FIELD OF THE INVENTIONExemplary embodiments of the present invention are directed to an internal combustion engine lubrication system and, more particularly an oil pan for an internal combustion engine having an insert including an oil sump that facilitates rapid warm-up of oil therein.
BACKGROUNDCustomer demand driven by high fuel prices as well as governmental regulations relating to the fuel efficiency of internal combustion engines, especially those used in vehicular applications, are driving fuel economy considerations into the design and operation of engines. In addition, environmental and customer concerns are dictating longer intervals between vehicle servicing, such as oil changes, often resulting in an increase in engine oil volume.
Increases in engine oil volume may run contrary to the desire for higher fuel efficiency and improved emissions performance in that larger volumes of oil require a longer warming period following an initial cold start of the engine. Internal combustion engines operate at peak efficiencies when the oil used for lubrication of its moving parts has reached a steady state operating temperature.
The need exists for an internal combustion engine lubrication system that facilitates higher oil volumes for longer service intervals but rapidly heats the oil to normal, steady state operating temperatures.
SUMMARYIn an exemplary embodiment of the present invention, a baffle assembly for disposition in the oil pan sump region of an internal combustion engine comprises an upper flange partially closing the oil sump region, an oil pick-up well, opening through the upper flange and defined by a wall portion, for receipt of heated oil returning from the internal combustion engine, an oil reservoir defined in the oil sump region by the wall portion wherein oil in the oil reservoir is separated from oil in the oil pickup well, a viscosity sensitive oil flow restrictive passage extending between the oil pick-up well and the oil reservoir defining fluid communication therebetween and an oil pick-up for fluid communication with an oil pump of the internal combustion engine and having a pick-up inlet disposed in the oil pick-up well that is configured to withdraw oil therefrom.
In another exemplary embodiment of the present invention an internal combustion engine lubrication system comprises an internal combustion engine, an oil pan assembled to the internal combustion engine and having a bottom, a plurality of sides extending from the bottom to define an open top end, for sealing engagement with a mating surface of the internal combustion engine, and an oil sump region therein. A baffle assembly is disposed in the oil sump region and is configured to divide the oil sump region into an oil pick-up well, configured for receipt of oil returning from the internal combustion engine, and an oil reservoir for storage of bulk oil therein. An oil pick-up configured for fluid communication with an oil pump of the internal combustion engine has a pick-up inlet disposed in the oil pick-up well configured to withdraw oil therefrom. A viscosity sensitive oil flow restrictive passage is disposed between the oil pick-up well and the oil reservoir for fluid communication therebetween.
In yet another exemplary embodiment of the present invention a method for rapidly warming the engine oil in the oil pan of an internal combustion engine comprises defining an oil pick-up well in the oil pan, disposing an oil pick-up, in fluid communication with an oil pump of the internal combustion engine, in the oil pick-up well to withdraw oil therefrom, directing oil returning from the internal combustion engine to the oil pick-up well and defining a viscosity sensitive oil flow restrictive passage in the oil pick-up well to define fluid communication with oil in the oil reservoir in the oil pan.
The above features and advantages, and other features and advantages of the present invention are readily apparent from the following detailed description of the best modes for carrying out the invention when taken in connection with the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGSOther objects, features, advantages and details appear, by way of example only, in the following detailed description of embodiments, the detailed description referring the drawings in which:
FIG. 1 is a longitudinal sectional view of an oil pan assembly embodying exemplary features of the present invention;
FIG. 2 is a top plan view of the oil pan assembly ofFIG. 1;
FIG. 3 is an enlarged, partial sectional view of the oil pan assembly ofFIG. 1 illustrating an exemplary mode of operation;
FIG. 4 is an enlarged, partial sectional view of the oil pan assembly ofFIG. 1 illustrating another exemplary mode of operation;
FIG. 5 is an enlarged, partial sectional view of an oil pan assembly embodying exemplary features of the present invention;
FIG. 6 is a bottom facing perspective view of an oil pan baffle assembly embodying exemplary features of the present invention; and
FIG. 7 is an enlarged, partial sectional view of an oil pan assembly embodying exemplary features of the present invention.
DESCRIPTION OF THE EMBODIMENTSThe following description is merely exemplary in nature and is not intended to limit the present disclosure, application or uses. It should be understood that throughout the drawings, corresponding reference numerals indicate like or corresponding parts and features.
In accordance with an exemplary embodiment of the present invention,FIG. 1 illustrates anoil pan assembly14 for application to aninternal combustion engine5. Theoil pan14 may be constructed of stamped steel, plastic, composite or may be of a cast metal composition and includes anopen top end18, having an upper flangedsurface16 that is configured to mate with acorresponding mating surface7 of theinternal combustion engine5 in a sealing arrangement, a closedlower end20 andsides22. The oil pan is configured to collectengine oil24 that drains from the engine block following lubrication thereof. The oil pan includes anoil sump region26 that is fed by an engine oil return system including angled, oil collection ramps orsurfaces28 that are configured to collect theengine oil24 and direct the oil towards thesump region26. An oil pump (not shown) is fluidly connected to an oil pick-up30 having a pick-up inlet32 disposed in the oil pan, preferably in theoil sump region26. The oil pump may be electrically operated or engine operated (such as through mechanical connection to the crankshaft, the camshaft, an accessory drive or another rotatable component of the internal combustion engine5) and functions to withdrawengine oil24 from theoil pan14 through the oil pick-up30 for distribution throughout theinternal combustion engine5 during engine cranking and operation, for lubrication of various moving parts.
