HomeShop by ProductOther ProductsCleaners and Protectants Save up to 25% or Product Highlights View Full Description Improves engine performance by removing gum, varnish and carbon deposits that affect power, operation, idle and fuel economy. Power Foam cleans intake valves, intake manifolds and throttle plates to keep the combustion intake system running at peak efficiency. Helps reduce engine ping and keeps carburetors and injector systems operating like new. **NOT AVAILABLE IN CANADA**NOT AVAILABLE IN CALIFORNIAAMSOIL Power Foam® (APF) improves engine performance by removing gum, varnish and carbon deposits that affect power, operation, idle and fuel economy. Effective in both two-cycle and four-cycle gasoline engines, AMSOIL Power Foam helps reduce engine ping and keeps carburetors and injector systems operating like new. Power Foam is safe for fuel injectors, catalytic converters and emission control devices. It will not damage seals, gaskets, rubber or plastic materials commonly used in gasoline engines.

Performance FeaturesCleans deposits from ethanol and degraded fuelRemoves gum and varnishMaximizes horsepowerRestores startabilityHelps improve fuel economyReduces pollutionApplicationsUTVs/ATVsBoatsMotorcyclesLawn EquipmentTractorsAutomobilesDirectionsProtect painted surfaces and mass airflow sensors (MAF) from spray.Ensure application is in a well-ventilated area.Run engine to normal operating temperature and remove air cleaner assembly.While engine is running, spray foam directly into throttle body as fast as possible without stalling engine.Shut off engine and allow to sit for 10-15 minutes.Repeat application of Power Foam as needed.In extreme cases, disassemble carburetor and soak parts.RecommendationsAvoid contact with hoses and exterior plastic components. To prevent the dissolving of paint, do not overspray. AMSOIL Power Foam is not recommended for use in diesel engines or as a general purpose degreaser.AMSOIL PRODUCT AVAILABILITYAMSOIL Power Foam is available in 18-ounce spray cans.

AMSOIL products are backed by a Limited Liability Warranty. This product is not expected to cause health concerns when used for the intended applications and according to the recommendations in the Safety Data Sheet (SDS). An SDS is available or upon request at (715) 392-7101. Keep Out of Reach of Children. Recycle used oil and bottle. For More Technical Information, click here to download the product data bulletinMisfire codes, stumbling and suspicious fuel trim numbers. On a scan tool, the engine may show a loss in volumetric efficiency. The driver may complain about a loss of power, poor fuel economy and hard starts. Carbon deposits on the intake valves. Deposits cause the air to tumble into the combustion chamber, and this turbulence causes the air/fuel mixture to be unevenly distributed. When ignited, the flame front can be erratic, leave unburned fuel and create hot spots in the combustion chamber. When the early direct-injection engines hit the three-year or 30,000-mile mark, some developed driveablity problems due to carbon buildup on the necks of the intake valves.

In the late ‘90s and early 2000s, TSBs related to carbon deposits on the valves were few and far between. air cleaners for woodworkingThere are three reasons why direct-injection engines are more prone to carbon deposits, one of which is unique to direct injection, while the remaining two are also problems for port fuel injection but are made worse by direct injection.air screen seed cleaner The main reason is that fuel and added detergents are not hitting the back of the intake valves. best spray carpet cleaner for pet stainsBy injecting the fuel directly into the cylinder instead of at the back of the valve, the gasoline and detergents can’t clean the valve and port. Second, leaner mixtures and higher combustion pressures can make the problem worse over time.

A direct fuel injection motor produces more energy from a given amount of fuel and air than a port fuel injection engine. Today’s engines operate on a ragged edge between optimal efficiency and a misfire. There is not much room for error, like hot spots in the combustion chamber or a worn spark plug. When a hot spot or sub-optimal flame front is created due to turbulent air, the amount of unburned fuel in the combustion chamber increases. When the valve opens during the intake stroke, it might come in contact with these byproducts, and, unlike the exhaust valve, the gases passing by are not hot enough to burn them off. Third, the intake valve goes into the combustion chamber, regardless of whether it is port fuel injected or direct injected. When it does, for that small period of time, the valve is exposed to combustion byproducts that can stick to its neck. If the previous combustion cycle was less than optimal, the intake valve is exposed. Some direct-injection vehicles with variable valve timing can expose the valve to combustion byproducts as the valves adjust, which creates a scavenging effect to either pull or leave behind a small amount of exhaust gases in the chamber to control NOX emissions.

Also, some turbocharged direct-injection engines will leave the intake and exhaust valves open at the same time in order to keep the turbo spinning to reduce lag. Problem Vehicles: Some direct-injection engines have bad timing. The modern engine typically has variable valve timing and even cylinder deactivation. The engine management system can control when, how long and, in some cases, how deep the valve goes into the combustion chamber. If an intake valve is dropping into a combustion chamber with combustion byproducts or unburned fuel, the valve might be exposed to the precursors that cause carbon buildup. Positive crankcase ventilation (PCV) systems are sometimes blamed for leaving an oily film on the intake valve that is then baked into carbon. Some blame the valve overlap during the intake stroke that eliminates the need for an EGR valve. Some even have cited cylinder deactivation modes that can create positive pressure. There are several fixes available to solve carbon buildup problems.

The first is preventive maintenance. Scheduled oil changes can keep the camshaft actuators working in optimal condition to control the exposure of the intake valves. Spark plug replacement can reduce the amount of unburned fuel in the combustion chamber that can stick to a valve. Fuel injector cleaning can help injectors maintain the correct spray geometry to prevent hot spots. But the number one method for preventing a carbon buildup problem is updating the engine management software. New software can reduce carbon deposits by reducing the exposure of the valves to conditions that cause carbon buildup by adjusting valve and spark timing. Don’t assume that you will find a TSB saying that a reflash of the ECM will correct a carbon buildup problem because most of the updates will be contained in normal housekeeping that may never mention a problem. You may even have to check the OEM’s website to see if the vehicle has the latest version of the software. If the vehicle has reached the point where the deposits are affecting performance, you might be able to remove the deposits with a chemical cleaner injected into the intake.