Patent Application
20120160207
The present disclosure relates generally to engine bearings, and more particularly, to an internal combustion engine system and method that employs engine bearing shells.
Engine parts start to wear as heat increases. Friction causes heat. Engine bearings are used to decrease friction, heat and wear. Engine bearings, such as split-half bearings, are conventionally constructed in two parts i.e., an upper half bearing shell and a lower half bearing shell. Together, the upper and lower half bearing shells form a bearing shell.
Bearing shells provide a contacting surface on which a revolving part (e.g., a crankshaft) rests. Such bearing shells are preliminarily mounted in a crankcase, prior to insertion of the crankshaft, such that the upper half shell is positioned in the upper half of the crankcase (engine block portion) and the lower half shell is positioned in the lower half of the crankcase (bearing cap or cover portion). When the engine block portion and the bearing cap portions are tightened, the ends of the upper and lower half bearings are pushed together or force fit, and the bearings are forced into a bearing bore. Such force fit is usually referred to as a “bearing crush”. The resulting bearing bore also helps define the diameter measurement of a cylinder in a piston engine.
However, such bearing crush can cause the upper and lower half bearing shells to become misaligned at a parting line. The parting line refers to the area where the two bearing halves join together.
More specifically, for example, the bores formed within the engine block and bearing cap may be slightly misaligned. As such, the upper and lower half shells of the bearing, when joined together, may also be misaligned. The sharp edges that result from such misalignment may remove or scrape off lubricants from the rotating crankshaft.
As a result, such misalignment have conventionally required removal, during or after manufacture, of materials at the ends or sides of the bearing shells in order to avoid introduction of a sharp edge that can be disposed to scrape needed lubrication oil off of rotating parts. Although such conventional relief of material solution may reduce lubrication issues caused by misalignment, the removal of bearing material indiscriminately from various locations greatly decreases the load carrying capabilities of such bearing shells. As one example, belt driven loads powered by an engine and located at a side of the engine may produce loads that are concentrated at the sides, or parting lines, of the bearing shells. Due to the decreased load carrying capabilities that result from relieved material removal, such bearing shells are susceptible to being incapable of supporting such side loads and, as a result, may be damaged.
Thus, conventional techniques of indiscriminately relieving, or removing bearing material from bearing shells at various locations to achieve smooth, low-friction movements between surfaces have resulted in engine failures. It is therefore desirable to provide, among other things, an improved bearing shell.
In accordance with one embodiment, the present disclosure is directed to an engine bearing. The engine bearing includes an upper bearing shell having a first single side relief portion. The engine bearing also includes a lower bearing shell having a second single side relief portion. The upper bearing shell and the lower bearing shell can be assembled to form an approximately cylindrical bore that is disposed therebetween. The first and second single side relief portions are configured to compensate for any offset shift that occurs at parting lines located between the assembled upper and lower bearing shells.
In another embodiment, the present disclosure is directed to an internal combustion engine having an engine block configured to receive an upper bearing shell. The upper bearing shell includes a first single side relief portion. The internal combustion engine also includes a bearing cap configured to receive a lower bearing shell. The lower bearing shell includes a second single side relief portion. The engine block and the bearing cap also include an assembled configuration such that the upper bearing shell and the lower bearing shell define an approximately cylindrical bore in the assembled configuration. The first and second single side relief portions are configured to compensate for any offset shift that occurs at a parting line disposed between the upper and lower bearing shells.
In another embodiment, the present disclosure is directed to a method of desensitizing bearing support to effects of engine block and bearing cap misalignment in an internal combustion engine. The method includes positioning an upper bearing shell within a recess of the engine block. The upper bearing shell includes a first single side relief portion. The method also includes positioning a lower bearing shell within a recess of the bearing cap. The lower bearing shell includes a second single side relief portion. Further, the method includes assembling the engine block and the bearing cap.
Reference will now be made in detail to exemplary embodiments, which are illustrated in the accompanying drawings. Wherever possible, the same reference numbers will be used throughout the drawings to refer to the same or like parts.
The engine bearing 100 is a definable structure that provides improved oil lubrication throughout an engine employing single side relief to a selective portion of a bearing. Such improved oil lubrication helps prevent scraped off oil-related bearing failures that may result from oil starvation by providing sufficient oil between, for example, the crankshaft journal 114 and the bearing. The oil that flows to the bearings forms an oil film between the crankshaft journal and the bearing. Rotation of the crankshaft journal tends to force oil between the journal and the bearing and, during normal operation, prevents metal-to-metal contact as the pressurized oil develops. Lack of lubrication or oil starvation may cause metal-to-metal contact, increased friction, and higher temperatures that can lead to the bearing seizing to the shaft. In extreme cases, the bearings surface may adhere tightly, or seize, and thus, cause the crankshaft surface to be completely destroyed.
In one example, the engine bearing 100 includes the first single side relief portion 130 of the upper bearing shell 106 and the second side relief 140 portion of the lower bearing shell 108 such that the first and second single side relief portions 130, 140 are diametrically opposed relative to the cylindrical bore 112. The cylindrical bore 112 defines the measurements of the journal diameters in an engine. As used herein, the parting line refers to a mark that results when the engine block portion 102 and the bearing cap portion 104 are tightened, thereby causing the ends of the upper and lower half bearings 106, 108 to be pushed together or force fit so that the bearings are forced into a bearing bore 112. Such force fit may also cause frictionally gripping of the half shells 106, 108 to bores 116 and 118.
