| 摘要 |
A “two-cycle” internal combustion engine has a single or multi-stage pre-cooled compression, which allows the temperature and pressure of intake air to the combustion cylinders to be tightly controlled, so that a much higher compression ratio and pre-ignition compression pressure can be achieved without approaching the auto-ignition threshold. Because this design can effectively regulate and set the maximum pre-ignition temperature of the fuel-air mixture, it can combust virtually any type of liquid hydrocarbon fuel without knocking. This “two-cycle” engine, due to its higher compression ratio, generates power equivalent to or greater than a four-cycle “CWPSC” engine in a smaller and lighter engine and at the same or higher efficiency. |
| 主权项 |
1. A “two-cycle” spark ignition internal combustion engine that has the functionality of a four-cycle combustion engine, comprising:
one or more combustion cylinders, each cylinder having a total cylinder volume, an intake volume, a top dead center (TDC) and a bottom dead center (BDC), and each cylinder having one or more intake valves and one or more exhaust valves, and each cylinder containing an axially reciprocating piston mechanically connected to a crankshaft and a flywheel, wherein the crankshaft, the intake valves and the exhaust valves are configured and controlled so that each cylinder executes a two-cycle combustion process, comprising an expansion cycle, during which the intake valves and the exhaust valves are closed and during which the piston moves through a first crankshaft angle interval axially toward the BDC of the cylinder without reaching the BDC, followed by an exhaust cycle, during which the intake valves remain closed and the exhaust valves are opened and during which the piston continues moving axially toward the BDC until the piston reaches the BDC, and then moves through a second crankshaft angle interval axially toward the TDC of the cylinder and drives a portion of an exhaust gas out of the cylinder, followed by a combined exhaust-intake cycle, during which the intake valves are opened and the exhaust valves remain opened and during which the piston continues moving axially toward the TDC of the cylinder through a third crankshaft angle interval and during which pressurized intake air is forced into the cylinder through the opened intake valves to expel a remainder of the exhaust gas through the opened exhaust valves, followed by an intake cycle, during which the intake valves remain opened and the exhaust valves are closed and during which a pressurized intake volume of an air-fuel mixture is forced into the cylinder through the opened intake valves, while the piston moves axially through a fourth crankshaft angle interval toward the TDC, followed by a compression cycle, during which the intake valves are closed and the exhaust valves remain closed and during which the piston continues to move axially toward the TDC of the cylinder through a fifth crankshaft angle interval and compresses the air-fuel mixture to a pre-ignition compression volume, a pre-ignition compression pressure, and a pre-ignition compression temperature, followed by a spark ignition of the air-fuel mixture, which drives the piston toward the BDC of the cylinder in a next expansion cycle, followed by a next exhaust cycle, and wherein a ratio of the intake volume to the pre-ignition compression volume defines an effective compression ratio; one or more pre-stage air compressors, each compressor connected to the crankshaft, and each compressor having a compressor air volume, wherein the crankshaft is configured and controlled so that each compressor compresses the compressor air volume of ambient air at an atmospheric pressure and at an ambient air temperature, to generate a pressurized pre-intake air volume having a pre-intake air temperature and a pre-intake air pressure of more than 2.1 Bars; one or more heat-exchangers, each of which is controlled by a central processing unit (CPU) that is configured and programmed to regulate the heat-exchangers so that the pressurized pre-intake air volume is cooled, without volume expansion, to an intake air pressure of more than 1.8 Bars and an intake air temperature, so as to produce an intake air volume, which is mixed with a fuel that has an auto-ignition temperature, so as to constitute the intake volume of one of the cylinders; and wherein the heat exchangers are regulated by the CPU so that the intake air temperature remains constant, regardless of the ambient air temperature, and so that the intake air temperature is sufficiently low that the pre-ignition compression temperature, at a designated effective compression ratio, is below the auto-ignition temperature of the fuel. |
