The present invention is directed to a system for use with a reciprocating engine and, more particularly, to an enhanced fuel delivery system for use with a reciprocating engine that is effective for improving fuel usage.
Standard reciprocating engines, such as internal combustion engines, rely upon a pressure differential to move a fuel/air mixture into a combustion chamber associated with each engine cylinder. During an intake stroke of a piston of a conventional engine, the piston recedes in the cylinder bore and an inlet valve is simultaneously opened at the inlet port to admit the fuel/air mixture. A receding piston creates a partial vacuum in the combustion chamber and throughout the intake manifold. This vacuum operates to draw air through into the combustion chamber were a fuel injector system (or carburetor system) operates to spray liquid fuel droplets into the air to create a misty fuel/air mixture.
The nature and quality of the combustion of the liquid fuel and air mixture in the combustion chamber depends on numerous factors. One of the most significant of these factors is the degree to which the liquid fuel droplets released by the fuel injectors (or carburetor) are atomized and vaporized on their way to or within the combustion chamber. Ideally, the fuel/air mixture in the combustion chamber should be in a gaseous state. However, this is not currently achievable in conventional internal combustion engines. Accordingly, fuel in a liquid state, is typically suspended in the combustion chamber as a mist or droplets, and will often not ignite. Such un-vaporized fuel that does not burn completely during the combustion stroke of the cylinders is then expelled into the engine exhaust system where it continues to burn, heating the engine and requiring surplus pollution control devices or it is vaporized and exhausted into the atmosphere thereby wasting fuel and adds to air pollution.
Accordingly, it would be desirable to have a system whereby fuel can be stored in its liquid state and converted into a vapor state prior to being introduced into the combustion chamber of a reciprocating engine thereby increasing combustion efficiency and reducing fuel consumption and air pollution.
The subject invention is to an enhanced fuel delivery system for use with a reciprocating engine that is effective for improving fuel usage and reducing air pollution. The system comprises a fuel storage container for providing and storing a quantity of liquid fuel, a vaporization vessel connected to the fuel storage container through a fuel supply channel that operates to transfer liquid fuel stored in the fuel storage container to flow into the vaporization vessel. The vaporization vessel includes a central core structure and wicking material, whereby the wicking material operates to draw the liquid fuel entering the vaporization vessel to spread the liquid fuel to increase the surface area of the fuel exposed to air within the vaporization vessel thereby transforming the liquid fuel into vapor. The vapor is then directed through one or more openings in the central core structure to an inner core passage and out to a fuel line that operates to direct the vapor to a fuel intake of the reciprocating engine.
In a preferred embodiment of the invention, the vaporization vessel has an upper vessel component, a bottom vessel end and a vaporization body having an outer vessel surface and an inner vessel surface and extends longitudinally from the top component to the bottom vessel end wall that together define an enclosed inner cavity. The top component includes a plurality of apertures that operate to direct air from outside the vaporization vessel (“atmospheric air”) to enter the enclosed inner cavity. The inner vessel surface of the vaporization body has a smooth continuous rounded configuration such that it is effective for maintaining a smooth air flow (laminar air flow) within the enclosed inner cavity (or minimizing the amount of turbulent air flow within the enclosed inner cavity).
In a preferred embodiment of the invention the plurality of apertures formed along the upper vessel component are formed in a circular pattern along the upper vessel component and each are angled to direct the atmospheric air in a circular downward laminar air flow within the enclosed inner cavity.
In a preferred embodiment of the invention the plurality of apertures are angled about 10 degrees that operate to direct air flow along the inner vessel surface to promote a downward laminar air flow within the enclosed inner cavity.
In a preferred embodiment of the invention the plurality of apertures each have an inner diameter of about 0.093 in. (2.36 mm).
In a preferred embodiment of the invention the inner vessel surface of the vaporization body has a circular cross section.
In a preferred embodiment of the invention, the vaporization vessel and the fuel storage container are formed from a material suitable for use with liquid fuel, such as, but not limited to a high-density polyethylene, or steel, aluminum or brass.
In a preferred embodiment of the invention the wicking material is formed from a material operates to draw liquid fuel through the wicking material using capillary action to spread the liquid fuel (increase the amount of surface area of the liquid fuel exposed to air within the inner cavity) and increase the rate of vaporization of the liquid fuel.
In a preferred embodiment of the invention the wicking material is formed from a material resistant to decomposition or deterioration by the liquid fuel and operates when in contact with the liquid fuel to draw the liquid fuel using capillary action through the wicking material to increase the rate of vaporization of the liquid fuel.
In a preferred embodiment of the invention the wicking material is formed from conventional fuel filter paper.
In another preferred embodiment of the invention the wicking material is formed from fuel filter material made from a mixture of hardwood and softwood.
In another preferred embodiment of the invention the wicking material is formed from conventional automotive engine paper air filter material.
