Gerald Rowley -- vapor carburetorWarren Brown - The 50% MPG
Gain That Detroit Won't Touch - washingtonpost.com

 
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**Gerald ROWLEY**

**Vapor Carburetor**

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[**http://www.washingtonpost.com**](http://www.washingtonpost.com/)  
 **Sunday,
August 26, 2007**

**The
50% MPG Gain That Detroit Won't Touch**

**by** **Warren Brown**

DELRAY BEACH, Fla.
--- Gerald Rowley keeps his dreams in his garage. There, on a
quiet street in this southeast Florida town, he stores an
aging Mazda 626 sedan, cream white with a worn interior,
unremarkable in nearly all respects with the exception of a
precisely machined, one-gallon steel box in the trunk
connected to fuel lines leading to a gasoline vaporizing
device under the hood.

The steel box holds
one gallon of regular unleaded gasoline. The device beneath
the hood is called the VFS, Vaporizing Fuel System--not the
most elegant name, but one considerably more acceptable and
descriptive than the "Vapster" badge Rowley originally stuck
on his invention.

I came here to drive
Rowley's VFS-equipped car. For years, I had spurned the
invitations of homespun inventors worldwide to travel to
distant points to witness first-hand machines that could
deliver 100 miles per gallon or 200 miles per gallon.

The claims sounded
too incredible to believe -- ridiculous, in fact. If such
devices really worked, really did what their inventors said
they did, why would they still be sitting on shelves in
anonymous workshops -- ignored by the driving public and all
of the vehicle manufacturers who serve them? What automobile
manufacturer in its right mind, especially with rising
concerns about future oil availability and with gasoline
prices escalating worldwide, would not jump at the opportunity
to acquire a device that delivered 100 miles per gallon?

The inventors'
claims didn't make sense. So, I did what any sensible,
hardened journalist would do. I ignored them.

But then a good
friend, Sasha Tapie, a computer geek and an absolute nut about
fuel efficiency, called me boasting about yet another
"fantastic" fuel-saving device "you have to see to believe."

Sasha is a master
salesman. He could sell God heaven at a higher price and make
the Almighty believe He got a deal.

"You just can't
brush this off," said Sasha, who, as usual, had a financial
interest in the project he was extolling. "You just can't walk
away from this without at least driving it yourself. You are a
better journalist than that."

You can sell
anybody, especially a journalist, by appealing to ego. I was
sold. And so here I was with Rowley, a man who grew up making
race car engines, standing in front of his VFS-equipped car,
ready to do something that defied common sense -- take a long
ride in an old car down a Florida highway on one gallon of
gas.

But, first, a
primer: Rowley's patented device is nothing new. It's just the
latest iteration of an idea already developed by others -- the
notion that you could get more miles per gallon out of a
traditional gasoline engine if you pre-heated the fuel to
about 350 degrees Fahrenheit, thus turning it into a vapor
before it enters the combustion chamber.

Vaporized fuel, when
properly mixed with air, burns more efficiently, saves fuel
and emits fewer tailpipe pollutants than traditional fuel-air
mixtures in which gasoline is sprayed into a combustion
chamber in tiny droplets and then mixed with air before
burning.

All car companies
know this. Most have sought to increase combustion efficiency
by swirling gasoline in intake valves before mixing it with
air and by using computers to more precisely open and close
engine intake and exhaust valves to better meter fuel-air
mixtures. The manufacturers' rapid-swirl, electronically
controlled variable-valve lift technology has brought about
substantial increases in fuel efficiency--but nothing near the
reported 40 percent to 60 percent improvements in efficiency
touted by inventors of the pre-heating, fuel vaporizing
equipment.

It turned out that
the steel box in the trunk of Rowley's old Mazda 626 had an
on-off valve leading to a separate fuel line. The car's
original fuel line was connected to a larger fuel tank.

"Don't worry,"
Rowley assured me. "When we run out of fuel in the gasoline
cell [the steel box] the car will coast to a stop. I'll get
out and switch the valve to the regular tank. We won't get
stranded."

I was relieved.

Powered by the fuel
in the test-control box, we entered a nearby highway and
cruised at a steady pace of 65 mph for 45 miles before the
engine sputtered and died, forcing us to coast to a roadway
shoulder. I was impressed. That early 1990s Mazda 626 normally
would have gotten 30 miles per gallon under those conditions.
Rowley's device yielded a 50 percent improvement. It worked.
Or, at least, it certainly seemed to work.

