The present invention is related to methods and apparatus for temporarily reducing the compression pressure in reciprocating internal combustion engines during startup cranking, thereby reducing the cranking torque and energy required from the engine starting system. In particular, it is related to such methods and apparatus applicable to multi-cylinder vehicle engines that may be stopped and started frequently to reduce the fuel consumed while the vehicle is not moving.
Significant fuel consumption savings may be gained in city driving by stopping the engine while the vehicle is stopped, and cranking and re-starting the engine automatically when the driver steps on the accelerator pedal. This repetitive cranking, however, places high torque and energy demands on the starting system, typically a battery powered electric motor, leading to larger and more costly batteries and motors than are required for less frequent use. Compression of air in the cylinders during the compression strokes is a major contributor to the torque and energy load, and partial release of air from the cylinders during the compression strokes during cranking is a well-known method of reducing cranking effort often used on small engines that need manual pull-start capability.
Typical prior art compression release systems incorporate a mechanism incorporated in the camshaft that opens the exhaust valves during a portion of the compression stroke to reduce the amount of fuel-air mixture trapped and compressed, thus reducing the compression and cranking effort. The exhaust valves reclose before ignition, since combustion pressure force on partially open exhaust valves would place unacceptably high stresses on the valve gear rather than carrying the force safely on the seat of the closed valve. The combustion and expansion of the reduced amount of fuel-air mixture is sufficient to increase the engine speed so that the rotary inertia of the crankshaft, flywheel and any other attached rotating mass powers subsequent compression strokes, leading to sustained engine operation. The compression release is disengaged manually or by a centrifugal mechanism for normal engine operation.
Contemporary vehicle engines offer new opportunities for compression release. They have computerized engine control modules that measure a number of parameters including crank angle, and control fuel delivery and ignition on a cycle by cycle basis to each cylinder. This allows the engine to be cranked up to starting speed with valves slightly open during the entire compression and expansion strokes to reduce compression, since the engine electronic control module may be used to turn off fuel delivery and/or ignition to prevent firing events that could otherwise damage the valve gear. When starting speed is reached, the valves are allowed to close fully and fuel and ignition are restored for normal sustained operation.
The present invention includes a compression release method for engine starting comprising:
Controlling the valve motion such that the exhaust and/or inlet valves remain slightly open during the compression and expansion strokes;
Disabling the fuel delivery and/or the ignition;
Cranking the engine to starting speed;
Controlling the valve motion such that the valves close completely; and
Enabling the fuel delivery and/or the ignition.
The invention further includes systems and apparatus for carrying out the controllable compression release method for engine starting comprising a cam and actuator or hydraulic pressure source that moves the rocker arm pivot relative to the cam lobe on command such that the associated engine valve does not fully close.
In the drawings, in which like reference numbers indicate corresponding parts throughout the several views;
The cam operated compression release mechanism according to the present invention is illustrated in
The rotatable compression release cam 118 is positioned in a bore 119 adjacent to lash adjuster flat end 115, such that when it is rotated from the position shown in
The compression release cam may be rotated by a number of known means such as hydraulic, pneumatic or electrical rotary actuators, a lever and cylinder, or the like. It is important to avoid actuating the compression release during firing events to prevent engine damage, so power actuation and spring release is a preferred fail-safe arrangement to reduce the chance of inadvertent actuation. This in turn requires stored energy such as battery power, hydraulic pressure in an accumulator, or a vacuum reservoir for actuation. A compression release cam position sensor is desirable to signal the electronic control module that the valves are in fact restored to normal running operation before engine firing is initiated. A variety of devices including mechanical switches and optical or magnetic sensors or the like is suitable.
The hydraulically operated compression release mechanism according to the present invention is illustrated in
Although in principle any pressurized fluid may be introduced into conduit 300 to move the lash adjuster, the engine lubricating oil is a convenient choice since it can leak around the lash adjuster and mingle with other lubricating oil in the lash adjuster oil gallery. The pressure required to move the lash adjuster in the range of 100 to 200 psi, higher than the 20 to 80 psi typical of engine lubricating pump pressures, but the volume is small, on the order of a cubic inch. A number of options may provide the intermittent oil pressure to move the lash adjusters and release compression. These include a battery powered pump switched on to provide the pressure and turned off to release it, or an engine or battery powered pump to charge an accumulator combined with a solenoid valve to control the oil flow. The accumulator and solenoid valve configuration offers the advantage of faster on-off response. A pressure sensor connected to conduit 300 that allows the electronic control module to determine when the compression release is active is useful to protect the engine and to carry out the automated starting procedure.
The compression relief apparatus described above enables the electronic control module to carry out a method for automatically restarting the engine that reduces the required torque and energy compared to starting with full compression. The method comprises the following steps:
Step 1. Detect the driver's intent to start the engine by measuring accelerator motion or another appropriate input signal.
Step 2. Turn on the compression release actuator such that the exhaust and/or inlet valves remain slightly open during the compression and expansion strokes.
Step 3. Measure compression release cam 119 position or pressure in conduit 300 to confirm that compression is released.
Step 3. Disable fuel delivery and/or the ignition.
Step 4. Crank the engine to starting speed and confirm speed.
Step 5. Turn off the compression release actuator such that the exhaust and/or inlet valves close normally during the compression and expansion strokes.
Step 6. Measure compression release cam 119 position or pressure in conduit 300 to confirm that compression is restored.
Step 7. Enable the fuel delivery and/or the ignition to begin self-sustained engine operation.
The method and apparatus of this invention enhance stop-start engine performance with modest changes to the engine and its valve gear. In particular, the valve gear dynamics in normal operation are unchanged, and ruggedness and reliability are not compromised. Further, the method assures proper automatic sequencing of the starting process, including measurement of parameters to confirm actions have taken place before proceeding to the next step, to optimize system performance and durability.
While the method and apparatus of the invention are described with reference to reducing torque and energy requirements for the engine starting process, it will be obvious to those skilled in the art that the invention is applicable to other purposes such as reducing compression-induced engine noise, vibration and harshness during engine shutdown.
This application claims the benefit of U.S. provisional application Ser. No. 61/687,835 filed May 2, 2012.
Number | Date | Country | |
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61687835 | May 2012 | US |