The purpose of this invention is to produce a fuel igniter adapted as a spark plug and a glow plug in common usage terms, that is configured to be the receptacle of the fuel injector. It makes direct fuel injection more feasible for all internal combustion engines, past, present, and future; and more cost effective. It also enables both igniter and fuel injector to be sited in the center of the combustion chamber, to provide the most complete fuel burn. Additionally, it makes possible the siting of two or three necessary devices of the ignition process, to one location.
1. Field of the Invention
The field of this invention resides in the category of delivery of an igniter element, into the combustion chamber of an internal combustion engine. The igniter element may be a spark produced by a spark plug in gasoline engines, or heat produced by a glow plug in diesel, engines. A device is inserted into the combustion chamber, to initiate the burning sequence of the surrounding air and fuel mixture.
2. History of the Prior Art.
There have been many designs of spark plugs over the years. One that relates to this device is a U.S. publication #2005/0040749A1, of an invention by Maurice E. Lindsay of El Segundo, Calif., U.S.A. Of necessity, an aperture must be made into the walls of the combustion chamber to allow this igniter to have access to the air and fuel mixture. Early in the prior art, carburetors were used to accomplish the air and fuel mixing according to a stoichometric ratio of 15:1 air and fuel. Carburetors were positioned at a distance from the combustion chamber. Later, fuel injectors replaced carburetors, but were also positioned at some distance away from the combustion chamber in the intake manifold runner, or in the intake port. The spark plug remained in the combustion chamber.
The adoption of direct fuel injection now sites the fuel injector in the combustion chamber and not in the intake manifold runner or port. Therefore it has become necessary to find a suitable locus for the fuel injector in a combustion chamber. The combustion chamber in many modern designs, is filled with multiple poppet valve heads. Characteristically, the locus must allow the provision of a site for an additional aperture, preferably in the center of the chamber, for insertion of the fuel injector; in addition to the site for the igniter. This necessitates two apertures into more specifically, the top or roof of the already crowded combustion chamber. One or both of these apertures may be threaded. This adds expense as well as spatial compromise to the utilization of direct fuel injection technology. This feature is also typical of compression ignition internal combustion engines or diesels, with the exception that the igniter is adapted to be a glow plug.
This invention is made to address this conundrum by necessitating as is typical of internal combustion engines, only one aperture into the combustion chamber, even with the use of direct fuel injection.
The present invention resides in an igniter adapted to be a spark plug and a glow plug, housing the fuel injector within its body. It enables the injector to access the combustion chamber of an internal combustion engine, through a single aperture that is providing an access for the spark plug or glow plug. The body of the spark plug is constructed as an elongated tubular housing having, defined within it's center, an aperture along a longitudinal axis. This aperture extends from a polygonal shaped top, to the base of the body, and in a preferred embodiment, may be threaded. Within this aperture the fuel injector is sited. Encircling the aperture, is defined a groove or a channel within the body, in which is an electrode embedded in an insulator. Both also project along a longitudinal axis. This electrode defines a terminal at the polygonal shaped top, from which it projects, through a longitudinal tubular channel, to prongs at the base of the body. These prongs may be constructed to be in close proximity to the inner housing wall around the central chamber, or in an additional embodiment, to be directed towards the outer peripheral threaded housing wall. This electrode is insulated from the body, which is grounded. In typical use this electrode, carries a positive electrical charge when energized. In spark plugs, this charge jumps an air gap, towards the housing wall, creating a spark in the combustion chamber.
It is an accepted principle in the technology of internal combustion engines, that the center of the combustion chamber is the ideal location for the spark plug. It is also the ideal location for the fuel injector, but the prior art has never been able to demonstrate this fact, due to a simple statement of physics; until this invention. The benefits of direct fuel injection are further improved by this invention, resulting in additional gains in fuel efficiency, horsepower and torque.
An advantage of this invention, is that the coil and the fuel injector which were sited at varying positions, can now be assembled in unit with the spark plug, at the location of the aperture in the cylinder head into the combustion chamber.
