The present teachings generally include an engine assembly having an air-oil separator.
Blowby gasses are combustion gasses that leak from an engine cylinder past piston rings into the crankcase volume. To prevent the blowby gasses from exiting to the atmosphere, positive crankcase ventilation (PCV) systems transfer blowby gasses from an engine crankcase volume to the engine air intake system, where the blowby gasses are mixed with fresh air and are combusted in the engine cylinders. The blowby gasses include unburned fuel, combustion byproducts, and water vapor. The blowby gasses mix with oil mist in the crankcase. Air-oil separators are sometimes used in the PCV system to separate oil from the blowby gasses en route to the air intake system. The air-oil separators are typically mounted within the cylinder head cover which in turn is mounted to the cylinder head and engine block. This increases the overall packaging space required for the engine assembly. In addition, the water vapor in blowby gasses can freeze within the vent system passages at low operating temperatures, such as below freezing.
An engine assembly includes an engine block at least partially defining a combustion chamber and a crankcase volume. The engine block defines an opening in fluid communication with the crankcase volume. An air-oil separator is mounted to the engine block at the opening and is configured to separate oil from blowby gasses flowing from the crankcase volume through the air-oil separator.
In one aspect of the present teachings, the air-oil separator is a first air-oil separator, and the engine assembly includes a cylinder head mounted to the engine block and an air intake system operatively connected to the cylinder head. A second air-oil separator is in fluid communication with the air intake system. The engine block defines a passage that at least partially establishes fluid communication between the first air-oil separator and the second air-oil separator such that oil is first separated from the blowby gasses by the first air-oil separator and is further separated from the blowby gasses by the second air-oil separator.
A method of ventilating an engine crankcase volume includes directing blowby gasses from the crankcase volume through a first air-oil separator mounted in the engine block adjacent the crankcase volume to separate oil from the blowby gasses. The blowby gasses passing through the first air-oil separator are then heated by directing engine cooling fluid through a coolant passage in the engine block.
The above features and advantages and other features and advantages of the present teachings are readily apparent from the following detailed description of the best modes for carrying out the present teachings when taken in connection with the accompanying drawings.
Referring to the drawings, wherein like reference numbers refer to like components throughout the several views,
Blowby gasses 58 can leak past the pistons 50 into the crankcase volume 28. Blowby gasses include uncombusted fuel, products of combustion including water, and air. The blowby gasses 58 mix with oil droplets 60 from lubricating oil that drains to the oil pan 26. It is desirable to route the blowby gasses 58 back to the combustion chambers 52 for combustion. This is done with a positive crankcase ventilation (PCV) system 62 shown in part in
The air-oil separator 18 is designed to remove large oil droplets 60 before the blowby gasses 58 enter the main air-oil separator 70, thereby reducing oil consumption. As shown in
In this embodiment, the air-oil separator 18 is a series of vertically-extending, spaced, V-shaped strips 88 arranged offset from one another in at least two rows to create a tortuous flow path through the air-oil separator 18 from the crankcase volume 28 to the passage 72. While the blowby gasses 58 tend to pass through the rows, a large fraction of the oil droplets 60 contact the V-shaped strips and tend to drain downward via gravity along an outer surface 83 of the strips facing the crankcase volume 28. The V-shaped strips 88 may have openings 90 that allow blowby gasses 58 to pass directly through the strips 88 to prevent excessive back pressure in the PCV system 62. The main air-oil separator 70 may be a similar configuration. In other embodiments, the air-oil separators 18, 70 can be a fleece material or other porous material that permits gas flow and tends to prevent the passage of the oil droplets 60. Other configurations of an air-oil separator that allows oil to collect can also be used.
The engine assembly 10 includes a cooling system 92, shown schematically in
Referring again to
Accordingly, a method of ventilating the engine crankcase volume 28 includes directing blowby gasses 58 from the crankcase volume 28 through a first air-oil separator 18 mounted in the engine block 12 adjacent the crankcase volume 28 to separate oil from the blowby gasses 58. Furthermore, the blowby gasses 58 passing through the first air-oil separator 18 are heated by directing engine cooling fluid through one or more coolant passages 94 in the engine block 12. Additionally, the method includes directing the blowby gasses 58 from the first air-oil separator 18 to a second air-oil separator 70 through a connecting passage 72 that at least partially establishes fluid communication between the first air-oil separator 18 and the second air-oil separator 70 such that oil is further separated from the blowby gasses 58 by the second air-oil separator 70.
While the best modes for carrying out the many aspects of the present teachings have been described in detail, those familiar with the art to which these teachings relate will recognize various alternative aspects for practicing the present teachings that are within the scope of the appended claims.
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