Embodiments described herein relate generally to ventilation of a combustion engine. More specifically, embodiments described herein relate to a ventilation system for blow-by gas in a combustion engine.
During operation of a combustion engine, gas is pressed out of the combustion chamber and into a crankcase through a gap between a piston ring and a cylinder wall. Gas may also come from valve stem seals and turbocharger seals. This gas, which includes hydrocarbon gases, water vapor, and a small amount of entrained liquid oil, is called blow-by gas. Unless removed from the crankcase, the blow-by gas increases the pressure inside the crankcase.
Conventionally, the blow-by gas may be vented from the crankcase with a crankcase ventilation system, also called a crankcase breather system. In an open crankcase ventilation system, the crankcase breather system vents to the atmosphere. Blow-by gas is one component of the vehicle's overall emissions, and as such, is an emission that the industry attempts to mitigate. Further, blow-by gas can produce noxious odors, which may present an issue when the vehicle is stationary.
Another conventionally known crankcase ventilation system is a closed crankcase breather system, where the blow-by gas can be vented back to the engine, for example by first being vented to a turbocharger compressor. Venting blow-by gas to the engine intake/turbocharger compressor inlet can potentially contaminate the air intake hardware of the engine/turbocharger compressor. Under high temperatures and high loading of blow-by gases, the oil entrained in the blow-by gas can harden and stick to the engine/turbocharger compressor. The hardening and sticking process of the oil from the blow-by gas is known as coking, which can reduce turbocharger compressor efficiency, thereby increasing engine emissions, and ultimately lead to failure of the engine/turbocharger compressor.
A method of selectively directing a flow of blow-by gas in a vehicle having an engine and a turbocharger compressor includes the steps of providing fluid communication for the flow of blow-by gas from the engine to a valve, actuating the valve with a valve actuator to at least one of a closed system position and an open system position, and directing the flow of blow-by gas from the valve to at least one of the turbocharger compressor and an atmosphere.
Referring now to
The engine 14 emits a flow of blow-by gas F from a crankcase breather 16, which in the direction of flow of blow-by gas, is downstream of the engine 14 and upstream from the three-way valve 12. The crankcase breather 16 may be assembled to the engine 14, and may include a breather oil mist separator (not shown), which may remove some of the entrained oil hydrocarbons contained in the flow of blow-by gas F.
In the direction of flow of blow-by gas F, an inlet 18 of the three-way valve 12 is in downstream fluid communication with an outlet 20 of the crankcase breather 16. After the flow of blow-by gas F enters the three-way valve 12, the blow-by gas can flow to one of two outlets, an open system outlet 22 or a closed system outlet 24. It should be appreciated that fluid communication between components, including but not limited to the engine 14, the crankcase breather 16, the valve 12 and the turbocharger compressor 32, may be provided by tubes, conduits, vessels or any other channels that convey fluids.
When the three-way valve 12 is in an open system position, the flow of blow-by gas is directed out the open system outlet 22 to a tube or conduit 26 that vents to the atmosphere 28. In the open system position, the variable open-closed crankcase breather system 10 is an open system. Valve 12 is closed to the turbocharger compressor 32 in the open system position.
When the three-way valve 12 is in a closed system position, the flow of blow-by gas is directed out the closed system outlet 24 to an inlet 30 of a turbocharger compressor 32. In the closed system position, the variable open-closed crankcase breather system 10 is a closed system that is it is closed to the atmosphere 28.
The closed system outlet 24 of the three-way valve 12 is in upstream fluid communication with the inlet 30 of the turbocharger compressor 32. The flow of blow-by gas F may be combined with a flow of air A from an engine air filter 34. From the turbocharger compressor 32, the blow-by gas flows to the engine 14, and may flow through a charge air cooler 36 between the turbocharger compressor 32 and the engine.
The three-way valve 12 selectively permits the flow of blow-by gas F to the turbocharger compressor 32 or to the atmosphere 28. The closed system position directing the flow of blow-by gas F to the turbocharger compressor 32 is the default position of the three-way valve 12. When the pressure in the turbocharger compressor 32 reaches a predetermined level indicating a predetermined loading on the engine 14, a valve actuator 38 actuates or switches the three-way valve 12 to the open system position, which vents the flow of blow-by gas F to the atmosphere 28.
The loading on the engine 14 may be determined indirectly through a turbocharger turbine 40, which receives exhaust from the engine. The turbocharger turbine 40 is mechanically linked to the turbocharger compressor 32 to power the compressor. The valve actuator 38 may be actuated by the discharge air pressure downstream of the turbocharger compressor 32.
It is possible that the valve 12 may have an additional outlet, for example a four-way valve for directing a flow of blow-by gas F to an aftertreatment system of a vehicle 42. Additionally, it is possible that the valve 12 may have a third position, where the valve directs portions of the flow of blow-by gas F from the engine 14 out more than one outlet, for example a first portion of the flow of blow-by gas F1 is directed to the turbocharger compressor 32, and a second portion of the flow of blow-by gas F2 is directed to the atmosphere 28.
In the variable open-closed crankcase breather system 10, the valve actuator 38 is mechanically connected to the three-way valve 12, however other connections, such as electrical or pneumatic, are possible. In the open-closed system 10, the valve actuator 38 is pneumatic, driven by boost air. Alternatively, the engine 14 may directly actuate the valve actuator 38, either mechanically, electrically or pneumatically. It is also possible that the valve actuator 38 may be controlled by the user/driver of the vehicle to selectively actuate the valve 12 to the open system position or the closed system position. It is possible that the engine control module (not shown) may control the valve actuator 38 and the valve 12.
The variable open-closed crankcase breather system 10 allows the selective closed ventilation to the turbocharger compressor 32, for example when emitting blow-by gas to the atmosphere 28 may cause noxious odors, such as when the engine 14 is idling. Further, the variable open-closed crankcase breather system 10 allows the selective open ventilation to the atmosphere 28, for example when high flow rates of blow-by case through the turbocharger compressor 32 may cause coking of the turbocharger compressor.
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Number | Date | Country | |
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20110023850 A1 | Feb 2011 | US |