The present invention relates to the technical field of combustion engines, and in particular to a method and system for evaluating the delivery and effectiveness of engine performance chemicals and products for reducing intake valve deposits for gasoline direct injection and port fuel injection engines.
Fuel injection refers to a system for admitting fuel into an internal combustion engine, and has become the primary fuel delivery system used in automotive engines, having replaced carburetors. The primary difference between carburetors and fuel injection is that fuel injection atomizes the fuel through a small nozzle under high pressure, while a carburetor relies on suction created by intake air accelerated through a Venturi tube to draw the fuel into the airstream. Modern fuel injection systems are designed specifically for the type of fuel being used. Some systems are designed for multiple grades of fuel (using sensors to adapt the tuning for the fuel currently used). Most fuel injection systems are for gasoline or diesel applications.
Benefits of fuel injection include smoother and more consistent transient throttle response, such as during quick throttle transitions, easier cold starting, more accurate adjustment to account for extremes of ambient temperatures and changes in air pressure, more stable idling, decreased maintenance needs, and better fuel efficiency. Fuel injection also dispenses with the need for a separate mechanical choke, which on carburetor-equipped vehicles must be adjusted as the engine warms up to normal temperature. Fuel injection systems are also able to operate normally regardless of orientation, whereas carburetors with floats are not able to operate upside down or in zero gravity, such as encountered on airplanes. Fuel injection generally increases engine fuel efficiency. Exhaust emissions are cleaner because the more precise and accurate fuel metering reduces the concentration of toxic combustion byproducts leaving the engine, and because exhaust cleanup devices such as the catalytic converter can be optimized to operate more efficiently since the exhaust is of consistent and predictable composition.
Gasoline direct injection (GDI) is a variant of fuel injection employed in modern two-stroke and four-stroke gasoline engines, where the gasoline is highly pressurized, and injected via a common rail fuel line directly into the combustion chamber of each cylinder as shown in
A problem encountered with fuel injection systems is the buildup of carbon deposits on the inlet side (top) of the intake valves. The deposits create turbulence and can restrict airflow into the cylinders causing performance and driveability problems including hesitation, stumbling, misfiring, and hard starting. The thicker the carbon deposit buildup on the valves, the worse the driveability problems. While many fuels have additives to clean intake valves these additives are ineffective for GDI based engines, since GDI sprays fuel directly into the combustion chamber, as shown in
Thus, there exists a need for a method and system for evaluating the delivery and effectiveness of engine performance chemicals and products for reducing intake valve deposits for gasoline direct injection and port fuel injection engines.
A method is provided for evaluating the delivery and effectiveness of engine performance chemicals and products for reducing intake valve deposits for gasoline direct injection and port fuel injection engines. Embodiments of the inventive engine evaluation tool provide the ability to repeatedly quantify the relative improvements between engine performance and maintenance products through a series of tests in a controlled environment with parameters that simulate intake valve and combustion chamber conditions of an engine. Non-limiting examples of test engine parameters available with embodiments of the invention illustratively include air fuel ratio, intake air flow, temperature of sample, oscillation frequency, presentation angle of replaceable sample, and product delivery method that includes throttle body upstream, port vacuum in plenum, and by fuel injector.
Embodiments of the inventive engine evaluation tool provide the ability to test multiple upstream manifold and port geometries. Non-limiting examples of test engine adjustable variables that may be controlled with embodiments of the invention include temperature range, oscillation frequency, air flow range/air-fuel ratio, and sample presentation angle range. In addition, embodiments of the invention provide programmable duty cycle logic. In a specific embodiment programmable duty cycles illustratively include idle, low speed, and full throttle. In specific inventive embodiments automated delivery controls for aerosol applications are provided.
A system is provided for the evaluation of the delivery and effectiveness of engine performance chemicals and products for reducing intake valve deposits for gasoline direct injection and port fuel injection engines.
The present invention is further detailed with respect to the following figures that depict various aspects of the present invention.