Other fuel vaporizer
pioneers, such as Canadian engineer Charles Nelson Pogue,
inventor of the double-chamber Pogue Carburetor, have made
similar claims about their fuel vaporizing devices. And their
claims are framed with conspiracy theories about why such
technology remains isolated, generally removed from the
marketplace. Pogue has pointed a finger at oil companies,
allegedly working to keep fuel-efficient technology off the
market. Others have accused the car companies of ignoring the
technology to protect their multibillion-dollar investments in
their current gasoline-engine infrastructure.

There is no proof
behind any of those allegations. And, as I pointed out
earlier, the car companies have not ignored the idea of
getting a more efficient burn through a more thorough
vaporization of fuel entering combustion chambers.

The real problem?

My guess is that it
has everything to do with our increasingly litigious culture,
which is woefully intolerant of the trial-and-error nature of
anything related to invention and innovation. What happens to
those fuel vaporizers in a crash? What is the increased
potential of fire and explosion? How do you maintain
government-mandated fuel system integrity with a bolted-on
fuel vaporizing device? Is there any increase in ambient
gasoline vapor emissions with the vaporizers? Who gets sued if
a vaporizer fails and someone is injured or killed, or if a
state or federal agency determines that ambient emissions from
the devices violate clean-air standards? Who carries the legal
and financial weight?

Inventors tend to be
shallow-pocket solo artists, men and women with big ideas
absent big boards of directors and large shareholder groups.
Inventors have more freedom to take chances. Corporations are
different. They have deep pockets, which makes them big
litigation targets. They are well aware that a good deed gone
wrong, even for a moment, can lead to a big and potentially
ruinous lawsuit. As a result, they tread more carefully, which
means it will be a long while before any of them is willing to
take a risk with an externally mounted fuel vaporizing device.

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**Fuel
Vaporizing and Mixing System and Method**

**USP
# 6,578,532**

**( 2003-06-17 )**

**Gerald ROWLEY**

**Abstract ---**
A fuel vaporization and mixing system is provided for
producing a mixture of fuel vapor, atomized water and air for
delivery into an internal combustion engine, the system being
configured and positioned relative to the internal combustion
engine to draw heat from the engine exhaust system to vaporize
fuel for combining into the mixture.

**Current U.S.
Class:  123/25R**   
Current International Class:  F02M 29/00 (20060101); F02M
29/06 (20060101); F02M 31/18 (20060101); F02M 31/02
(20060101); F02M 031/00 ()   
Field of Search: 
123/557,554,527,25R,25A,25B,25C,25D,25N,25P   
 **References
Cited -- U.S. Patent Documents**   
1319718 October 1919 Martin   
3306273 February 1967 Dolphin   
3874353 April 1975 Wooldridge   
3931801 January 1976 Rose et al.   
4112889 September 1978 Harpman   
4188928 February 1980 Faustinos   
4398523 August 1983 Henson   
4594991 June 1986 Harvey   
5685281 November 1997 Li

Other References

Paul Stenquist,
Water Injection, Hot Rod, Jul. 1983, pp. 59 and 60..

**Description**

**BACKGROUND OF THE
INVENTION**

**1. Field of the
Invention**

The present
invention relates generally to the field of fuel combustion
and internal combustion engine design. More specifically the
present invention relates to a fuel vaporization and mixing
system for producing a mixture of fuel vapor, atomized water
and air for delivery into an internal combustion engine, the
system being configured and positioned relative to the
internal combustion engine to draw heat from the engine
exhaust system to vaporize fuel for combining into the
mixture. While it is known that properly combining sprayed
fuel and air with atomized water can boost horsepower and fuel
efficiency, the automobile industry has failed to recognize
that vaporizing the fuel with engine exhaust system heat prior
to mixing with air and water is an efficient way of still
further enhancing horsepower and fuel mileage.

