This disclosure is directed towards an engine assembly and a method of operating an engine assembly.
Machines, including backhoe loaders, excavators, loaders and the like, commonly comprise an engine assembly including an engine, particularly an internal combustion engine, for providing power for driving the machine and operating its components. The engine typically comprises a crankshaft rotating within a crankcase and a lubrication system typically distributes lubricant through the crankshaft and into the crankcase. Engine assemblies also commonly comprise a turbocharger driven by exhaust gases from the engine and for compressing intake gas entering the engine to increase its power output.
The turbocharger may also receive lubricant from the lubrication system and the lubricant may be returned to the crankcase via a lubricant drain. However, high pressure in the crankcase may force lubricant and/or high pressure back into the lubricant drain, such as due to crankshaft windage, and cause a differential pressure in the turbocharger. As a result, seals in the turbocharger may be compromised and lubricant may leak from the turbocharger.
KR101251711B1 discloses a closed crankcase ventilator for preventing oil backdraft expelled into an oil pan and to supply blow-by gas into an intake port of an engine. However, such a ventilator requires an additional device and system components in the engine assembly and also may increase pressure locally around the ventilator.
The present disclosure therefore provides an engine assembly comprising: a crankcase comprising a crankcase chamber formed at least partially within a crankcase inner surface; a crankshaft rotatably mounted in the crankcase chamber, wherein during rotation the crankshaft is configured to drive a crankcase fluid flow in the crankcase chamber; a lubrication system comprising a lubricant drain for a drain fluid flow therethrough, the lubricant drain extending through the crankcase to a drain aperture at the crankcase chamber; and a fluid guide arrangement mounted to the crankcase, extending into the crankcase chamber from the crankcase inner surface and located adjacent or in proximity to the drain aperture, the fluid guide arrangement being configured for guiding crankcase fluid flow away from the drain aperture and/or for reducing the pressure of the crankcase fluid flow past the drain aperture, such that drain fluid flows from the lubricant drain.
The present disclosure further provides a method of operating the aforementioned engine assembly comprising: rotating the crankshaft and thereby drive the crankcase fluid flow in the crankcase chamber; and operating the lubrication system such that drain fluid flow passes through the lubricant drain to the drain aperture, wherein the fluid guide arrangement guides the crankcase fluid flow away from the drain aperture and/or reduces the pressure of the crankcase fluid flow past the drain aperture, such that the drain fluid flows from the lubricant drain.
By way of example only, embodiments of apparatuses and methods of the present disclosure are now described with reference to, and as shown in, the accompanying drawings, in which:
The present disclosure is generally directed towards an engine assembly in which a fluid guide arrangement is configured to reduce the impact of windage effects upon lubricant draining from a lubricant drain. In particular, the fluid guide arrangement guides fluid flow in the crankcase in order to assist the fluid flow from the lubricant drain. The fluid guide arrangement may guide the drain fluid flow by directing the crankcase fluid flow away from the lubricant drain and/or by inducing a negative pressure in the crankcase fluid flow to draw the drain fluid flow out of the lubricant drain.
The engine assembly 10 further comprises an engine 16, which may be arranged to receive compressed intake gas from the compressor 13. The engine 16 may be in fluid communication with and direct exhaust gas to the turbine 14 for driving the turbine 14. The turbine 14 may be in fluid communication with an exhaust system 17 for directing exhaust gas out of the engine assembly 10 to atmosphere.
Although not illustrated, the engine assembly 10 may comprise a supercharger for further compressing intake gas entering the engine 16, an exhaust gas recirculation system, an aftertreatment system for treating the exhaust gas in the exhaust system 17 to remove pollutants prior to directing the exhaust gas to atmosphere and the like.
The engine 16 may be an internal combustion engine, such as a compression-ignition or spark-ignition engine, and an embodiment thereof is illustrated in further detail in
The crankcase 22 comprises a crankcase chamber 23 formed at least partially within a crankcase inner surface 26 of the crankcase 22. A lower part of the crankcase 22 (i.e. opposite to the at least one engine cylinder 21) may be open and a lower housing (not shown) may be attached to the crankcase 22 to enclose the crankcase chamber 23 within the engine block 20, crankcase 22 and lower housing. The lower housing may comprise a lubricant sump pan.