In a preferred embodiment of the invention the vaporization vessel includes a warm air inlet that operates to direct external warm air (air from outside the vaporization vessel) into the enclosed inner cavity of the vaporization vessel.
In preferred embodiment of the invention the warm air inlet operates to direct warm air entering into the enclosed inner cavity in a downward circular direction thereby increasing the rate of the vaporization of the liquid fuel.
In a preferred embodiment of the invention the fuel supply channel has an inner diameter of about 0.040 to about 0.062 in (1.016 mm-1.575 mm).
Another preferred embodiment of the invention is an enhanced fuel delivery system for use with a reciprocating engine that is effective for improving fuel usage, the system comprises a fuel storage container for storing a volume of liquid fuel; a vaporization vessel connected to the fuel storage container through a fuel supply channel that operates to direct liquid fuel from the fuel storage container to the vaporization vessel; wherein the vaporization vessel has a upper vessel component, a bottom vessel end and a vessel body having an inner vessel surface that together define an enclosed inner cavity. The enclosed inner cavity contains a central core structure with one or more openings and wicking material positioned around the central core structure. The wicking material is formed from a material that operates to draw liquid fuel entering the vaporization vessel through the fuel supply channel using capillary action such that the liquid fuel is vaporized transforming the liquid fuel into vapor. The fuel vapor is then directed through the one or more openings in the central core to an inner core passage and to a fuel line that operates to direct the fuel vapor to a fuel intake of the reciprocating engine. The upper vessel component of the vaporization vessel includes a plurality of apertures that operate to direct air from outside the vaporization vessel into the enclosed inner cavity and wherein the plurality of apertures are each angled to produce a downward air flow within the enclosed inner cavity. The inner vessel surface of the vessel body has a smooth continuous rounded configuration that is effective for maintaining laminar air flow within the enclosed inner cavity (minimizing turbulent air flow within the enclosed inner cavity).
Another preferred embodiment of the invention is a reciprocating engine having an enhanced fuel deliver system comprising a fuel storage container for containing and storing a quantity of liquid fuel, a vaporization vessel connected to the storage container through a fuel supply channel that operates to direct liquid fuel from the fuel storage container to the vaporization vessel, wherein the vaporization vessel has a central core structure and wicking material positioned around the central core structure. The wicking material operates to draw the liquid fuel entering the vaporization vessel through the wicking material by capillary action to transform the liquid fuel into vapor and whereby the fuel vapor is directed through one or more openings in the central core structure to an inner core passage to a fuel line that operates to direct the vapor to a fuel intake of the reciprocating engine.
Another preferred embodiment of the invention is an article comprising a reciprocating engine and an enhanced fuel deliver system, the enhanced fuel delivery system having a fuel storage container for storing a quantity of liquid fuel, a vaporization vessel connected to the fuel storage container through a fuel supply channel that operates to direct liquid fuel to flow through the fuel supply channel from the fuel storage container into the vaporization vessel. The vaporization vessel includes a central core structure and wicking material positioned around the central core structure that operates to draw liquid fuel entering the vaporization vessel through the wicking material by capillary action to transform the liquid fuel into vapor. The fuel vapor is directed through one or more openings in the central core structure to a inner core passage to a fuel line that operates to direct the fuel vapor to a fuel intake of the reciprocating engine.
Other objects, advantages and embodiments of the invention will be apparent from the following description, drawings and the appended claims.
To provide a more complete understanding of the present invention and further features and advantages thereof, reference is now made to the following description taken in conjunction with the accompanying drawings, in which:
The present invention relates to an article having a reciprocating engine and, more particularly, to a new and novel enhanced fuel delivery system for use with a reciprocating engine. As used herein, the term “liquid fuel” refers to liquid fuels typically used with conventional reciprocating engines, such as gasoline, kerosene and other fuels having volatility sufficient to allow vaporization of the fuel as described below. It should be understood that as used herein “reciprocating engines” include various conventional internal combustion engines such as those used as portable engines for small electrical generators, home equipment such as lawn mowers, trimmers, cutting tools, and the like; and for use for small recreational vehicles such as small motorized vehicles, scooters, snowmobiles, outboard boat engines, and the like. In describing the preferred embodiments of the invention and as illustrated in the drawings, specific terminology will be resorted to for the sake of clarity. However, the invention is not intended to be limited to the specific terms so selected, and it is to be understood that each specific term includes all technical equivalents that operate in a similar manner to accomplish a similar purpose. It should be understood however that as used herein reciprocating engines do not include engines, such as conventional diesel engines, that require controlled ignition to minimize simultaneous combustion of the entire fuel spray immediately upon entry of the fuel in a cylinder unless systems are used to provide proper combustion within the combustion chamber.
