1. Technical Field
This invention relates generally to internal combustion engines, and more particularly to pistons and their method of construction.
2. Related Art
Engine manufacturers are encountering increasing demands to improve engine efficiencies and performance, including, but not limited to, improving fuel economy, reducing oil consumption, improving fuel systems, increasing compression loads within the cylinder bores, reducing heat lost through the piston, reducing friction losses, decreasing engine weight and making engines more compact. In order to achieve these goals, the piston size and their compression height need to be reduced. However, while desirable to increase compression loads within the combustion chamber, it remains necessary to maintain the piston within workable limits. As such, although desirable to increase compression loads within the combustion chamber, there is a tradeoff in that these “increases” limit the degree of which the compression height, and thus, overall engine size, can be decreased. Further, the degree to which the engine weight can be reduced is compromised in that the increase of mechanical and thermal loads imposed on the piston require that they be made of steel.
A piston constructed in accordance with this invention overcomes the aforementioned disadvantages of known piston constructions and other disadvantages, as will become apparent to those skill in the art upon reading the disclosure and viewing the drawings herein.
A piston constructed in accordance with this invention is constructed of steel, thereby providing the piston with enhanced strength and durability to withstand increased compression loads within a cylinder bore, such as those seen in modern high performance engines. Further, due to the novel configuration of the piston, the compression height (CH) and weight of the piston are able to be minimized, thereby allowing an engine in which the pistons are deployed to be made more compact and lightweight.
In accordance with one aspect of the invention, a piston is constructed including a top part having an uppermost surface with annular inner and outer upper joining surfaces depending from the uppermost surface. The piston further includes a bottom part having a pair of pin bosses providing a pair of laterally spaced pin bores aligned with one another along a pin bore axis and having a pair of upwardly extending annular inner and outer lower joining surfaces joined by separate respective inner and outer weld joints to the inner and outer upper joining surfaces of the top part with an annular cooling gallery formed laterally between the upper joining surfaces and the lower joining surfaces. The bottom part includes a combustion bowl wall recessed below the uppermost surface, wherein the combustion bowl wall has an upper apex and an annular valley surrounding the upper apex and a lower apex underlying the upper apex. The inner weld joint joining the top part to the bottom part is substantially coplanar with the lower apex, thereby minimizing the compression height of the piston.
In accordance with another aspect of the invention, a piston is constructed including a top part having an uppermost surface with annular inner and outer upper joining surfaces depending from the uppermost surface. The piston further includes a bottom part having a pair of pin bosses providing a pair of laterally spaced pin bores aligned with one another along a pin bore axis and having a pair of upwardly extending annular inner and outer lower joining surfaces joined by separate respective inner and outer weld joints to the inner and outer upper joining surfaces with an annular cooling gallery extending laterally between the upper joining surfaces and the lower joining surfaces. The bottom part has a combustion bowl wall recessed below the uppermost surface, wherein the combustion bowl wall has a thickness extending between an upper apex and a lower apex underlying the upper apex with an annular valley surrounding the upper apex and the lower apex, wherein the thickness of the combustion bowl wall is substantially constant.
In accordance with another aspect of the invention, a piston is constructed including a top part having an uppermost surface with annular inner and outer upper joining surfaces depending from the uppermost surface. The piston further includes a bottom part having a pair of pin bosses providing a pair of laterally spaced pin bores axially aligned along a pin bore axis and having a pair of upwardly extending annular inner and outer lower joining surfaces joined by separate respective inner and outer weld joints to the inner and outer upper joining surfaces with an annular cooling gallery formed between the upper joining surfaces and the lower joining surfaces. The top part and the bottom part form a piston head region having an outer diameter, wherein a compression height of the piston extends between the uppermost surface of the top part and the pin bore axis. The compression height ranges between about 38% to 45% of the piston outer diameter.
In accordance with another aspect of the invention, a method of constructing a piston for an internal combustion engine is provided. The method includes forming a top part having an uppermost surface with annular inner and outer upper joining surfaces depending from the uppermost surface. Further, casting a bottom part having a pair of pin bosses providing a pair of laterally spaced pin bores aligned with one another along a pin bore axis and having a pair of annular inner and outer lower joining surfaces extending upwardly from the pin bores with a combustion bowl wall recessed below the uppermost surface. The combustion bowl wall is formed having an upper apex and an annular valley surrounding the upper apex and a lower apex underlying the upper apex. The method further includes welding the top part to the bottom part by forming separate inner and outer weld joints between the respective inner and outer upper joining surfaces and forming an annular cooling gallery extending laterally between the upper joining surfaces and the lower joining surfaces. Further yet, forming the inner weld joint in substantially coplanar relation with the lower apex of the combustion bowl.