The system includes
a fuel tank for holding fuel prior to vaporization and mixing,
a fuel pump in fluid communication with the fuel tank for
delivering fuel from the fuel tank, a vacuum pump/or vacuum
drawn off engine intake manifold with check valve, a fuel
metering valve in fluid communication with the fuel pump for
metering the flow of fuel from the fuel tank, a vapor
collecting chamber in fluid communication with the fuel
metering valve for holding fuel while the fuel is vaporized,
the vapor collecting chamber being in thermal communication
with the engine exhaust system to draw fuel vaporizing heat
from the exhaust system, fuel blowing means mounted within the
vapor collecting chamber for stirring and uniformly
distributing the fuel vapor, a molecule mixture box in fluid
communication with the vapor collecting chamber for receiving
vaporized fuel from the chamber, a throttle mounting opening
in the molecule mixture box wall containing a throttle, having
a throttle body, for regulating the flow of air from the
surrounding atmosphere into the molecule mixture box, an air
filter mounted to the throttle body to filter air entering the
throttle, a pressurizing air/water pump in fluid communication
with the molecule mixture box, an air intake structure in
fluid communication with the air/water pump for delivering air
through the air/water pump into the molecule mixture box, a
water holding tank in fluid communication with the air/water
pump for delivering water through the air/water pump into the
mixture box, an air/water injector positioned to receive and
transform the air and water exiting the pump into a combined
spray as the air and water enter the mixture box, and a spiral
mixture delivery means for guiding the resulting mixture from
the molecule mixture box into an intake manifold or port of an
internal combustion engine. A method is also provided,
including the steps of delivering sufficient heat into the
fuel to transform the fuel into vaporized fuel; atomizing
water; mixing metered quantities of the vaporized fuel and
atomized water mist with a metered quantity of air to produce
a fuel mixture; and delivering the fuel mixture into an
internal combustion engine.

**2. Description of
the Prior Art**

Many efforts have
been made over the years to boost the performance of internal
combustion engines running on standard, commercially available
gasoline and other hydrocarbon based fuels. A good summary of
known methods is provided in an article published on page 59
of the July 1983 edition of HOT ROD.TM. magazine, entitled

**Water Injection**

"Nearly all of the
changes that an enthusiast might attempt [to boost horsepower]
are designed to raise cylinder pressure: a higher compression
ratio raises pressure by squeezing the mixture into a smaller
combustion area; increasing spark advance raises cylinder
pressure by giving the hot gases more time to expand; even
valve timing and fuel system changes result in more cylinder
pressure because they allow the cylinders to fill more
completely.

"Low-octane fuels
are incompatible with high cylinder pressure because they
ignite easily. As a fuel's octane number increases, it becomes
more resistant to self-ignition. As an engine's cylinder
pressure increases, the combustion chamber temperature
increases. A combination of relatively low-octane fuel and
high combustion chamber temperature causes the fuel to ignite
before the time of spark ignition. This means that the gases
in the cylinder start burning and expanding before they
should. When spark ignition does occur, a second flame front
is developed. The two areas of combustion expand, causing
tremendous pressure and heat between them. This results in
uncontrolled, violent explosion of the unburned parts of the
charge. This effect, known as detonation, breaks pistons,
flattens bearings, and destroys engines.

"There are three
ways to deal with detonation. You can (1) reduce cylinder
pressure and sacrifice horsepower and efficiency, (2) buy
expensive racing gasoline, or (3) inject water to control
rising combustion chamber temperatures --undoubtedly the best
solution.

"Water injection can
work for you in two different ways . . . if it is injected
properly and in the right amounts. A fully aerated water mist
that mixes completely with the incoming charge can keep
chamber temperatures below the flash point of low-octane fuel
until the point of spark ignition. If the amount of water
injected is not excessive, it will only keep the temperature
just barely within limits and will not hinder combustion when
the spark does occur. On the other hand, a well distributed,
fully aerated charge will turn into a steam at the moment of
combustion, expanding nearly 1700 times. . . . The expanding
water vapor will actually increase pressure and, consequently,
horsepower if it turns to steam at exactly the right time . .
.

"Many water
injection systems fail to accomplish this because the're
really nothing more than squirt guns. . . .[T]hey merely
deliver water under pressure to a carburetor without properly
aerating it first."

The benefits of
combining atomized water with the fuel/air mixture and the
need to fully aerate the water component prior to mixing have
been recognized for nearly two decades. Yet there has been no
recognition of the need to fully aerate the fuel, which has at
least equal capacity for boosting engine power and fuel
mileage.