Referring toFIGS. 1 and 2, in an exemplary embodiment, disposed within theoil pan assembly14, preferably within theoil sump region26, is a baffle assembly, designated generally as34. Thebaffle assembly34 includes an upper flange36 alower flange38 and aninterconnecting wall portion40 extending between, and connecting, the upper and the lower flanges. Thebaffle assembly34 is disposed within theoil sump region26 such that thelower flange38 is positioned in a closely spaced orientation with thebottom42 of theoil sump region26 to define a viscosity sensitive oil flowrestrictive passage44 therebetween. Theupper flange36 is configured to at least partially close the oil sump region against the ingress ofengine oil24 from around thebaffle perimeter46.Mounting bolts48 may engage corresponding oil pan mounting bosses (not shown) to retain thebaffle assembly34 securely and sealingly in position within theoil pan14.
Thebaffle assembly34 partitions thesump region26 into anoil reservoir52, and an oil pick-up well53,FIGS. 3 and 4 that is configured to receive the pick-up inlet32 of the oil pick-up30. Amounting flange54,FIG. 2, may be associated with oil pick-up inlet32 and receivesattachment bolts56 that are operable to securely retain the oil pick-up30 within theoil pan14.
In an exemplary embodiment, upon engine start-up, especially following a cold engine start-up,supply oil60 is drawn from the oil pick-up well53 by the engine oil pump (not shown) through the pick-up inlet32 of the oil pick-up30. Thesupply oil60 is circulated through the lubrication system of theinternal combustion engine5, where is it warmed, and subsequently returned to theoil pan14 as indicated byreturn oil flow58. Due to the at least partial closure of theoil sump region26 by thebaffle perimeter46 of theupper flange36,return oil flow58 is directed back to the oil pick-up well53 rather than to theoil reservoir52. The result is thatheated engine oil24 returning to the oil pick-up well53 asreturn oil flow58 will be preferentially available to the pick-up inlet32 of the oil pick-up30 and thus, the oil pump and engine lubrication system. As such, a reduction in the time required for theinternal combustion engine5 to reach steady state operating temperature is achieved, thereby improving the efficiency and emissions performance of the engine. In an exemplary embodiment thebaffle assembly34, or at least the portion of the assembly defining the oil pick-up well53 such as interconnectingwall portion40, may be constructed of an insulative material defining an additional thermal barrier between the warm oil in the oil pick-up well53 and the cooler oil in theoil reservoir52. The material may comprise a high density, temperature tolerant plastic or composite material or may comprise a double walled sheet assembly constructed of metal or a plastic or composite material.
In an exemplary embodiment illustrated inFIG. 1, during engine startup and steady state operation thereof,return oil flow58 andsupply oil flow60 are relatively equal and, as such, the oil level in thesump region26 will remain at relatively equal levels in theoil reservoir52 and the oil pick-up well53 as indicated by theoil level27. However, referring toFIG. 3, during operation of theinternal combustion engine5 at high speeds (i.e. high RPM) or during rapid transient operation of the engine, oil draw down may occur in the oil pick-up well53 resulting in a difference inoil levels62a,62bbetween the oil pick-up well53 and theoil reservoir52, respectively. The resulting pressure differential between the differing oil level “fluid columns”,62a,62b, will causereplacement oil64 to flow from theoil reservoir52 to the oil pick-up well53 through viscosity sensitive oil flowrestrictive passage44, resulting in fluid leveling throughout theoil sump region26. A vent opening (not shown) in thebaffle assembly34 provides equal pressures in theoil reservoir52 and the oil pick-up well53 thereby allowing rapid leveling of theoil levels62aand62bby preventing a partial vacuum in the oil reservoir during times of unequal fluid levels. As shown inFIG. 4, during operating conditions which may result in a largerreturn oil flow58 than is required by the engine oil pump assupply oil60, the fluid the oil pick-up well may rise, resulting in a difference inoil levels62a,62bbetween the oil pick-up well and theoil reservoir52, respectively. Again, the pressure differential between the differing oil level “fluid columns” will causereplacement oil64 to flow from the oil pick-up well53 to theoil reservoir52 resulting in fluid leveling throughout theoil sump region26.
