The present invention relates to pistons for internal combustion engines.
In order to make engine powered vehicles more energy efficient, in addition to implementing various technologies that improve the energy consumption of the engine itself, vehicle and engine manufacturers also try to reduce the weight of the various components of the vehicle, including the engine.
Pistons are one of the most important components of reciprocating internal combustion engine. The pistons transfer the energy of the expanding combustion gases in the combustion chamber to the crankshaft of the engine, thereby causing the crankshaft to turn. However, the pistons also represent a significant amount of the reciprocating masses of the engine.
For this reason, in many engines, the steel from which the pistons were traditionally made has been replaced with aluminum. In addition to being lighter in weight, aluminum pistons are also less expensive and provide good heat conductivity characteristics.
One of the disadvantages of aluminum pistons is that they are less resistant to high temperatures than steel pistons. The overheating of a piston can lead to deformation and cracking of the crown of the piston and to ductile deformation of the pin bosses used to attach the piston to the connecting rod.
High temperatures of the pistons can be the result of many different factors. For example, high power output engines tend to be hotter. In order to achieve low emissions and low fuel consumptions, many engine manufacturers opt for a lean air-fuel mixture to be combusted in the combustion chambers, which results in higher temperature combustion engines. In carbureted two-stroke engines, a fuel mixed with air flows in the crankcase that can absorb some of the heat from the pistons. However, some two-stroke engines now employ direct fuel injection technology where the fuel is injected directly in the combustion chambers. As a result, there is no more fuel flowing in the crankcase that could absorb heat from the pistons, and therefore the pistons get hotter. As such, aluminum pistons may not be suitable in engines having one or more of the above-described characteristics.
Therefore, there is a need for a relatively lightweight piston having good heat resistance characteristics.
It is an object of the present invention to ameliorate at least some of the inconveniences present in the prior art.
In one aspect, the present invention provides a piston for an internal combustion engine having a crown having a crown outer side and a crown inner side and a skirt extending from the crown. The skirt has a skirt outer side and a skirt inner side. The skirt defines a reciprocation axis of the piston. First and second pin boss assemblies are connected to the crown inner side and the skirt inner side. The first and second pin boss assemblies define a pin bore axis perpendicular to the reciprocation axis. The first and second pin boss assemblies are adapted for receiving a piston pin having a piston pin axis with the piston pin axis being coaxial with the pin bore axis. The first and second piston boss assemblies are disposed on opposite sides of the reciprocation axis and are spaced apart in a direction defined by the pin bore axis. Each of the first and second pin boss assemblies has a pin boss, a rib, a central strut, and first and second diagonally extending struts. The pin boss defines a pin bore. The pin bore defines the pin bore axis. The rib extends from the crown inner side toward the pin boss. The rib is generally aligned with the pin boss in the direction defined by the pin bore axis. The rib extends along the crown inner side along a direction generally parallel to a lateral axis of the piston. The lateral axis of the piston intersects and is perpendicular to the reciprocation axis and the pin bore axis. The central strut extends from the pin boss to the crown inner side in a direction generally parallel to the reciprocation axis. The central strut is generally centered relative to the pin bore axis. The first diagonally extending strut has a first end connected to the pin boss and a second end connected to a junction of the crown inner side and the skirt inner side. The second diagonally extending strut has a first end connected to the pin boss and a second end connected to the junction of the crown inner side and the skirt inner side. The first and second struts are disposed on opposite sides of a plane containing the reciprocation axis and the pin bore axis.
In a further aspect, for each of the first and second pin boss assemblies, the central strut is connected to the rib.
In an additional aspect, for each of the first and second pin boss assemblies a dimension of at least a portion of the central strut in a direction defined by the lateral axis is less than 40 percent of a diameter of the pin bore.
In a further aspect, for each of the first and second pin boss assemblies: a dimension of a portion of the first strut in the direction defined by the pin bore axis is at least twice a dimension of the portion of the first strut in a direction perpendicular to the pin bore axis and to a central longitudinal axis of the first strut; and a dimension of a portion of the second strut in the direction defined by the pin bore axis is at least twice a dimension of the portion of the second strut in a direction perpendicular to the pin bore axis and to a central longitudinal axis of the second strut,
In an additional aspect, for each of the first and second pin boss assemblies a dimension of the second strut in the direction defined by the pin bore axis is at least 20 percent greater at the second end of the second strut than at the first end of the second strut.