Wooldridge, **U.S.
Pat. No. 3,874,353**, issued on Apr. 1, 1975, discloses an
air and fuel mixing system using a bath of liquid fuel for
contributing liquid fuel to the air. Martin, **U.S. Pat. No.
1,319,718**, issued on Oct. 28 1919, teaches a kerosene
vaporizer for internal combustion engines in which an electric
coil and engine exhaust gases provide vaporizing heat to the
kerosene. Hensen, **U.S. Pat. No. 4,398,52**3, issued on
Aug. 16, 1983, reveals a fuel conservation device in which
fuel is vaporized with a heating element. Harvey, **U.S.
Pat. No. 4,594,991**, issued on Jun. 17, 1986, discloses a
fuel and water vaporizer for internal combustion engines.
Harpman, **U.S. Pat. No. 4,112,889**, issued on Sep. 12,
1978, teaches a fuel system and vaporizer for internal
combustion engines. Faustinos, **U.S. Pat. No. 4,188,928**,
issued on Feb. 19, 1980, reveals a fuel vaporizing apparatus
for internal combustion engines. A problem with these prior
devices and systems is that none teach or suggest the
advantage of combining air and water with fuel which has been
vaporized by engine exhaust system heat.

It is thus an object
of the present invention to provide a fuel vaporization system
which produces a fuel mixture including metered quantities of
vaporized fuel, misted water and air, for high power
combustion within an internal combustion engine.

It is another object
of the present invention to provide such a fuel vaporization
system which vaporizes fuel with heat received from the engine
exhaust system.

It is still another
object of the present invention to provide a fuel vaporization
method for execution by the disclosed fuel vaporization system
which includes the steps of vaporizing fuel with heat from an
engine exhaust system and mixing the vaporized fuel with
atomized water and with air to produce a fuel mixture, and
delivering the fuel mixture into an internal combustion
engine.

It is finally an
object of the present invention to provide such a system which
is reliable and inexpensive to manufacture.

**SUMMARY OF THE
INVENTION**

The present
invention accomplishes the above-stated objectives, as well as
others, as may be determined by a fair reading and
interpretation of the entire specification.

A fuel vaporization
and mixing system is provided for producing a mixture of fuel
vapor, atomized water and air for delivery into an internal
combustion engine having an engine exhaust system, including a
fuel source under vacuum to reduce the vaporization point of
the fuel and for holding fuel prior to vaporization; a fuel
pump in fluid communication with the fuel source for
delivering fuel from the fuel source; a vapor collecting
chamber in fluid communication with fuel pump for holding a
quantity of fuel while the quantity of fuel is vaporized, the
vapor collecting chamber being in thermal communication with
the engine exhaust system to draw fuel vaporizing heat from
the exhaust system; a molecule mixture box having a box wall
and being in fluid communication with the vapor collecting
chamber for receiving vaporized fuel from the vapor collecting
chamber; a pressurizing air/water pump in fluid communication
with the molecule mixture box; an air intake structure in
fluid communication with the air/water pump for delivering air
through the air/water pump into the molecule mixture box; a
water source in fluid communication with the air/water pump
for delivering water through the air/water pump into the
molecule mixture box; and an air/water aerating mechanism
positioned to receive aerate and mix the air and water exiting
the air/water pump as the air and water enter the molecule
mixture box.

The fuel source is
optionally a fuel tank. The fuel vaporization and mixing
system preferably additionally includes a fuel blowing
mechanism mounted within the vapor collecting chamber for
stirring and uniformly distributing fuel vapor. The fuel
vaporization and mixing system preferably additionally
includes a spiral mixture delivery structure for guiding and
efficiently combining the mixture from the molecule mixture
box to an internal combustion engine.

The fuel
vaporization and mixing system preferably still additionally
includes a throttle mounting opening in the molecule mixture
box wall; and a throttle within the throttle mounting opening
having a throttle body for regulating the flow of air from the
surrounding atmosphere into the molecule mixture box. The
throttle preferably additionally includes an air filter
mounted to the throttle body to filter air entering the
throttle.

