.9 13.0 0.63 0.06 0.69 0.37 0.32 0.58 29 102 100 78 72 5-50-5
mph runs 109 28.1 10.3 0.79 -- -- 0.50 -- 0.62 31 -- 101 -- 76
116 28.1 10.0 0.82 -- -- 0.43 -- 0.52 27 -- 143 -- 77 \*There
were condensed water losses.

Good results were achieved by using a combination of the two
carbon beds and the Rohm & Haas ion exchange resin column,
C33OC34DR12E (referred to as C33E herein). This sample had a TOC
of only 0.1 ppm, a pH of 6.8 and conductivity of only 6.1, Table
2. The other sample was purified through both carbon beds and
both resin beds, and had a TOC of 0.3 ppm (C33C from now on). It
is likely that the second resin bed gave off TOC to the water.
The pH of the water is close to neutral at 6.8 and the
conductivity is very low, 7.5 .mu.S/cm. There appears to be a
correlation between small amounts of TOC and conductivity. Based
on these preliminary data, it is believed that conductivity can
be used as a sensor for water purity, as well as an indicator of
breakthrough on the ion exchange resin bed.

TABLE 2 TOC, pH and Conductivity of Drinking Water from Exhaust
Exhaust Purified Water Metal Water C33O C33LC34O Contaminant MDL
Units W103/115 C34DR12E R11AR12AC3 TOC 0.5 mg/L 65 BDL BDL
pH(Lab) 0.1 pH 3.00 6.84 6.81 Conductivity 0.1 .mu.S/cm 496.4
6.14 7.48

The highest purity sample C33E was submitted for trace organics
analysis (Chemir Labs, Saint Louis, Mo. and EDG, Lexington,
Ky.), to identify the nature of the 0.1 ppm of organic compounds
left in the water.

ESI MS and GC/MS: The first analytical technique used was
Electrospray Ionization Mass Spectrometry (ESI MS) in both the
positive and negative ion modes. Positive ion ESI MS produced an
ion series consistent with the presence of a small amount of
polymer with a separation between the ions of 76 amu. Negative
ion ESI did not produce any ions above background.

The second technique used was GC/MS, using a solid phase
microextractor (SPME) probe to concentrate the analytes before
injection. The analysis indicates the presence of toluene
(retention time .about.3.2 min) and 2-ethyl-1-hexanol (5.25
min). These compounds are present when the sample analysis is
compared to a blank consisting of Millipore purified water. The
components are present in very small amounts, and appear to be
present in smaller quantities than were observed for the
previous analysis.

GC/MS Analysis: This resolves the sample components based on
volatility, and MS detects and identifies the components. Sample
components that interact less with the stationary phase spend
less time in the chromatographic column. In MS, the resolved
sample components are ionized and separated in a mass analyzer.
The fragmentation pattern of a sample component and its computer
library match enables sample identification.

The organic compounds present in water with TOC of 0.1 and 2.6
ppm are shown in Table 3.

TABLE 3 Organic contaminants present in trace amounts in
drinking water samples and a sample with 2.6 ppm TOC
Contaminants Identified in C33C34R12E C33C34R12E R12E Trace
Amounts TOC = 0.1 ppm TOC = 0.1 ppm TOC = 2.6 ppm Toluene trace
0.8 .mu.g/l trace 4-methyl-2-pentanone ND 17 .mu.g/l ND
2-ethyl-1-hexanol trace ND ND small amount of polymer trace ND
ND phosphoric acid, alkyl ND ND trace phosphates
2-ethyl-3-hydroxyethylester of ND ND trace 2 methylpropanoic
acid Tributyrin ND ND trace Note - TOC limit is 2 ppm for
drinking water

All metals identified in the exhaust condensate were reduced
below regulated levels. Sodium was found at 2 ppm and lithium at
1.2 ppb. Some metals are present in the <1 ppb range, for
example, scandium 0.5 ppb, molybdenum 0.13 ppb, niobium 0.01
ppb, aluminum 0.04 ppb, and calcium is present at less than 0.01
ppb.

To illustrate the purity of the water from exhaust, a UV-VIS
scan was performed on the water along with untreated exhaust
condensate, Lexington, Ky. drinking water and organic-free
drinking water purchased from an independent laboratory. The UV
scans show that the exhaust water contains significantly less
organic contaminants than both the organic-free lab grade water
and the Lexington drinking water.