The present invention has utility as a method and system for evaluating the delivery and effectiveness of engine performance chemicals and products for reducing intake valve deposits for gasoline direct injection and port fuel injection engines. Embodiments of the inventive engine evaluation tool provide the ability to repeatedly quantify the relative improvements between engine performance and maintenance products through a series of tests in a controlled environment with parameters that simulate intake valve and combustion chamber conditions of an engine. Non-limiting examples of test engine parameters available with embodiments of the invention illustratively include air fuel ratio, intake air flow, temperature of sample, oscillation frequency, presentation angle of replaceable sample, and product delivery method that includes throttle body upstream, port vacuum in plenum, and by fuel injector.
Embodiments of the inventive engine evaluation tool may be implemented as a test stand that verify the efficiency of a particular additive in removing carbon deposits from a test specimen with pre-defined carbon content. Electrical controls are implemented in embodiments of the test stand to monitor and control system parameters illustratively including temperature, pressure, humidity, and proportions of fuel, air, additive mixture, etc. In embodiments of the invention the test stand may be configured with a graphical user interface (GUI) and user controls to configure or monitor system parameters.
It is to be understood that in instances where a range of values are provided that the range is intended to encompass not only the end point values of the range but also intermediate values of the range as explicitly being included within the range and varying by the last significant figure of the range. By way of example, a recited range of from 1 to 4 is intended to include 1-2, 1-3, 2-4, 3-4, and 1-4.
Embodiments of the inventive engine evaluation tool provide the ability to test multiple upstream manifold and port geometries. In a specific embodiment the primary air/fuel charge delivery angle may be set between 90° to horizontal as shown in
Embodiments of the inventive engine evaluation tool primarily use three approaches to introduce cleaners for reducing intake valve deposits for gasoline direct injection and port fuel injection engines. In a first approach, a cleaner is added into an airstream as the airstream enters the intake and flows through the air duct and past the test surface to effect cleaning. In this first approach the cleaner may be added by aspiration, pump sprayer, aerosol propellant, compressed gas, or other means to atomize or disperse the cleaning fluid. The first approach is equivalent to those commonly used to service an actual engine with an aerosol spray carburetor or throttle body cleaner. The second approach is to add a cleaning fluid by suction into an air duct, which may be done by introducing a tube between a vented container of cleaning fluid and the airstream within the air duct. The resulting vacuum will draw fluid into the duct and distribute it over the test specimen, potentially cleaning the surface. The equivalent of the second approach to an actual engine service is the vacuum intake cleaner commonly used for retail fuel system services. The third approach is to add detergent to the fuel itself which is then sprayed onto the test surface to effect cleaning. The equivalent to the third approach commonly used by consumers is a pour-in fuel additive added to a tank of fuel to enhance deposit cleaning. The first two approaches to introducing a cleaner are applicable to both engines using traditional port fuel injectors and newer direct injector system, while the third approach is applicable only to engines with port fuel injectors.
A test piece (carbon deposited valve) is placed in test stand, and heated up to a temperature of 200° C. with a temperature test range of −75° C. to 200° C. with a step size of 10° C. and subject to to-fro motion at 2500 revolutions per minute (RPM). A mixture of air, additive, and fuel is supplied through inlet runners into the chamber where the valve is held. The valve should not be disturbed at any point of time during temperature measurement or heating. Heating of the valve may be accomplished with a thin film heater source as shown in
Fuel prior to use in test set up injector is “dirty-upped” by using untreated fuel that tends to build deposits on the valve.
A dirty-up process for fuel injected into test set up using engine oil aspirated through the injector, potentially mixed with fuel at a concentration ranging from 0% to 100%.
The engine oil may be previously used or treated so that it contains suspended carbon and other contaminants that may contribute to valve deposits.
The foregoing description is illustrative of particular embodiments of the invention, but is not meant to be a limitation upon the practice thereof. The following claims, including all equivalents thereof, are intended to define the scope of the invention.
This application claims priority of provisional application Ser. No. 62/245,780 filed 23 Oct. 2015, the contents of which are hereby incorporated by reference.
Number | Date | Country | |
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62245780 | Oct 2015 | US |