The invention relates to an oil separating device for separating oil from crankcase gases. More particularly, the invention relates to an oil separating device having a narrow wave-shape passage downstream of a first chamber such that crankcase gases are drawn through the passage in the same direction in which separated oil drains.
An internal combustion engine includes a combustion chamber, where a fuel air mixture is burned to cause movement of a set of reciprocating pistons, and a crankcase, which contains the crankshaft driven by the pistons. During operation, it is normal for the engine to experience “blow-by,” wherein combusted crankcase gases leak past the piston-cylinder gap from the combustion chamber and into the crankcase. These blow-by or crankcase gases contain moisture, acids and other undesired by-products of the combustion process.
It is normal for crankcase gases to also include a very fine oil mist. The oil mist escapes from the engine to the manifold. The oil mist is then carried from the manifold back into the combustion chamber along with the fuel/air mixture. This results in an increase in oil consumption. Additionally the combustion of the oil mist causes a build up of residuals in the combustion chamber and on pistons which over time decreases engine efficiency. An engine typically includes a Positive Crankcase Ventilation (PCV) system for removing harmful gases from the engine and prevents those gases from being expelled into the atmosphere. Accordingly, it is known to incorporate an oil separating device into a PCV system to remove oil from these crankcase gases. The crankcase gases flow through into localized high velocity areas of the oil separator to promote separation of oil from the gases. The oil is re-introduced back to a sump via a drain device which is located generally at the bottom of the oil separator to allow for gravity to assist the drainage of oil. The sump generally holds excess oil in the system.
Though introducing crankcase gases into a localized high velocity area is sufficient to remove large particles of oil from the crankcase gases, micron and sub-micron particles of oil still remain. Oil separating devices such as Punching and Impactor Plates (PIP), or Cyclone Separators may be used to capture small particles of oil, however these oil separating devices are inefficient at capturing sub-micron oil particles. Furthermore, these devices create a high pressure drop which interferes with the drainage of captured oil. Specifically, the high pressure drop across the device interferes with the force of gravity pulling separated oil particles towards the oil drain. Accordingly, it remains desirable to provide an improved oil separator that is more efficient than conventional oil separator designs in removing micron and sub-micron particles of oil from crankcase gases while at the same time assisting gravity in directing oil towards the oil drain.
An oil separating device for separating micron and sub-micron particles of oil from crankcase gases is provided. The oil separating device includes a housing having a first chamber in communication with a second chamber. An inlet interconnects the engine with the first chamber so as to allow crankcase gases to be drawn into the first chamber, and an outlet interconnects the second chamber with the engine intake. An oil drain interconnects the second chamber with the engine so as to allow captured oil to be returned to the engine. The oil separating device further includes a narrow wave-shaped passage disposed between the first chamber and the second chamber. The narrow wave-shaped passage is defined by a first inner wall having a first undulating surface opposite and spaced apart from a second inner wall having a second undulating surface mirroring the first undulating surface. The narrow wave-shaped passage is disposed downstream of the first chamber and above the oil drain so as to allow oil particles in crankcase gases passing from the inlet to the outlet to accumulate on the first and second inner walls and assist gravity in forcing the accumulated oil through the narrow wave-shaped passage into the oil drain.
Other advantages of the present invention will be readily appreciated, as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings wherein:
Referring to the Figures, wherein like numerals indicate corresponding parts throughout the several views, an oil separating device 10 for separating oil from crankcase gases is generally indicated at 10. With reference now to
The oil separating device 10 further includes a narrow wave-shaped passage 24 disposed between the first chamber 14 and the second chamber 16. The narrow wave-shaped passage 24 is defined by a first inner wall 26 having a first undulating surface 28 a opposite and spaced a predetermined distance from a second inner wall 30 having a second undulating surface 32 mirroring the first undulating surface 28. The narrow wave-shaped passage 24 includes at least three undulations. The narrow wave-shaped passage 24 is disposed downstream of the first chamber 14 and above the oil drain 22 so as to allow oil present in crankcase gases to accumulate on the first and second inner walls 26, 30 as the crankcase gases flow from the inlet 18 to the outlet 20. Additionally, the narrow wave-shaped passage 24 is disposed such that gravity assists in forcing the oil accumulated on first and second inner walls 26, 30 through the narrow wave-shaped passage 24 into the oil drain 22.