Specific compositions, methods and embodiments discussed herein
are intended to be only illustrative of the invention disclosed
by this specification. Variation on these compositions, methods
or embodiments are readily apparent to a person of skill in the
art based upon the teachings of this specification and are
therefore intended to be included as part of the inventions
disclosed herein. Reference to documents made in the
specification is intended to result in such patents or
literature cited are expressly incorporated herein by reference,
including any patents or other literature references cited
within such documents as if fully set for forth in this
specification.

The foregoing detailed description is given primarily for
clearness of understanding and no unnecessary limitations are to
be understood therefrom, for modification will become obvious to
those skilled in the art upon reading this disclosure and may be
made upon departing from the spirit of the invention and scope
of the appended claims. Accordingly, this invention is not
intended to be limited by the specific exemplifications
presented hereinabove. Rather, what is intended to be covered is
within the spirit and scope of the appended claims.

---



**USP Appln # 2004231345**   
**Use of Flow Through Capacitor in the
Recovery and Purification of Water from Exhaust Gases of
Internal Combustion Engines**

2004-11-25   
Inventor: MAZZETTI MARIT JAGTOYEN (US)   
Classification: - international: B01D5/00; B01D53/26; C02F1/469;
C02F9/00; C02F1/18; C02F1/28; C02F1/42; C02F1/44; C02F1/467;
B01D5/00; B01D53/26; C02F1/469; C02F9/00; C02F1/18; C02F1/28;
C02F1/42; C02F1/44; C02F1/461; (IPC1-7): F17C9/04; F25D3/02;
F25D17/06; F25D21/14; - European: B01D5/00H14; B01D53/26D;
C02F1/469B; C02F9/00H4   
Also published as:  US7000409 (B2)   
**Abstract ---** A process for recovering potable water from
the exhaust gases of an internal combustion engine is disclosed.
In this process the exhaust gases are cooled causing water to
condense out, and the water formed is passed through particulate
filters, activated carbon filters and ion exchange resin
filters. In this process, the water is treated to reduce the
levels of nitrates, sulfates, acidic and other organic
components therein (for example, by passing it through a flow
through capacitor) before the water is passed through the ion
exchange resins. The apparatus for practicing this process is
also disclosed.

**Description**

**TECHNICAL FIELD**

[0003] The present invention relates to an apparatus and method
for the recovery and purification of water from the exhaust
gases of internal combustion engines, such as those used in land
transit vehicles. More particularly, an on-board, portable
device produces potable water from vehicle exhaust gases. More
particularly, the present application deals with the
purification of the water formed using a flow through capacitor
to assist in the removal of metals, inorganics and TOC.

**BACKGROUND OF THE INVENTION**

[0004] The present invention allows for the recovery of water
from exhaust gases of internal combustion engines, such as those
found in military vehicles, cars, jeeps and all-terrain
vehicles. The goal is to provide a source of water for drinking
and for other uses, for example, for army troops in the field or
campers in a wilderness area. The composition of engine exhaust
emissions vary as a function of fuel type and content, as well
as the fuel:air ratio, the type of engine and mode of its
operation, and factors such as ignition timing, cylinder design
and fuel additives. Although the relative concentrations of
various exhaust components may change depending on the mode of
engine operation, generally the nature and content of exhaust
remains within a predictable range. It would be useful to be
able to capture the water vapor found in engine exhaust and turn
it into drinkable water, particularly for military operations or
travel in hostile environments (e.g., desert areas).

[0005] The concentration of water vapor in exhaust gases of
either gasoline or diesel engines or turbines ranges up to about
10% by volume. Upon cooling the exhaust gases below its dew
point, i.e., about 100.degree. F., water begins to condense from
the exhaust. Some gases present in the exhaust, such as oxygen,
nitrogen and hydrogen, do not condense. The other exhaust
components, such as hydrocarbons, sulfur dioxide, nitrogen
oxides, carbon dioxide and particulates and suspended solid
matter, and other dissolved organic and inorganic matter
(including metals), contaminate the condensed water by
dissolving in or condensing with the water vapor and must be
removed to obtain a potable water product. The treatment
apparatus for the recovery of potable water from the engine
exhaust must condense the water vapor, remove the particulates,
and purify the water produced therefrom, and do this in an
efficient and effective way.