The water source
optionally is a water holding tank. The water source, the air
intake structure, the air/water pump and the air/water
aerating mechanism are placed in fluid communication with each
other through a tubular air/water fluid manifold. The fuel
blowing mechanism preferably includes a turbine blade
rotatably mounted within the vapor collecting chamber and a
turbine blade drive shaft onto which the turbine blade is
mounted extending through and sealingly abutting a port in the
vapor collecting chamber to a turbine drive motor located
outside the vapor collecting chamber and drivably connected to
the turbine blade drive shaft. The vapor collecting chamber
preferably has an upper portion and the molecule mixture box
preferably is in fluid communication with the upper portion of
the vapor collecting chamber, to receive fuel only in vapor
state.

The fuel
vaporization and mixing system preferably additionally
includes a fuel metering valve in fluid communication with the
fuel pump for metering the flow of fuel from the fuel source
into the vapor collecting chamber. The fuel source, the fuel
pump and the fuel metering valve preferably are in fluid
communication with each other through a segmented fuel line.
The fuel metering valve preferably is a flow control metering
valve.

A method is provided
of producing a mixture of fuel vapor, atomized water and air
and outside air for delivery into an internal combustion
engine, including the steps of delivering sufficient heat into
a quantity of fuel under less than atmospheric pressure to
transform the quantity of fuel into vaporized fuel; atomizing
water with air into a water mist; and mixing metered
quantities of the vaporized fuel and water mist with a metered
quantity of air to produce a highly combustible fuel mixture.
The method preferably includes the additional step of
delivering the fuel mixture into a spiral delivery tube
eventually into the head chamber of an internal combustion
engine.

An internal
combustion engine is provided with a fuel vaporization and
mixing system, including a fuel burning cylinder with a
cylinder head for receiving a fuel mixture from a mixture
delivery structure into the fuel burning cylinder; an engine
exhaust system; a fuel source for holding fuel prior to
vaporization; a fuel pump in fluid communication with the fuel
source for delivering fuel under less than atmospheric
pressure from the fuel source; a vapor collecting chamber in
fluid communication with fuel pump for holding a quantity of
fuel while the quantity of fuel is vaporized, the vapor
collecting chamber being in thermal communication with the
engine exhaust system to draw fuel vaporizing heat from the
exhaust system; a molecule mixture box having a box wall and
being in fluid communication with the vapor collecting chamber
for receiving vaporized fuel from the vapor collecting
chamber; a pressurizing air/water pump in fluid communication
with the molecule mixture box; an air intake structure in
fluid communication with the air/water pump for delivering air
through the air/water pump into the molecule mixture box; a
throttle body in fluid communication with the molecule mixture
box for delivering ambient air to the molecule mixture box in
the proper proportions to produce a highly combustible
mixture; a water source in fluid communication with the
air/water pump for delivering water through the air/water pump
into the molecule mixture box; an air/water aerating mechanism
positioned to receive aerate and mix the air and water exiting
the air/water pump as the air and water enter the molecule
mixture box and a spiral mixture delivery structure for
guiding the mixture from the molecule mixture box into the
fuel burning cylinder.

**BRIEF DESCRIPTION
OF THE DRAWINGS**

Various other
objects, advantages, and features of the invention will become
apparent to those skilled in the art from the following
discussion taken in conjunction with the following drawings,
in which:

**FIG. 1** is a
schematic of the inventive fuel vaporizing and mixing system
combined with an internal combustion engine.

![](fig1.jpg)

**FIG. 2** is a
close-up cross-sectional view of the spiral fins of the mixing
delivery means.

![](fig2.jpg)

**DETAILED
DESCRIPTION OF THE PREFERRED EMBODIMENTS**

As required,
detailed embodiments of the present invention are disclosed
herein; however, it is to be understood that the disclosed
embodiments are merely exemplary of the invention which may be
embodied in various forms. Therefore, specific structural and
functional details disclosed herein are not to be interpreted
as limiting, but merely as a basis for the claims and as a
representative basis for teaching one skilled in the art to
variously employ the present invention in virtually any
appropriately detailed structure.

Reference is now
made to the drawings, wherein like characteristics and
features of the present invention shown in the various FIGURES
are designated by the same reference numerals.