The engine 16 may comprise at least one piston 24 reciprocatively mounted within the at least one engine cylinder 21. The at least one piston 24 may be configured to reciprocate along a piston reciprocating axis 19. The engine 16 may comprise at least one intake valve (not shown) for selectively allowing the intake gas, which may be received from the turbocharger 12 and air intake system 11, to enter the at least one engine cylinder 21. The engine 16 may comprise at least one exhaust valve (not shown) for selectively allowing exhaust gas generated by combustion to exit the at least one engine cylinder 21, which may exit the engine assembly 10 via the turbocharger 12 and exhaust system 17.
The engine 16 comprises a crankshaft 30 rotatably mounted in the crankcase 22 and in the crankcase chamber 23. The crankshaft 30 may be rotatable in a crankshaft rotation direction 36 about a crankshaft axis 31. The at least one piston 24 may be mounted to the crankshaft 30 by at least one connecting rod 25 and the crankshaft 30 may be configured, upon rotation about the crankshaft axis 31, to provide a power output from the engine 16.
Fuel, such as diesel, petrol or natural gas, may be selectively provided to the at least one engine cylinder 21 to combust with the intake gas and drive the at least one piston 24, thereby rotating the crankshaft 30 and providing an engine 16 output torque and power.
The crankshaft 30 may be mounted on main bearings (not shown) of the engine 16. The crankshaft 30 may comprise journals 32. The journals 32 may comprise at least one rod journal 32 (as shown in
The crankshaft 30 may comprise at least one crankshaft web 33, which may connect and extend between adjacent rod journals 32. The at least one crankshaft web 33 may trace and/or form a crankshaft outer perimeter 37 of the crankshaft 30 during its rotation. As the at least one crankshaft web 33 forms the outermost diameter of the crankshaft 30, the crankshaft outer perimeter 37 may represent the outermost limit of reach of the crankshaft 30 through its entire rotation.
The engine assembly 10 comprises a lubrication system 40 for distributing lubricant, such as oil, therearound. The lubrication system 40 may comprise a lubricant sump or reservoir, which may be in the lower housing in the form of the lubricant sump pan. The lubrication system 40 may comprise at least one pump (not shown) for pumping lubricant around it.
The lubrication system 40 may comprise a crankshaft lubrication system 34 for distributing lubricant to the journals 32 and, as illustrated, the crankshaft lubrication system 34 may comprise at least one duct formed within the crankshaft 30. The at least one pump may direct lubricant through the crankshaft 30 to the journals 32. The lubricant may be ejected from the journals 32 into the crankcase chamber 23 and collected in the lubricant sump.
The lubrication system 40 comprises a lubricant drain 42 for a drain fluid flow 38 therethrough. The drain fluid may comprise lubricant and/or air or gas and the lubricant drain 42 may be for returning the drain fluid to the sump. As illustrated in
The lubricant drain 42 may comprise at least one drain passageway 43 extending through the crankcase 22 and to the drain aperture 46. The at least one drain passageway 43 may comprise at least one bore through, and optionally cast or drilled in, the engine block 20. The lubricant drain 42 may comprise at least one drain tube 44 mounted to the at least one drain passageway 43, such as via a drain flange 45.
The lubrication system 40 may distribute lubricant to the turbocharger 12, as illustrated in
However, the lubrication system 40 may distribute lubricant to other components of the engine assembly 10 and the lubricant drain 42 may be configured to return drain fluid from any such component. The lubrication system 40 may therefore comprise a plurality of lubricant drains 42 leading from different components.
The crankshaft 30 is configured to drive, and drives during use, a crankcase fluid flow 48 in the crankcase chamber 23. The crankcase fluid may comprise lubricant, such as that sprayed from the lubricant sump and/or crankshaft lubrication system 34 during rotation of the crankshaft 30. The crankcase fluid may comprise a gas, such as the air and/or other exhaust gases or the like within the crankcase chamber 23. The crankshaft 30 may drive such crankcase fluid flow 48 by windage effects. The crankcase fluid flow 48 may be annular around the crankshaft 30 and/or may be between the crankcase 22, particularly the crankcase inner surface 26, and the crankshaft 30. The crankshaft 30 may be configured to drive, and may drive during use, the crankcase fluid flow 48 towards the drain aperture 46. The crankcase fluid flow 48 may extend past the drain aperture 46 and may be in the same direction as the crankshaft rotation direction 36.