In accordance with another aspect of the invention, a method of constructing a piston for an internal combustion engine includes forming a top part having an uppermost surface with annular inner and outer upper joining surfaces depending from the uppermost surface. Further, forming a bottom part having a pair of pin bosses providing a pair of laterally spaced pin bores aligned with one another along a pin bore axis and having a pair of upwardly extending annular inner and outer lower joining surfaces with a combustion bowl wall recessed below the uppermost surface. The combustion bowl wall is formed having an upper apex and a lower apex underlying the upper apex with a thickness extending between the upper apex and a lower apex and having an annular valley surrounding the upper apex and the lower apex. The method further yet includes forming the thickness of the combustion bowl wall being substantially constant.
In accordance with yet another aspect of the invention, a method of constructing a piston for an internal combustion engine includes forming a top part having an uppermost surface with annular inner and outer upper joining surfaces depending from the uppermost surface. Further, forming a bottom part having a pair of pin bosses providing a pair of laterally spaced pin bores aligned with one another along a pin bore axis and having a pair of annular inner and outer lower joining surfaces extending upwardly from the pin bores with a combustion bowl wall recessed below the uppermost surface. Then, welding the top part to the bottom part by forming separate inner and outer weld joints between the respective inner and outer upper joining surfaces with an annular cooling gallery extending between the upper joining surfaces and the lower joining surfaces and forming a piston head region having an outer diameter. The method further includes providing a compression height extending between the uppermost surface of the top part and the pin bore axis upon performing the welding step wherein the compression height ranges between about 38% to 45% of the piston head region outer diameter.
These and other aspects, features and advantages of the invention will become more readily appreciated when considered in connection with the following detailed description of presently preferred embodiments and best mode, appended claims and accompanying drawings, in which:
Referring in more detail to the drawings,
As shown in
As best shown in
The head region 14 of the piston 10 further includes an annular ring belt 44 formed in an annular outer wall 46 of the piston 10. The outer wall 46 extends downwardly from the top wall 20, wherein an upper portion of the outer wall 46 is provided by the top part 18 of the piston 10, and a remaining bottom portion of the outer wall is provided by the bottom part 16. The upper portion of the outer wall 46 depends from the top wall 20 to an annular, outer, upper joining surface 47 while the lower portion of the outer wall 46 extends upwardly to an annular, outer, lower joining surface 49. An upper portion of the ring belt 44 is shown as being formed in the upper portion of the outer wall 46 within the top part 18 of the piston 10 and a lower portion of the ring belt 44 is shown as being formed in the bottom portion of the outer wall 46 within the bottom part 16 of the piston 10. The ring belt 40 has a plurality of outer annular ring grooves 45 in which piston rings (not shown) are received in the usual manner. The ring grooves 45 shown include an uppermost ring groove adjacent the top wall 20 of the piston head region 14, wherein the uppermost ring groove can be formed entirely within the top part 18, between the top part 18 and the bottom part 16, or entirely within the bottom part 16, wherein the uppermost ring groove 45 is provided to receive a compression ring (not shown). In addition, a pair of lower ring grooves 45 below the uppermost ring groove 45 are shown, wherein the pair of lower ring grooves 45 are preferably formed in the bottom part 16, such as to receive an intermediate wiper ring and a lowermost oil ring (neither shown). Further yet, a bottom (fourth) annular groove or recess 45′ is formed below the lowermost oil ring groove 45, wherein the annular recess 45′ is formed “as cast” primarily as a weight reduction feature.
The head region 14 of the piston 10 further includes an annular bottom wall 48 that extends radially inwardly from the lower end of the ring belt 44 toward the central axis A. The bottom wall 48 is formed entirely from the material of the bottom part 16. The bottom wall 48 transitions radially inwardly over a transition region 51 into the floor 26 of the combustion bowl 22 radially inwardly of the side wall 38 of the combustion bowl 22.