With reference now to
As stated above, the narrow wave-shaped passages 24 are disposed such that crankcase gases are drawn through the narrow wave-shaped passage 24 in the same direction in which oil drains 22 towards the oil drain 22. The undulating surfaces 28, 32 are disposed on a pair of opposing blocks 34, and are spaced apart from each other such that a desired volume of crankcase gases are drawn therethrough. For example, the undulating surfaces 28, 32 may have an amplitude between 1 mm and 20 mm; a frequency between 0.5 waves/length and 20 waves/length; and a length between 10 mm and 100 mm; and are spaced apart from each other between 0.5 mm and 10 mm. In an engine 12 where the engine 12 pressure varies between 1 atm and 1 atm±20 kPa, the narrow wave-shaped passage 24 is configured such that up to 150 L/min (volume flow rate) of crankcase gases may be drawn through the passage at the maximum pressure at any given instant. The specifications set forth above are meant to be illustrative and are in no way limiting to the scope and spirit of the invention.
With reference again to
When the crankcase gases are passed through the narrow wave-shaped passage 24, the crankcase gases flow in the same direction as the drainage of oil. A liquid film of oil is formed on the undulating surfaces 28, 32 of the narrow wave-shaped passage 24 as crankcase gases come into contact with the undulating surfaces 28, 32. Eventually, the undulating surfaces 28, 32 become coated with oil and as crankcase gases continue to flow between the undulating surfaces 28, 32, micron and sub-micron oil particles are absorbed by the coat of oil. Furthermore, the drainage of oil is not inhibited. Rather, gravity assists the drainage of collected oil by having the flow of crankcase gases in the same direction as the drainage of oil as indicated by the arrows in
The oil separating device 10 may further include a third chamber 42 in communication with the narrow wave-shaped passage 24. The third chamber 42 defines a large volume of space which calms the flow of crankcase gases to further avoid oil entrainment. Specifically, the chamber is large enough such that captured oil may drain freely into the oil drain 22 without being captured by crankcase gases proceeding to the outlet 20. For example, if the narrow wave-shaped passage 24 is configured such that 150 L/min of crankcase gases may pass through, the third chamber 42 should be configured to be 1˜1.5×105 mm3 (volume). The oil separating device 10 may further include at least one partition 44 partially enclosing the second chamber 16 so as to define a second labyrinth to further separate oil particles from crankcase gases which have been entrained.
With reference again to
The narrow wave-shaped passage 24 is configured to draw crankcase gases along the same direction as gravity. The crankcase gas oils begin to accumulate on the undulating surfaces 28, 32 as those gases are passed through. Eventually, a coat of oil is formed on the undulating surfaces 28, 32. This coat of oil further increases the oil separating abilities of the narrow wave-shaped passage 24 as it attracts and absorbs micron and sub-micron particles of oil. Gravity forces the oil accumulating on the undulating surfaces 28, 32 towards the oil drain 22. Thus, the flow of crankcase gases assists gravity in directing the oil towards the drain, and the oil drips towards the drain as it leaves the narrow wave-shaped passage 24. The dripping oil enters into the third chamber 42 located downstream of the narrow wave-shaped passage 24. The third chamber 42 is large enough so as to calm the flow of crankcase gases and avoid oil entrainment. The filtered crankcase gases then continue through the second chamber 16 and navigate the partitions 44 and exits through the outlet 20.
Obviously, many modifications and variations of the present invention are possible in light of the above teachings and may be practiced otherwise than as specifically described while within the scope of the appended claims.
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Number | Date | Country | |
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20100126479 A1 | May 2010 | US |