A further advantage of this invention is that the two distinct electrical circuits needed to activate the fuel injector and the coils and park plug complex, are reduced to one. The current that activates the fuel injector, also activates the coil to discharge it's amplified, stored electrical energy to the spark plug in a sequence.
The advantages listed in [0007] also applies to compression ignition or diesel internal combustion engines, that utilize a glow plug. In this configuration, no coil is used. combustion engines, that utilize a glow plug. In this configuration, no coil is used.
The above, as well as other features and advantages of the present invention will become apparent from the following more detailed description and accompanying drawings. These illustrate the principles of the invention, as an example.
100 injector
101 coil
102 cylinder head
103 combustion chamber
104 combustion chamber contents
Shown in
A central aperture 16 for the receipt of the fuel injector is defined in the surface of the polygonal top 14 of the igniter 09 and opens into a central chamber 20 disposed along a longitudinal axis to an end at the base 18. The central chamber 20 may have a series of screw threads 21 defined in the surface that extend from the central aperture 16 along the longitudinal axis to an end at the fuel injector receipt ledge 22 and is the preferred embodiment.
In
Operation—
The igniter 09 embodied in my invention described in this application, is adapted as a spark plug. It functions to accomplish the same task as the current spark plug, used in direct fuel injection into the combustion chamber 103 of internal combustion engines. It is threadably inserted into the screw threads in the spark plug receipt aperture in the cylinder head 102 of the engine, engaging screw threads 17. A suitable tool grasping around the periphery of the polygonal top 14 pivots it. The plug moves through the aperture and is pivoted to a stop with circular lip member 25 as in
This embodiment of my invention of an igniter 09, is adapted as a glow plug. It functions to accomplish the same task as the current glow plug used in the combustion chamber of a compression ignition engine. An electrical current from a source such as a battery, is activated by a switch, and transmitted to the igniter to contact terminal 13a or 13b. The electrical current is transmitted or conducted through the electrode 13 to the rings 30 embedded in the insulator 15 in the base 18. The rings 30 spiral around the central chamber 20, creating a heating element, and are attached to the grounded inner housing wall 12. The electrical current activates the rings 30 to heat and ignite the fuel sprayed into the combustion chamber by the fuel injector located in the central chamber 20. The electrical current to the igniter is switched off, and combustion is thereafter sustained by a cycle of compression of air and fuel mixtures.
Conclusion, Ramifications And Scope.
Accordingly, the reader will see that the igniters in the various embodiments presented in the specification, and illustrations, have many advantages over the devices of the prior art. Their use allows the two or three devices of the ignition process, to be relocated to a discrete site, in the most beneficial locale; the entrance to the combustion chamber, and at its center. They solve the issue of spatial compromise, in the design of the combustion chamber, resulting in increased fuel efficiency, increased horsepower and torque. In addition, they reduce the increased cost of adopting direct fuel injection, by reducing the manufacturing costs involved in drilling another aperture and tapping it. Also, they reduce the electrical hardware and the manufacturing costs of electronic control modules, by requiring only one electrical pathway for activating the fuel injector and the coil. The prior art requires two pathways; one to the fuel injector and another to the coil. There are further benefits permitted by the use of multiple prongs. They provide multiple spark presentations, that are most compatible with the reduced amperage of current ignition systems. The results are reliable, stable and durable ignition. The benefits of direct fuel injection, some of which are well demonstrated in compression ignition engines, are now available with enhancements. These can be fitted to past, present and future internal combustion engines, having a single aperture through the cylinder head, into the combustion chamber.
Although the present invention has been described with reference to particular embodiments, it will be apparent to those skilled in the art, that variations and modifications can be substituted therefor without departing from the principles and spirit of the invention, or limiting it's scope. Thus the scope of the embodiments should be determined by the appended claims and their legal equivalents, rather than by the examples given.
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Number | Date | Country | |
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