For today's engines that are not of the old "steel piston" design 16% to 18% oil is the premium amount of oil based on testing by Wildcat and independent analysis of Wildcat Fuels by many engine manufacturers. Wildcat Premium and Premium Xtra is designed for maximum engine life and performance.

 

THE 2-CYCLE PRINCIPLE


The two steps (strokes) in a complete power cycle of a 2-stroke-cycle engine.

CLICK HERE FOR A COMPARISON OF 2 STROKE AND 4 STROKE ENGINES

[ A ]  The crankshaft has rotated away from bottom dead center (BDC), moving the piston toward the cylinder head and closing the transfer and exhaust ports. Trapped above the piston is the air fuel charge inducted from the previous cycle. Below the piston, the rotary disk has started to uncover the induction port that leads to the carburetor and the outside atmosphere.  Because the volume of the crankcase beneath the piston is increasing, its pressure relative to the outside air is decreasing. This pressure differential causes outside air to rush into the carburetor where it mixes with available fuel before continuing through the induction port and rotary disk, into the crankcase.

[ B ]  As the piston nears top dead center (TDC) on the secondary compression operation, the air fuel mixture reaches the ignition point. Ignition is achieved by the heating effect of compression and the heat retained by the glow plug element from the previous cycle, among other things.  Combustion occurs between the top of the piston and the cylinder head. This volume is known as the combustion chamber. As combustion progresses and the gas increases, pressure rises proportionally. The momentum of the rotating engine components carries the piston beyond TDC in the direction of crankshaft rotation. The rotary disk is almost closed as pressure caused by combustion (several 100 pounds per square inch), drives the piston away from the cylinder head on the power event.

[ C ]  Diagram C shows the piston moving to a point at which the power (or expansion) event has just ended with the opening of the exhaust port. The period of crankshaft rotation necessary to move the piston from exhaust opening to transfer opening is called exhaust lead. Exhaust lead is necessary in most engines to provide time for the relatively high exhaust-gas pressure to blow down to atmospheric pressure. If exhaust lead were eliminated, exhaust gas would probably back-flow through the transfer port, contaminating the cool, fresh air-fuel mixture in the crankcase. Notice that the rotary disk valve is still closed, allowing the descending piston to continue compressing the fresh air-fuel mixture in the crankcase (primary compression), as it awaits the opening of the transfer port.

[ D ]  Diagram D depicts the exhaust and transfer ports open, with cylinder and crankcase
scavenging taking place. The previously compressed fresh air-fuel mixture is flowing through the bypass channel and transfer port-chasing the tail-end exhaust gases out of the exhaust port.