[0006] Vehicle exhaust gases and the condensed water produced
therefrom are very corrosive. The untreated water that is
recovered from exhaust gases generally has a pH of from about 1
to about 3 and, in a high temperature environment, corrosion
easily occurs in pits and crevices of heat exchangers, ducting
and ancillary equipment used to condense it, as well as the
various materials, such as the ion exchange resins, used to
purify the water. High exhaust temperatures and the elevated
ambient temperatures that prevail under desert/arid conditions
exacerbate the rates of chemical attack on materials. Hence, the
selection of appropriate materials for the
condensation/purification components can be extremely important.

[0007] A method and apparatus for recovering potable water from
the exhaust gases of an internal combustion engine is described
in our earlier International Patent Application WO 02/059043 A2,
published Aug. 1, 2002, and in U.S. Pat. No. 6,581,375, Jagtoyen
and Kimber, issued Jun. 24, 2003, both incorporated herein by
reference. The method disclosed comprises the steps of:

[0008] (a) cooling said exhaust gases so as to cause water to
condense from them (for example, utilizing heat exchangers);

[0009] (b) passing said water through one or more particulate
filters having a maximum pore size of from about 0.1 to about 10
microns;

[0010] (c) passing said water through one or more activated
carbon beds or monolithic activated carbon (a preferred one
sequentially combining a wood-based carbon having a majority of
pores in the range of from about 17 to about 40 .ANG., with a
coal-based water-treatment carbon having an average pore size of
from about 6 to about 20 .ANG.--the wood-based carbon preferably
made by phosphoric acid activation and treated to minimize the
amount of phosphorous released into the water); and

[0011] (d) passing said water through one or more ion exchange
resin beds (preferred resins being a mixed bed of highly acidic
and strongly basic Type 1 ion exchange resins and/or mixed bed
resins exhibiting ultra-low leaching of organics, such as those
made for the semiconductor industry, with low organics and
particulate contaminants having high cation and anion exchange
capacity). The order in which steps (c) and (d) are carried out
can also be reversed.

[0012] The present invention provides an improvement on the
process and apparatus disclosed in that patent application.

**SUMMARY OF THE INVENTION**

[0013] Specifically, the present invention relates to a method
for recovering potable water from the exhaust gases of an
internal combustion engine, comprising the steps of:

[0014] (a) cooling said exhaust gases so as to cause water to
condense from said exhaust gases; followed by

[0015] (b) passing said water through one or more particulate
filters having a maximum pore size of from about 0.1 to about 10
microns;

[0016] (c) passing said water through one or more activated
carbon filter beds; and

[0017] (d) passing said water through one or more ion exchange
resin filters; which includes the improvement comprising, prior
to step (d), treating said water (for example, using a flow
through capacitor) so as to reduce the levels of nitrates,
sulfates, acidic and other organic components therein (for
example, so as to reduce the ionic conductivity of said water to
from about 1000 to about 20 micro S/cm).

[0018] The present invention also relates to an apparatus for
recovering potable water from the exhaust gases of an internal
combustion engine comprising a means for connecting said
apparatus to the exhaust portal of said engine; a means for
cooling the exhaust gases so as to cause water in said gases to
condense; a means for collecting said water and channeling it to
a purification system which comprises one or more particulate
filters having an average pore size of from about 0.1 to about
10 microns, one or more activated carbon filter beds, and one or
more ion exchange resin beds; and means for collecting the water
which has passed through said purification system; and which
includes the improvement which comprises the inclusion in said
purification system of a means (for example, a flow through
capacitor) for reducing the level of nitrates, sulfates, acidic
and other organic components in said water prior to passing said
water through said one or more ion exchange resin beds.