The annular bottom wall 48 of the head region 14 is spaced in axial alignment along the central axis A from the top wall 20, and the outer wall 46 of the ring belt 44 is spaced radially outwardly from the inner combustion bowl side wall 38. As such, as shown in longitudinal cross-section, these walls 48, 20, 46, 38 form an annular, toroid-shaped box structure that bound a substantially enclosed, circumferentially continuous oil gallery 50 within the piston head region 14. An upper region of the oil gallery 50 is formed by the top part 18 of the piston 10 and a lower region of the oil gallery 50 is formed by the bottom part 16 of the piston 10. The bottom wall, also referred to as floor 48, of the oil gallery 50 is formed with at least one oil feed or inlet 52 that is open to the bottom of the piston 10 and is in direct fluid communication with the oil gallery 50 for introducing a flow of cooling oil from a supply source (not shown), such as from an oil jet during operation of the diesel engine in which the piston 10 is to be installed. If the bottom part 12 of the piston is fabricated by casting (e.g., investment cast), then the oil inlet 52 may be formed as a “cast-in” feature rather than being subsequently formed by a machining operation. The bottom wall 48 may also include at least one oil drain hole or outlet 54 that is open to the bottom of the piston 10 and is in open fluid communication with the oil gallery 50 for draining oil from the gallery 50 back into the crankcase of the engine during operation. The at least one oil drain hole 54 may likewise be a “cast-in” feature of the bottom piston part 16. While it is preferred to avoid secondary or downstream processes to form the inlet and outlet 48, 50 by casting them directly in the bottom part 16, they can also be machined or otherwise processed, if desired. In addition, the bottom wall 48 can be formed “as cast” to provide an annular undercut region to provide an annular reentrant portion 55 of the oil gallery 50 extending radially inwardly beneath at least a portion of the side wall 38 to maximize the cooling effect of the oil within the cooling gallery 50 on the combustion bowl 22.
The bottom part 16 further includes a pair of pin bosses 56 configured to depend from the top part 18. The pin bosses 56 each have a pin bore 58, preferably bushless given the steel construction, wherein the pin bores 58 are spaced from one another coaxially along a pin bore axis B that extends transverse to the central longitudinal axis A. The pin bores 58 each have an uppermost surface extending tangent with an uppermost tangent plane 57 and a lowermost surface extending tangent with a lowermost tangent plane 59, wherein the tangent planes 57, 59 extend parallel to one another and transverse to the central axis A. The pin bosses 56 are joined to skirt portions, also referred to as skirt panels 60, that are formed as a monolithic piece of material with the bottom part 16 and are thus, formed integrally as a monolithic piece of material with the pin bosses 56.
The skirt panels 60 are joined along their longitudinally extending sides 61 directly to the pin bosses 56 via windows, also referred to as strut portions 62, such that the skirts panels 60 are arranged diametrically opposite one another across opposite sides of the pin bosses 56. One or more of the strut portions 62 can be formed having an opening 63, wherein the openings 63 are shown as elongate, arcuate oval or generally peanut-shaped openings extending generally lengthwise along the central axis A. The openings 63 are preferably formed “as cast” with the bottom part 16, though they could be machined or processed subsequent to casting, if desired for additional weight reduction.
The skirt panels 60 have convex outer surfaces extending between their respective sides 61 across a central region 65, wherein the outer surfaces are contoured for smooth, mating cooperation with a wall of the cylinder bore to maintain the piston 10 in a desired orientation as it reciprocates through the cylinder bore. The skirt panels 60 are constructed having a thickness ranging between about 2.0% to 3.0% of the piston head outer diameter. As best shown in
The skirt panels 60 are each joined at their upper ends and formed as one piece (e.g., cast) with the lower portion of the ring belt 44, wherein the annular recess 45′ extends between the skirt upper ends and the lowermost ring groove 45. The skirt panels 60 extend longitudinally generally parallel with the central axis A downward from the ring belt 44 to bottom or lower ends 64 which are spaced below the lowermost tangent planes 59 of the pin bores 58. At least one of the pin bosses 56 is formed with a datum pad 66 that projects downwardly from the bottom of the pin boss 56 to provide a flat reference surface 68 used in manufacture. The reference surface 60 is co-planer with the lower ends 64 of the skirt panels 60.
A weld joint 70 that unites the separately made top and bottom parts 18, 16 of the piston 10 extends at least through the side wall 38 of the combustion bowl 22 upon welding the radially inner annular lower joining surface 41 of the bottom part 16 to the radially inner annular upper joining surface 43 of the top part 18. Thus, the weld joint 70 is open to the combustion bowl 22 above the valley 34 and below the center peak 32 and the rim 40 of the combustion bowl 22. The weld joint 70 is also spaced axially above the lowest portion of the oil gallery, formed by the lower wall 48, which itself is spaced below the valley 34 of the combustion bowl 22.