The engine 16 comprises a fluid guide arrangement 50 mounted to the crankcase 22 and located adjacent or in proximity to the drain aperture 46. The fluid guide arrangement 50 extends into the crankcase chamber 23 from the crankcase inner surface 26. In particular, the crankcase inner surface 26 may extend around at least about 50% or at least about 60% of the circumference of the crankshaft 30 and the fluid guide arrangement 50 may extend around less than about 50%, less than about 25% or less than about 10% of the circumference of the crankshaft 30. The crankcase inner surface 26 around the crankshaft 30 may be separated from the crankshaft 30 by a greater distance than the fluid guide arrangement 50.
The fluid guide arrangement 50 is configured to guide the crankcase fluid flow 48 as it flows past or in proximity to the drain aperture 46. As a result, the fluid guide arrangement 50 controls the drain fluid flow 38 and/or the drain fluid flows 38 from the lubricant drain 42. The fluid guide arrangement 50 may be configured to change the direction of and/or deflect the crankcase fluid flow 48 from its otherwise substantially circular path around the crankcase chamber 23. The fluid guide arrangement 50 is configured to guide and/or deflect the crankcase fluid flow 48 away from the drain aperture 46. The fluid guide arrangement 50, in addition or alternatively, reduces the pressure of the crankcase fluid flow 48 past the drain aperture 46 (e.g. adjacent to the fluid guide arrangement 50) such that a negative pressure is induced in the crankcase fluid flow 48 relative to the pressure of the drain fluid flow 38 in the lubricant drain 42.
The fluid guide arrangement 50 may comprise a first fluid guide wall 51 mounted to the crankcase 22 and located at least partially over and/or upstream of the drain aperture 46, for example as illustrated in
Furthermore, the first fluid guide wall 51 may be located above (for example higher than but not necessarily vertically aligned with) the drain aperture 46 when the engine 16 is in its upright configuration as shown in
The first fluid guide wall 51 may extend into the crankcase chamber 23 toward the crankshaft axis 31 and/or crankshaft 30 and may comprise a first wall surface 52, which may extend between first wall proximal and distal ends 53, 54. The first wall proximal end 53 may be located proximal to the drain aperture 46 and the first wall distal end 54 may be located distal to the drain aperture 46. The first wall proximal end 53 may be downstream of the first wall distal end 54 and may be downstream of the first wall surface 52. The term “downstream” may refer to a feature being located in a direction along the crankshaft rotation direction 36 and crankcase fluid flow 48 and opposite to the upstream direction. The drain and crankcase fluid flows 38, 48 may mix together downstream of the drain aperture 46.
As illustrated in
The first wall surface 52 may be substantially concave and may curve and/or extend inwardly towards and/or into the crankcase 22 for guiding the crankcase fluid flow 48 away from the drain aperture 46, for example as illustrated in
Alternatively, as illustrated in
The first fluid guide wall 51 may extend at least partially over the drain aperture 46 and/or the first wall proximal end 53 may overhang the drain aperture 46, for example as illustrated in
The fluid guide arrangement 50 reduces the pressure of the crankcase fluid flow 48 past the drain aperture 46. The fluid guide arrangement 50 may be configured to induce a negative pressure in the crankcase chamber 23 adjacent to the drain aperture 46 relative to the pressure in the lubricant drain 42. The fluid guide arrangement 50 may form a differential pressure between the crankcase fluid flow 48 in the crankcase 22 and the drain fluid flow 38 in the lubricant drain 42. The fluid guide arrangement 50 may be configured to draw the drain fluid flow 38 out of the lubricant drain 42 and into the crankcase chamber 23 for mixing with the crankcase fluid flow 48. In particular, the fluid guide arrangement 50 may be configured to induce the Venturi effect adjacent to the drain aperture 46 to form such a negative pressure.