**BRIEF DESCRIPTION OF THE DRAWING**

**[0019] FIG. 1** shows the results of the water treatment
process described in the Example.

![](b1.jpg)

**[0020] FIGS. 2 and 3** show TOC levels from the process
described in the Example (samples W371 and W374).

![](b3.jpg)  
![](b4.jpg)

**DESCRIPTION OF THE INVENTION**

[0021] The present invention is an improvement over the process
(and apparatus) described in International Patent Application WO
02/059043, published Aug. 1, 2002, and U.S. Pat. No. 6,581,375,
Jagtoyen and Kimber, issued Jun. 24, 2003, both incorporated
herein by reference. In that process, the exhaust gases from the
internal combustion engine are cooled so as to cause the water
vapor contained in those gases to condense; the water formed is
passed through one or more particulate filters having a maximum
pore size of from about 0.1 to about 10 microns; the water is
passed through one or more ion exchange resin beds; and the
water is passed through one or more activated carbon beds. The
water may also, as a final step, be passed through a polishing
bed comprising carbon particulate filters. That invention also
includes an apparatus for recovery of potable water from exhaust
gases of an internal combustion engine comprising a means for
connecting said apparatus to the exhaust portal of said engine
(preferably via the catalytic converter); a means for cooling
the exhaust gases so as to cause the water in those gases to
condense; a means for collecting the water and channeling it to
a purification system which comprises one or more particulate
filters having a maximum pore size of from about 0.1 to about 10
microns, one or more activated carbon beds, and one or more ion
exchange resin beds; and means for collecting the water which
has passed through said purification system.

[0022] In the present improvement, the acidic and ionic
components, such as sulfates and nitrates, as well as metals and
organics, are removed from the condensed water prior to the time
that the water is introduced into the ion exchange resins. It
was found that the presence of sulfates and nitrates in the
untreated condensate was causing problems over time.
Specifically, the corrosive nature of the untreated exhaust
condensate caused oxidation and degradation of the ion exchange
resins and other components of the purification system, with a
resulting leaching of organic compounds from the ion exchange
resin into the treated water. In the process of the present
invention, ionic components, such as sulfates and nitrates, are
removed from the condensed water. The process may also remove
acidic and polar organic compounds. The net result of this
removal is that the ionic conductivity of the condensed water is
reduced from about 700-1000 micro S/cm to about 10-50 micro
S/cm. It is preferred that the treated condensed water have an
ionic conductivity of from about 10 to about 80, more preferably
from about 10 to about 50, most preferably from about 10 to
about 30, micro S/cm.

[0023] One way of accomplishing the removal of these ionic
compounds is through the use of a flow through capacitor (FTC).
Flow through capacitors are known in the art and are
commercially available from Biosource Inc. They are described,
for example, in the following U.S. patents, which are all
incorporated herein by reference: U.S. Pat. Nos. 5,192,432,
Andelman, issued Mar. 9, 1993; 5,196,115, Andelman, issued Mar.
23, 1993; 5,200,068, Andelman, issued Apr. 6, 1993; and
5,360,540, Andelman, issued Nov. 1, 1994. Generally, the flow
rate through the capacitor will be from about 0.1 to about 2 lpm
(preferably about 500 ml/min), the current in the capacitor is
from about 7 to about 11 A, and the voltage is between about 1.2
and about 1.5 V.

[0024] Another technology that may be useful in treatment of
the condensate is electrochemical treatment where a voltage of
12-18 V at 2-4 A is applied to electrodes immersed in the water
(i.e., an electrochemical cell). Powerful oxidizing agents are
produced without the addition of chemicals. Most kinds of
organic contaminants present in aqueous effluents are destroyed
or oxidatively degraded. BOD, COD, TOC, odor, color,
microorganisms, or other parameters indicative of the presence
of organic contaminants can be reduced to the ppb level or
lower.

[0025] Reverse osmosis, a process well known in the art, may
also be used to treat the condensate.

[0026] The removal of acidic and ionic components from the
condensate will render the water less corrosive before it enters
the ion exchange resin bed. By removing the sulfates, nitrates
and organic acids prior to running it through the ion exchange
resin bed, corrosion to the bed will be minimized. An additional
benefit of this process is the potential to remove ionic
contaminants from surface waters and sea water, allowing the use
of these as alternative water sources for the purification
system disclosed herein.

**EXAMPLE**

[0027] The following example illustrates the process and
apparatus of the present invention.

[0028] The internal combustion engine exhaust utilized in this
example was produced while driving a 1994 civilian-equipped
Hummer, modified to practice the present invention, which
included a heat exchanger to condense the water from the exhaust
gases (manufactured by NSM Corporation, England). The water
purification train of the present invention consisted of
particulate filters, a flow through capacitor, two different
granular carbon filters and one ion exchange resin filter.