In an exemplary embodiment, the flow characteristics of thereplacement oil64 is determined by the viscosity of the oil, the nature of the fluid flow (e.g. laminar or turbulent flow) the shape and the dimensions of the viscosity sensitive oil flowrestrictive passage44 which is defined by the distance “d1” between thelower flange38 and thebottom42 of theoil sump region26 or by the distance “d2” between theperimeter66 of thelower flange38 and theouter wall68 of theoil sump region26, or both (FIG. 3). As a result, the flow characteristics, or rate of flow, of thereplacement oil64 may be customized for a particular engine application by varying the dimensions “d1” and/or “d2” of the viscosity sensitive oil flowrestrictive passage44 such that the passage may be configured to regulate the rate of oil flow therethrough.
In an exemplary embodiment shown inFIGS. 5 and 6, a series of flow modifiers such as theribs70 extending between thelower flange38 of thebaffle assembly34 into the viscosity sensitive oil flowrestrictive passage44 may be utilized to further customize the flow characteristics of thesupply oil flow64 between theoil reservoir52 and the oil pick-up well53. In this embodiment of thebaffle assembly34, theribs70 extend from the lower surface of thelower flange38 and direct thesupply oil flow64 to the pick-up inlet32 of the oil pick-up30 under dynamic/high performance engine operating conditions. It is also contemplated that the flow modifiers orribs70 may extend from thebottom42 of the oil sump region as an integral feature of the oil pan. In addition, the spacing of the ribs will, through fluid friction with thesupply oil flow64, determine the flow rate of the oil under cold conditions.
In another exemplary embodiment illustrated inFIG. 7, it is contemplated that thebaffle assembly34 may include anupper flange36 and awall portion40 extending between the upper flange and thebottom42 of theoil sump region26. Theupper flange36 is configured to at least partially close the oil sump region against the ingress ofengine oil24 from around thebaffle perimeter46.Mounting bolts48 may engage corresponding oil pan mounting bosses (not shown) to retain thebaffle assembly34 securely and sealingly in position within theoil pan14. Thebaffle assembly34 partitions thesump region26 into anoil reservoir52, and an oil pick-up well53 that is configured to receive the pick-up inlet32 of the oil pick-up30. A series of viscosity sensitive oil flowrestrictive passages80 fluidly connect the oil pick-up well53 with theoil reservoir52.
Upon engine start-up, especially following a cold engine start-up,supply oil60 is drawn from the oil pick-up well53 by the engine oil pump (not shown) through the pick-upinlet32 of the oil pick-up30. Thesupply oil60 is circulated through the lubrication system of theinternal combustion engine5, where is it warmed, and subsequently returned to theoil pan14 as indicated byreturn oil flow58. Due to the at least partial closure of theoil sump region26 by thebaffle perimeter46 of theupper flange36, returnoil flow58 is directed back to the oil pick-up well53 rather than to theoil reservoir52. The result is thatheated engine oil24 returning to the oil pick-up well53 asreturn oil flow58 will be preferentially available to the pick-upinlet32 of the oil pick-up30 and thus, the oil pump and engine lubrication system. As such, a reduction in the time required for theinternal combustion engine5 to reach steady state operating temperature is achieved, thereby improving the efficiency and emissions performance of the engine. During engine startup and steady state operation thereof, returnoil flow58 andsupply oil flow60 are relatively equal and, as such, the oil level in thesump region26 will remain at relatively equal levels in theoil reservoir52 and the oil pick-up well53. As illustrated inFIG. 7, during operation of the engine at high speeds (i.e. high RPM) or during rapid transient operation of the engine, oil draw down may occur in the oil pick-up well53 resulting in a difference inoil levels62a,62bbetween the oil pick-up well53 and theoil reservoir52, respectively. The resulting pressure differential between the differing oil level “fluid columns”,62a,62b, will causereplacement oil64 to flow from theoil reservoir52 to the oil pick-up well53 through the viscosity sensitive oil flowrestrictive passages80 resulting in fluid leveling throughout theoil sump region26. As discussed in the earlier described embodiment, during operating conditions which may result in a largerreturn oil flow58 than is required by the engine oil pump assupply oil60, the fluid level in the oil pick-up well may rise, resulting in a difference inoil levels62a,62bbetween the oil pick-up well and theoil reservoir52, respectively. Again, the pressure differential between the differing oil level “fluid columns” will causereplacement oil64 to flow from the oil pick-up well53 to theoil reservoir52 resulting in fluid leveling throughout theoil sump region26.
The flow characteristics of thereplacement oil64 is determined by the viscosity of the oil, the nature of the fluid flow (e.g. laminar or turbulent flow) the shape and the dimensions of the oil flowrestrictive passages80 which are defined by the length of the passages as a function of the thickness of thewall portion40 and the diameter thereof. As a result, the flow characteristics, or rate of flow, of thereplacement oil64 may be customized for a particular engine application by varying the length and the diameters of the oil flowrestrictive passages80.
While the invention has been described with reference to exemplary embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the essential scope thereof. Therefore, it is intended that the invention not be limited to the particular embodiments disclosed as the best mode contemplated for carrying out this invention, but that the invention will include all embodiments falling within the scope of the present invention.