In addition to the weld joint 70 extending through the combustion bowl side wall 38, a weld joint 72 extends through at least one other wall in the head region 14. As illustrated, the weld joint 72 may extend through the outer ring belt 44 of the piston 10. The location of the ring belt weld joint 72 may be at any point along the length of the ring belt 44. As illustrated, the ring belt weld joint 72 may lie in the same plane extending transverse to the central axis A as that of the weld joint 70 in the combustion chamber side wall 38. The bottom part 16 of the piston 10 may thus include a radially outer, upwardly facing pre-joined lower joining surface 74 of the ring belt 44 and the top part 18 may thus include a radially outer, downwardly facing pre-joined upper joining surface 76 of the ring belt 40. The associated lower and upper joining surfaces 41, 43; 74, 76 may be united by a selected joining process, such as induction welding, friction welding, resistance welding, charge carrier rays, electron beam welding, brazing, soldering, hot or cold diffusion, etc.
The piston 10 is adapted for use in light, modern, high performance vehicle diesel engine applications with piston head outer diameter range from about 75 mm to 105 mm. While made of steel, the piston 10, by its thin-walled design, is as light, if not lighter, than its aluminum counterparts when taking into account the mass of the aluminum piston and the associated insert pin bore bushings, etc used in aluminum piston assemblies. The steel piston 10 also has a significantly smaller compression height CH, defined as the distance extending between the central pin bore axis B and the top wall 20, than its aluminum counterpart piston (i.e. 20-30% smaller). The comparable weight and smaller CH allows the engine to be made smaller and more compact, or for the connecting rod to be longer and have an enlarged small end, given the increased available space provided between the pin bore axis B and the underlying peak 36 of the combustion bowl wall 24, so as to reduce the side load on the piston during operation.
As mentioned, the steel piston 10 has a very short compression height CH. In comparison with prior art two-piece pistons having oil cooling galleries typical of heavy-duty diesel engine applications, it will be appreciated that the pin bosses 56, and thus their associated pin bores 58, are much higher up in the piston body 12 (the piston is more axially compact). The illustrated piston 10 has a compression height CH to piston head region outer diameter ratio of about 40.9%. Further, the distance from the pin bore axis B to the combustion bowl side wall weld joint 70 is about 27 mm. By comparison, an aluminum piston for a similar application would have about 20-30% greater CH to piston head region outer diameter ratio.
In
The piston 110 is similar to the piston 10 discussed above, having a bottom part 116 welded to a top part 118, however, the compression height CH is able to be further reduced due to a difference in the configuration of a bottom portion 50′ of an oil gallery formed between the bottom and top parts 116, 118. In particular, the configuration of the bottom portion 50′ of the oil gallery with in the bottom part 116 is altered, with the portion of the oil gallery in the top part 118 remaining the same. Rather than the oil gallery being formed having a symmetrically continuous annular configuration, the bottom portion 50′ of the oil gallery within the bottom part 116 is fabricated having an undulating floor 148 (
As shown in
The piston 210 is similar to the piston 10 discussed above, having a bottom part 216 welded to a top part 218, however, rather than having a combustion bowl configured concentrically about a longitudinal central axis A, a combustion bowl 222 is radially offset relative to a longitudinal central axis A of the piston 210 such that the combustion bowl 222 is non-concentric in relation to the longitudinal central axis A. As such, in order to provide uniform cooling to the radially offset combustion bowl 222, a cooling gallery 250 is altered in comparison with the cooling gallery 50 of the piston 10. The top part 218, as with the top part 18 of the piston 10, includes an upper portion of the cooling gallery 250 that is concentric about the longitudinal central axis A and annularly symmetric, however, the bottom part 216 includes a lower part of the cooling gallery 250 that is radially offset in non-concentric relation to the longitudinal central axis A and also annularly asymmetrical. The reason for the asymmetrical configuration is to reduce weight of the piston 210, and the reason for the non-concentric configuration is to provide a wall 224 of the combustion bowl 222 with a symmetrically uniform, constant circumferential thickness. As such, the cooling is made uniform about the combustion bowl 222.
In addition to the difference discussed with regard to the cooling gallery 250, as shown in
Obviously, many modifications and variations of the present invention are possible in light of the above teachings. It is, therefore, to be understood that within the scope of the appended claims, the invention may be practiced otherwise than as specifically described.
This application claims the benefit of U.S. provisional application Ser. No. 61/258,956, filed Nov. 6, 2009, which is incorporated herein by reference in its entirety.
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