[0029] The condensate was first filtered through laminated
glass fiber paper (maximum pore size 2 microns), which acted as
a particulate filter, removing an average of 55 ppm of solids.
The glass fiber paper was manufactured by Hollingsworth and
Vose.

[0030] The condensate was carbon-treated prior to introduction
into the flow through capacitor (FTC) to remove neutral organics
that can foul the membranes and electrodes of the FTC. The
carbon filter materials utilized were selected based on two main
criteria: high hardness and wide pore size distribution. In this
example, two different carbons were used. The first was
coal-based carbon F300 from Calgon, which has high hardness and
high density and, as a result, exhibits high capacity for
organic removal from water. The second carbon utilized has a
relatively wide pore size distribution and is a wood-based
carbon, such as RGC from Westvaco. This carbon is used to remove
large molecular weight organics as well as some polar organics
that coal-based carbons with less functionality do not remove as
well. The carbon materials were packed sequentially in a 2-inch
diameter, 10-inch tall SS bed operating in an up-flow mode. The
flow rate through the bed was 22 ml/min, which is equivalent to
about 150-200 ml/min in a full size bed (which would be able to
treat more than 2 gallons of water/hour). The results of the
carbon treatment are shown in Tables 1 and 2 and FIG. 1. The TOC
of the condensate water is lowered by this procedure from a
starting TOC of about 50-80 ppm to below about 20-30 ppm, i.e.,
most of the nonpolar organics and some polar organics are
removed.

1TABLE 1 TOC at different stages of treatment for condensates
W177/78 W177/78 A B C Untreated 67.52 67.52 67.52 Carbon 9.53
11.48 12.34 Capacitor pure 7.75 10.41 11.81 Capacitor waste 8.03
11.9 12.46 R1 -- 3.85 R2 2.61 1.07 Carbon 0.82 0.23 R1: WA-30
Mitsubishi R2: SMT200L, Mitsubishi

[0031]

2TABLE 2 TOC at different stages of treatment for condensate
W185 Waste W185 A B C D E F AC Untreated 54.44 54.44 54.44 54.44
54.44 54.44 Carbon 9.38 10.64 14.12 14.49 20.03 21.89 Capacitor
pure 9.01 9.58 10.4 13.42 8.98 Capacitor waste 9.58 10.92 14.22
24.97 12.42 R1 6.56 9.12 9.41 9.04 10.51 9.12 R2 3.44 6.836 6.96
Carbon 1.61 3.844 5.93 R1: WA-30, Mitsubishi R2: SMT200L,
Mitsubishi

[0032] A flow through capacitor (FTC), produced by Biosource,
Inc., was used in this example. The flow through capacitor
consists of two electrodes: one positive and one negative.
Charged compounds are absorbed on the electrodes, and when the
capacitor has reached saturation it is discharged. The absorbed
ions are desorbed and form a waste stream that is discarded. For
this application, the capacitor should be optimized to have a
waste stream that comprises less than about 5% of the water
treated. The FTC can remove impurities like metals and sulfates
and nitrates from water by flowing it over a charged electrode.
The capacitor will remove and hold contaminants from influent
condensate when it is appropriately charged. The effluent
condensate is thereby purified. At some point during the
process, depending upon the flow rate and quality of the
incoming stream, the FTC will saturate with impurities and
become ineffective. The impurities must then be discharged in a
separate effluent waste stream by turning off the surface
charge. The polarity of each electrode can be reversed every
cycle to prevent fouling of the electrode. A preferred FTC unit
is one which is self-regulating for time on line and time for
regeneration of the electrodes in order to obtain water of a
predefined purity.

[0033] In this example, Sample W174, exhaust condensate from a
titanium cross-flow heat exchanger, was treated with the
Biosource FTC. Because of potential problems with TOC
accumulating on the capacitor electrode, this condensate was
treated with carbon (as described above), before it was run
through the capacitor. The total condensate volume treated for
W174 was about 3 gallons. The TOC concentration in the purified
water after different treatment stages is shown in FIG. 1. The
TOC of the condensate before carbon treatment was 49 ppm. The
carbon treatment reduces the TOC to 18-34 ppm, by removing all
nonpolar and some of the polar organics.