The fluid guide arrangement 50 may therefore form a constriction between the fluid guide arrangement 50 and crankshaft 30 for the crankcase fluid flow 48 to pass through. The constriction may comprise a convergent section and/or a throat and a divergent section downstream of the convergent section and/or throat. The fluid guide arrangement 50 may form the throat at its minimum distance from the crankshaft 30, for example where the first fluid guide wall 51 and first wall surface 52 are closest to the crankshaft 30 and crankshaft outer perimeter 37.
As illustrated in
Alternatively, as illustrated in
At the first wall proximal end 53 the separation between the first fluid guide wall 51 and crankshaft outer perimeter 37 may be in the range of about 1 mm to about 10 mm or of about 2 mm to 7 mm. At the first wall distal end 54 the separation between the first fluid guide wall 51 and crankshaft outer perimeter 37 may be in the range of about 0.1 mm to about 1 mm.
The fluid guide arrangement 50 may comprise a second fluid guide wall 60 extending downstream from the drain aperture 46. The second fluid guide wall 60 may comprise a second wall surface 61 and may extend from a second wall proximal end 62 adjacent to the drain aperture 46 to a second wall distal end 63 distal to the drain aperture 46. The second fluid guide wall 60 may be closest to the crankshaft 30, crankshaft axis 31 and/or crankshaft outer perimeter 37 at its second wall proximal end 62. The separation between the second wall surface 61 and crankshaft 30, crankshaft axis 31 and/or crankshaft outer perimeter 37 may increase, for example continuously, from the second wall proximal end 62 to the second wall distal end 63. Thus the second wall surface 61 may form at least part of the divergent section. The second wall surface 61 may be concave and may extend inwardly into the crankcase 22.
The arrangement of
As in
However, as illustrated in
As illustrated in
However, as illustrated in
In
The fluid guide arrangement 50, such as the first and/or second fluid guide walls 51, 60, may be formed integrally with the crankcase 22 and/or engine block 20 as illustrated in
The fluid guide arrangement 50 may extend along a width (not shown in
The fluid guide arrangement 50 may be configured to avoid impacting the flow under gravity of lubricant from the drain aperture 46. If, as discussed above, the drain aperture 46 is on the opposing side of the crankcase 22 and the first fluid guide wall 51 is located below the drain aperture 46 when the engine 16 is in its upright configuration, the fluid guide arrangement 50 may be arranged in a similar manner to that shown in
Rotation of the crankshaft 30 may result in windage effects, which may be in the form of turbulence in the air around the crankshaft 30 and the lubricant being thrown about the crankshaft 30 within the crankcase 22. Such windage effects may be caused by air resistance or friction around the crankshaft 30. In prior art systems the windage effects may direct the crankcase fluid flow 48 towards the drain aperture 46. The turbulence may cause a higher pressure adjacent to the drain aperture 46 such that, in prior art systems, high pressure air and lubricant is forced back up into the lubricant drain 42. As a result, in such prior art systems a pressure differential may be created in the turbocharger 12, which may compromise the seals therein such that lubricant may leak therefrom.
However, the fluid guide arrangement 50 of the present disclosure controls, adapts or adjusts crankcase fluid flow 48 past the drain aperture 46 and therefore controls the drain fluid flow 38 from the lubricant drain 42, such as by preventing the crankcase fluid flow 48 from backing up through the lubricant drain 42 and/or by drawing the drain fluid flow 38 therefrom. The fluid guide arrangement 50 may control the crankcase 22 and drain fluid flow 48, 38 by directing the crankcase fluid flow 48 away from the drain aperture 46 and/or by inducing a negative pressure adjacent to the drain aperture 46 in order to draw the drain fluid flow 38 from the lubricant drain 42 and into the crankcase fluid flow 48. Thus the fluid guide arrangement 50 may reduce windage effects at the drain aperture 46 such that higher pressure air and lubricant are substantially not forced into the lubricant drain 42.
Number | Date | Country | Kind |
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2004113.3 | Mar 2020 | GB | national |