**First Preferred
Embodiment**

Referring to FIGS. 1
and 2, a fuel vaporization system 10 is disclosed for
producing a mixture of fuel vapor, atomized water and air for
delivery into an internal combustion engine I, the system 10
being configured and positioned relative to the internal
combustion engine I to draw heat from the engine exhaust
system E to vaporize fuel for combining into the mixture. The
fine atomization of the fuel resulting from the fuel
vaporization boosts higher fuel efficiency and causes the
engine I to produce significantly more horsepower. The system
10 includes a fuel tank 20 for holding fuel prior to
vaporization, a vacuum pump 14 or vacuum drawn off the intake
manifold of the engine with a check valve to hold and contain
less than atmospheric pressure in fuel tank 20, a fuel pump 30
in fluid communication with the fuel tank 20 for delivering
fuel from the fuel tank 20, a fuel metering valve 40 in fluid
communication with the fuel pump 30 for metering the flow of
fuel from the fuel tank 20, a vapor collecting chamber 50 in
fluid communication with the fuel metering valve 40 for
holding a quantity of fuel while the fuel quantity of fuel is
vaporized, the vapor collecting chamber 50 being in thermal
communication with the engine exhaust system E to draw fuel
vaporizing heat from the exhaust system E, vaporized fuel
blowing means 60 mounted within the vapor collecting chamber
50 for pushing and uniformly distributing the fuel vapor, a
molecule mixture box 70 in fluid communication with the vapor
collecting chamber 50 to receive vaporized fuel from the
chamber 50, with a throttle mounting opening 72 in the
molecule mixture box wall containing a throttle butterfly 74
having a throttle mechanism for regulating the flow of air
from the surrounding atmosphere into the molecule mixture box
70, an air filter 76 mounted above the throttle mounting
opening 72 to filter air entering the throttle 74, a
pressurizing air/water pump 80 in fluid communication with the
molecule mixture box 70, an air intake structure 90 in fluid
communication with the air/water pump 80 for delivering air
through the air/water pump 80 into the molecule mixture box
70, a water holding tank 110 in fluid communication with the
air/water pump 80 for delivering water through the air/water
pump 80 into the mixture box 70, an air/water injector 120
positioned to receive and transform the air and water exiting
the pump 80 into a fine mist spray as the air and water enter
the molecule mixture box 70, and a mixture delivery means 130
for guiding the mixture from the molecule mixture box 70 into
an intake manifold or port of an internal combustion engine I,
the mixture delivery means 130 including a passageway with
internal axially progressing spiral fins 132 for stirring the
mixture. The water holding tank 110, air intake structure 90,
air/water pump 80 and air/water injector 120 preferably are
placed in fluid communication with each other through a
tubular air/water fluid manifold 82. The fuel tank 20, fuel
pump 30 and fuel metering valve 40 preferably are placed in
fluid communication with each other through a segmented fuel
line 12. The vaporized fuel blowing means 60 preferably
includes a turbine blade 62 rotatably mounted within the vapor
collecting chamber 50 and a turbine blade drive shaft 64 onto
which the turbine blade 62 is mounted extending through and
sealingly abutting a port in the vapor collecting chamber 50
to a turbine drive motor 66 located outside the vapor
collecting chamber 50, to assure that no electric sparks
escape from the motor 66 into the chamber 50. The molecule
mixture box 70 is preferably in fluid communication with the
upper portion of the vapor collecting chamber 50, to receive
fuel only in its vaporized state. The fuel metering valve 40
preferably is a flow control needle valve. The internal
combustion engine I preferably includes a fuel burning
cylinder C with a cylinder head B through which the fuel
mixture is delivered by the spiral mixture delivery means 130
into the cylinder C, and the engine exhaust system E includes
an exhaust pipe P passing adjacent to the vapor collecting
chamber 50. The exhaust pipe P opens through an exhaust
release structure R into the surrounding atmosphere, and is
shown including a muffler M.

**Method**

In practicing the
invention, the following method may be used. The method
includes the steps of delivering sufficient heat into the fuel
to transform the fuel into vaporized fuel; atomizing water
with air into a water/air mist; mixing metered quantities of
the vaporized fuel and water/air mist with a metered quantity
of outside air to produce a volatile fuel mixture; and
delivering the volatile fuel mixture into a cylinder of an
internal combustion engine.

While the invention
has been described, disclosed, illustrated and shown in
various terms or certain embodiments or modifications which it
has assumed in practice, the scope of the invention is not
intended to be, nor should it be deemed to be, limited thereby
and such other modifications or embodiments as may be
suggested by the teachings herein are particularly reserved
especially as they fall within the breadth and scope of the
claims here appended.

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