[0034] The next stage is treatment with the Biosource FTC to
remove nitrates, sulfates, metals, inorganics and polar
organics. This was achieved by rejecting a waste stream rich in
the polar contaminants. The water was flowed through the
capacitor at a flow rate of about 350 ml/min, the voltage was
about 40 V, and the current varied between about 1 and about 40
amps. The yield of purified water was 92% in this experiment,
i.e., about 8% of the water enriched in contaminants was
rejected.

[0035] The water was resin treated and carbon treated again at
the end to remove any organics leaching from the ion exchange
resin bed. A 1-micron filter was used at the end to filter out
any fines created during the filtration process. The TOC of the
final sample ranged from 0.6-2.9 ppm after 3 gallons of
condensate was purified with polishing beds of carbon and resin
(see FIG. 1). By using the capacitor, the water yield was
reduced by 8%, but the size of the water purification canisters
in the apparatus will also be reduced significantly, and the
problem of dissolution of the binder in the ion exchange resin
is avoided as a result of removing the sulfates and nitrates at
an early stage in the process.

[0036] A second capacitor with Teflon.RTM. membranes
(Biosource, Inc.) was tested to determine if it was more
resistant to the acidic environment of the exhaust condensate
(flow rate.apprxeq.300 ml/min; capacitor charge=7-10 A and 1.2
V). Water condensate samples W177 and W185 were both treated in
this capacitor. The TOC of the starting condensate and the
purified water are shown in Tables 1 and 2. A total of 2.5
gallons of W177 were treated. For sample W185, 3 gallons were
treated. The TOC content of the water was not reduced
significantly, only 1-2 ppm, using this cell (see Tables 1 and
2), suggesting that the earlier data where TOC was lowered could
be partially due to retention on the cell, or that the operation
of the cell was such that it was not in balance, i.e., too
little time was allowed for regeneration so that TOC was
accumulating at the electrodes.

[0037] The capacitor removed the nitrates, sulfates and metals
to below detectable limits (BDL), as can be seen in Table 3. The
nitrate and sulfate content of the raw condensate was 0.6 and 72
ppm, respectively, and after treatment with the capacitor the
nitrates were below 0.02 ppm and sulfates were below 0.2 ppm.
All metals were removed to BDL, except for trace levels of
sodium, silica, iron and calcium, none of which are hazardous
and all of which would be removed by the ion exchange resin
downstream. Since the capacitor is so efficient in removing the
inorganics and metals, the size of the ion exchange resin bed
can be significantly reduced.

3TABLE 3 Metal Content of Cendensates treated by Carbon and
Flow Through Capacitor (FTC) Raw Condensate Carbon &
Capacitor Parameter MRL MCL W177/78 W177C2P1 W177C3P1 W177C4P1
Units Method Metals Antimony 1 6 <1.0 <1.0 <1.0 <1.0
.mu.g/L 200.8 Arsenic 2 10 <2.0 <2.0 <2.0 <2.0
.mu.g/L 200.8 Barium 2 2000 38 <200 <200 <200 .mu.g/L
200.8 Beryllium 0.3 4 <0.3 <10 <10 <10 .mu.g/L 200.8
Cadmium 1 5 <1.0 <10 <10 <10 .mu.g/L 200.8 Lead 1 15
2 <1.0 <1.0 <1.0 .mu.g/L 200.8 Nickel 1 100 240 <40
<40 <40 .mu.g/L 200.8 Selenium 2 50 <2.0 <2.0
<2.0 <2.0 .mu.g/L 200.8 Thallium 0.4 2 <0.4 <100
<100 <100 .mu.g/L 200.8 Aluminum 2 50-200 8500 <200
<200 <200 .mu.g/L 200.8 Boron 5- 850 <10 <10 80
.mu.g/L 200.8 Calcium 0.1- 0.05 0.05 0.05 mg/L 3111B Cobalt 2-
<2.0 <50 <50 <50 .mu.g/L 200.8 Copper 1 1000 37
<20 <20 <20 .mu.g/L 200.8 Iron 0.1 0.3 0.014 0.008
0.006 mg/L 3111B Magnesium 0.05- 0.2 <10 <10 <10 mg/L
3111B Manganese 2 50 33 <5 <5 <5 .mu.g/L 200.8
Molybdenum 2- 13 <200 <200 <200 .mu.g/L 200.8 Potassium
0.05- <40 <40 <40 mg/L 3111B Silica 0.2- 0.74 1.1 0.7
mg/L 200.7 Silver 2 100 <2.5 <20 <20 <20 .mu.g/L
200.8 Sodium 0.29 0.28 1.09 mg/L Titanium 5- <5.0 <5.0
<5.0 <5.0 .mu.g/L 200.8 Vanadium 2- <2.0 <200
<200 <200 .mu.g/L 200.8 Zinc 5 5000 350 <10 <10
<10 .mu.g/L 200.8 Inorganics Nitrate 0.1 0.6 <0.02
<0.02 <0.02 mg/L 300 Sulfate 0.1 72 <0.2 <0.2
<0.2 mg/L 300 TOC 0.5 2 67.52 7.73 10.2 11.81 ppm Lexcarb
Conductivity 20 25 50 microS/cm Solids 0.5 ppm Lexcarb pH 3.1
5.4