As illustrated in
Referring to
The container inner body surface 112 of the fuel storage container 102 preferably has a circular cross section with a container upper portion 120 of the top end 108 having an upper portion inner diameter CDU and a container lower portion 122 having a slightly smaller lower portion inner diameter CDL than that the container upper portion 120. In a preferred embodiment, the container upper portion inner diameter CDU of the container inner body surface 112 has a diameter of about 2.625 in (63.5 mm) and the container lower portion 122 has a lower portion diameter CDL of about 2.5 in. (63.5 mm). As shown, in
As shown in
Positioned within the enclosed inner cavity 168 of the vaporization vessel 104 is a longitudinally extending central core structure 164 and wicking material 166 concentrically spaced around the central core structure 164. The central core structure 164 includes an inner core passage 168 with one or more openings 170 that extend from the enclosed inner cavity 158 to the inner core passage 168. As shown, the inner core passage 168 extends outwardly through the bottom vessel end 156 and connects to the fuel line 16 of the reciprocating engine 12. In a preferred embodiment of the invention the wicking material is formed from conventional fuel filter paper. In another preferred embodiment of the invention, the wicking material is formed from fuel filter material made from a mixture of hardwood and softwood. In another preferred embodiment of the invention the wicking material is formed from conventional automotive engine paper air filter material. It should be understood that other materials that are resistant to deterioration caused by exposure to liquid fuel and operate to draw the liquid fuel through the wicking material by capillary action to increase the surface area of the liquid fuel to air within the enclosed inner cavity thereby increasing the rate of vaporization of the liquid fuel can be utilized.
The inner vessel surface 152 of the vaporization vessel 104 preferably has a circular cross section with a vessel body upper end 184 having a vessel inner diameter VDU and a vessel body lower end 162 having a slightly smaller inner vessel diameter VDL than that the vessel body upper end 184. In a preferred embodiment, the vessel inner diameter VDU of the vessel body upper end 184 has a diameter of about 2625 in. (66.675 mm) and the vessel body lower end 162 has a diameter VDL of about 2.5 in or 63.5 mm). In a preferred embodiment of the invention the upper vessel component 154 includes an upper section 172 having an upper section top surface 174 and a lower section top surface 176 with a circular vessel stem portion 178 integral with and extending perpendicularly downwardly from the lower section top surface 174. The vessel stem portion 178 has one or more fuel resistant vessel O-rings 180 concentrically mounted along the outer vessel stem surface 182 of the circular vessel stem portion 178 and which are sized to nest within the upper section 172 of the vessel body upper end 184 against a vessel rim 183 formed between the vessel body upper end 184 and the vessel body lower end 162 to provide a removable frictional tight seal for preventing fuel or fuel vapor from leaking out from the vessel body upper end 184 of the vaporization vessel 104. It should be understood that other systems for removably attaching the upper vessel component to vaporization body 148 can be utilized, such as by screw threads projecting concentrically outwardly from the outer vessel stem surface of the vessel stem portion that operate to mate with corresponding inwardly projecting screw threads positioned along the inner vessel surface of the vessel body upper end for releasably securing the upper vessel component to the vessel body upper end.
Referring to
As shown in
Referring to
In a preferred embodiment of the invention, the fuel storage container 102 and the vaporization vessel 104 include a mounting brace 192 having one or more threaded holes 194 that can be placed in position to align with holes in a support structure (not shown) for receiving a screw, bolt or the like for securing attaching the enhanced fuel delivery system 100 to the article or to the reciprocating engine. It should be understood that the enhanced fuel delivery system of the subject invention can include various other attachment and support structures that can operate to position the enhanced fuel delivery system at various locations on the article or the engine structure.
Referring to
It should now be apparent to one skilled in the art that an article having a reciprocating engine and the enhanced fuel delivery system of the subject invention operates whereby fuel can be stored in its liquid state and converted into a vapor state prior to being introduced into the combustion chamber of the reciprocating engine thereby increasing combustion efficiency and reducing fuel consumption and air pollution. It should also now be understood that the enhanced fuel delivery system can be easily utilized for use with small apparatus having reciprocating engines, such as emergency generators, that operate in limited space. By transforming the liquid fuel into a vapor and mixing the fuel vapor with the appropriate amount of air to create a desired fuel/air vapor mixture, operates to increase fuel utilization of the engine thereby allowing for a reduced amount of fuel to be stored or allows for increased time of operation of the engine for a given amount of stored liquid fuel. Further, by transforming the fuel from a liquid state to a vapor state and creating a desired fuel/air mixture allows for more efficient combustion thereby reducing the amount of un-burned fuel and pollutants that are expelled into the atmosphere.
Number | Name | Date | Kind |
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1067582 | Maxim | Jul 1913 | A |
4246878 | Tuzson | Jan 1981 | A |
4469075 | Jackson | Sep 1984 | A |
5427077 | Gilbert | Jun 1995 | A |
7942644 | Young | May 2011 | B2 |
20100021855 | Requejo | Jan 2010 | A1 |
Number | Date | Country |
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475335 | May 1915 | FR |
60144513 | Jul 1985 | JP |