In another example, the first single relief portion 130 and the second single relief portion 140 are respectively provided on internal surfaces of the upper and lower bearing shells 106, 108. In another example, the first single side relief portion 130 of the upper bearing shell 106 and the second single side relief portion 140 of the lower bearing shell 108 can be provided on external surfaces thereof.
In another example, the first single side relief portion 130 of the upper bearing shell 106 and the second single side relief portion 140 of the lower bearing shell 108 may each include an approximately planar surface 330, 340. (See
Conventional means of eliminating such sharp edges results in decreased the load capabilities of the bearing shells. As one example, belt driven loads powered by the engine and located at a side of the engine may produce loads concentrated at the sides or at areas proximate to the parting lines 110, 210. With the decreased load capabilities resulting from material removal, bearing shells in the areas of decreased thickness are not capable of supporting such loads and, as a result, may be damaged.
In one example, an internal combustion engine may be configured such that the first single side relief portion 130 of the upper bearing shell 106 and the second side relief portion 140 of the lower bearing shell 108 are diametrically opposed relative to the cylindrical bore 112. The first single relief portion 130 and the second single relief portion 140 may be respectively provided on internal surfaces of the upper and lower bearing shells 106, 108. In an assembled configuration, the first single side relief portion 130 of the upper bearing shell 106 and the second single side relief portion 140 of the lower bearing shell 108 may be disposed on opposing sides of the parting line 210 of the upper bearing shell 106 and the lower bearing shell 108. Such parting line 210 of the upper bearing shell 106 and the lower bearing shell 108 may be disposed substantially parallel to another parting line 110 that may be disposed between the engine block 102 and the bearing cap 104. Also, in another embodiment, the first single side relief portion 130 of the upper bearing shell 106 and the second single side relief portion 140 of the lower bearing shell 108 can be provided on external surfaces thereof. The first single side relief portion 130 of the upper bearing shell 106 and the second single side relief portion 140 of the lower bearing shell 108 may each be configured as an approximately planar surface. Such planar surface 330 of the upper bearing shell 106 and the planar surface 340 of the lower bearing shell 108 may be circumferentially spaced from the parting line 210 disposed between the upper and lower bearing shells 106, 108.
Polar plots illustrated in
In one example, the method for desensitizing bearing support to effects of engine block and bearing cap misalignment in an internal combustion engine includes positioning an internal side relief portion of the upper bearing shell 106 and an internal side relief portion of the lower bearing shell 108 based on an angle of rotation of the internal combustion engine 120. In another example, the method includes positioning an external planar surface 620 of the upper bearing shell 106 and an external planar surface 630 of the lower bearing shell 108 to each span a discontinuity between the engine block 102 and the bearing cap 104.
The disclosed engine bearing may be provided in any machine or engine where sufficient lubrication is a requirement. As one example, the engine bearing may be particularly applicable to a definable structure that provides improved oil lubrication throughout an engine. The operation of the engine bearing will now be explained.
During normal operation, engine bearing 100 may be housed in a crankcase of an internal combustion engine 120. The engine bearing 100 can include an upper bearing shell 106 having a first single side relief portion 130. Also, the engine bearing 100 can include a lower bearing shell 108 having a second single side relief portion 140. The upper bearing shell 106 and the lower bearing shell 108 may be assembled to form a cylindrical bore 112 that is disposed therebetween. The first and second single side relief portions 130, 140 are configured to compensate for any offset shift that occurs at parting lines 110 located between the assembled upper and lower bearing shells 106, 108.
Engine bearings 100 employing single side relief to a selective portion of the bearing helps prevent oil-related bearing failures that may result due to oil starvation. As one example, rotation of the crankshaft journal tends to force oil between the journal and the bearing. As such, during normal operation, providing sufficient oil between the crankshaft journal and the bearing helps prevent metal-to-metal contact as the pressurized oil develops. Lack of lubrication or oil starvation may cause metal-to-metal contact, increased friction, and higher temperatures, which may lead to the bearing seizing to the shaft. In extreme cases the bearings surface may adhere so tightly, and thus, causing the crankshaft surface to be completely destroyed.
Moreover, prolonged operation of an engine with insufficient oil film can cause damage to progress quickly to a smeared bearing, then to a scuffed bearing, and finally to a seized bearing. In one example, the first stage of such damage is smearing wherein a bearing may show displacement of the lead-tin overlay that may be disposed in the center of the bearing. In a second stage of damage (i.e., scuffing), the material (e.g., aluminum) located in the center of the bearing may be displaced. The final stages of failure may result in total seizure. In all three stages, the rotating journal displaces some of the veneer, or overlay material from the crown toward the mating face of each bearing half. The amount of displaced material will depend on how severe the lack of lubrication is. As the bearing and journal surfaces wear, clearances increase and oil film thickness changes, resulting in uneven support of the surfaces.
Thus, engine bearing 100 can provide a relatively inexpensive wear items designed to protect the expensive crankshaft, connecting rod and engine block 102. Engine bearings 100 having selective single side relief 130, 140 render such protection by providing a soft, smooth surface with a high load carrying capability. This protects, for example, the crankshaft journal surfaces during engine start-ups and heavy loads. Further, such engine bearing 100 having selective single side relief helps maintain correct oil flow and pressure between parts.
It is contemplated that such engine bearing 100 may be composed of materials such as nickel, bronze, steel to provide thickness; aluminum alloy to provide bearing strength; and copper to provide scuff resistance and to provide bonding material to bond lead-tin and aluminum layers together.
While this disclosure includes particular examples, it is to be understood that the disclosure is not so limited. Numerous modifications, changes, variations, substitutions and equivalents will occur to those skilled in the art without departing from the spirit and scope of the present disclosure upon a study of the drawings, the specification and the following claim