[0038] Jet fuel, such as JP8, may be used as a fuel in the
HMMWV engine. The resulting condensate is more acidic that
condensates made from commercial diesel fuel with pH ranging
from 1.7-2.3 for JP8, and 2-2.3 for diesel. This is due to the
higher sulfur content in JP8. The sulfur content of JP8 fuel can
be as high as 3000 ppm, while in diesel it is about 500 ppm. In
the examples given below, the sulfur content was 1620 ppm
resulting in a condensate pH of 1.7-2.3. The high acidity does
affect ion exchange resin performance. The resin performance is
degraded due to the acidic condensate resulting in higher TOCs
than previously seen in the purified water.

[0039] Based on previous data, a flow through capacitor was
designed for exhaust condensate purification. This capacitor was
optimized to only deliver high quality water of a certain
conductivity (in the range 20-80 micro S/cm) while maintaining a
high yield of purified water. The results from water
purification studies with JP8 fuel have been excellent when
using the capacitor as part of the water purification.

[0040] Two different exhaust condensates (W371 and W374) were
purified with the resin/carbon filtration system, described
above and in U.S. Pat. No. 6,481,375. In separate runs, the same
condensates were pretreated with the capacitor prior to the
resin/carbon treatment. The data from the capacitor runs are
shown in FIGS. 2 and 3, and the results of the water
purification study in Table 4.

4 TABLE 4 TOC (ppm) Purification Stage W371 W374 W371
Condensate 28.7 18.9 28.7 Carbon treated 12.22 9.61 -- Capacitor
treated 4.3 2.33 -- Resin/Carbon purified water 75 gallon 0.65
0.75 1.3 treated

**Description of Capacitor Operation**

[0041] The basic operation of the capacitor in the present
invention is as follows. The capacitor cycling starts with a
change in polarity where water is pumped into the spacer. Then
the concentration cycle starts and lasts for 150 seconds where
polar compounds are migrating toward the electrode. The current
starts out at about 30 A and drops to about 5 A during the
concentration cycle. The voltage stays constant at 1.2 V. The
pump comes on and diverts high conductivity waste to the waste
tube and then the polarity is reversed and the pure water starts
flowing as soon as it meets the required conductivity level.

[0042] Purification cycle: current=6-10 A; voltage=1.2 V

[0043] Concentration cycle: current=30 A drops to 5 A;
voltage=1.2 V

[0044] Waste cycle: current=6-10 A; voltage=1.2 V

[0045] In structuring the capacitor cell for use in the present
invention, the waste water can be recycled for purification in
order to obtain total water yields of 90-95%. A conductivity
probe can be used to monitor conductivity in the incoming
stream, the purified stream and the waste stream, and the waste
can be rejected only when it exceeds a defined limit set to
achieve purification yields of 95% or greater. In this way, only
water that meets a certain conductivity standard would be
allowed to pass through to the next purification step. After
treatment of a particular sample by the capacitor, that sample
had a conductivity of 30-50 microS/cm. The pH of the sample was
still around 5-6, suggesting that there were still acidic
organics in the water since all the nitrates and sulfates had
been removed. In that case, the condensate was treated with a
base ion exchange resin, for example UP 4000 from Rohm and Haas,
before treatment with the high purity, low TOC leaching resin,
in this case UP 6040, from Rohm and Haas (SMT 2001 from
Mitsubishi gives similar results). The condensate may then be
carbon treated. The final TOC content of the samples varied from
0.2 ppm to as high as 5 ppm.

---

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