In a further aspect, each of the first and second pin boss assemblies also has: a third diagonally extending strut having a first end connected to the pin boss and a second end connected to the skirt inner side, the second end of the third strut being further from the crown than the first end of the third strut, the third strut being disposed on a same side of the plane as the first strut; and a fourth diagonally extending strut having a first end connected to the pin boss and a second end connected to the skirt inner side, the second end of the fourth strut being further from the crown than the first end of the fourth strut, the fourth strut being disposed on a same side of the plane as the second strut.
In an additional aspect, for each of the first and second pin boss assemblies: a dimension of a portion of the third strut in the direction defined by the pin bore axis is between 50 and 70 percent of a dimension of a portion of the first strut in the direction defined by the pin bore axis; and a dimension of a portion of the fourth strut in the direction defined by the pin bore axis is between 50 and 70 percent of a dimension of a portion of the second strut in the direction defined by the pin bore axis.
In a further aspect, for each of the first and second pin boss assemblies: the plane is a first plane; the second end of the third strut is further from a second plane than the first end of the third strut; the second plane contains the reciprocation axis and the lateral axis; and the second end of the fourth strut is further from the second plane than the first end of the fourth strut.
In an additional aspect, a ring is connected to the skirt inner side. For each of the first and second pin boss assemblies: the pin boss is disposed between the ring and the crown in a direction defined by the reciprocation axis; and the second ends of the third and fourth struts are connected to the ring.
In a further aspect, a ring is connected to the skirt inner side. For each of the first and second pin boss assemblies: the pin boss is disposed between the ring and the crown in a direction defined by the reciprocation axis.
In an additional aspect, the plane is a first plane. A second plane contains the reciprocation axis and the lateral axis. The skirt defines a first arch and a second arch at a free end thereof. The first and second arches are disposed on opposite sides of the second plane.
In a further aspect, the crown defines a piston ring groove on an outer circumference thereof.
In an additional aspect, the plane is a first plane. A second plane contains the reciprocation axis and the lateral axis. The piston is asymmetrical about the first plane. The piston is symmetrical about the second plane.
In a further aspect, the crown, the skirt and the first and second pin boss assemblies are made of steel.
In an additional aspect, the crown, the skirt and the first and second pin boss assemblies are integrally formed via a casting process.
In another aspect, the present invention provides an internal combustion engine having a cylinder, a piston according to one or more of the above aspects disposed in the cylinder, a piston pin received in the piston bores of the piston, a connecting rod having a first end connected to the piston pin and a second end, and a crankshaft connected to the second end of the connecting rod.
In a further aspect, the engine is a direct fuel injection two-stroke engine.
Embodiments of the present invention each have at least one of the above-mentioned object and/or aspects, but do not necessarily have all of them. It should be understood that some aspects of the present invention that have resulted from attempting to attain the above-mentioned object may not satisfy this object and/or may satisfy other objects not specifically recited herein.
Additional and/or alternative features, aspects, and advantages of embodiments of the present invention will become apparent from the following description, the accompanying drawings, and the appended claims.
For a better understanding of the present invention, as well as other aspects and further features thereof, reference is made to the following description which is to be used in conjunction with the accompanying drawings, where:
A direct injection, two-stroke engine 10 having a high pressure fuel pump 12 will be described. However, it is contemplated that the embodiments of pistons described below could also be used in other types of engines, such as, but not limited to, carbureted or semi-direct injection engines and/or engines using low pressure fuel pumps.
As seen in
Turning now to
As the piston 24 reciprocates in the cylinder 22, it opens and closes an intake port 56, an exhaust port 58, and a pair of auxiliary exhaust ports 60 (only one of which is shown) as is typical of two-stroke engines. It is contemplated that the auxiliary exhaust ports 60 could be omitted. The intake port 56, the exhaust port 58 and the auxiliary exhaust ports 60 are formed by the cylinder block 16. The cylinder block 16 also defines a passage 62 to receive an exhaust valve assembly (not shown) used to change the surface areas of the exhaust port 60 and of the auxiliary exhaust ports 62 depending on the operating conditions of the engine 10. It is contemplated that the exhaust valve assembly, and therefore its associated passage 62 could be omitted. A piston ring 64 arranged around the piston 24, as will be described in greater detail below, helps prevent gases present in the combustion chamber from entering the chamber defined by the crankcase 14.
Turning now to
The piston 24 has a crown 66 and a generally cylindrical skirt 68 extending therefrom. A central axis of the skirt 68 defines a reciprocation axis 70 of the piston 24. As the name suggests, the reciprocation axis 70 is the axis along which the piston 24 reciprocates in the cylinder 22 and is coaxial with a central axis of the cylinder 22 (not shown). The reciprocation axis 70 intersects and is perpendicular to the pin bore axis 52. For purposes of the present application, the axis of the piston 24 that intersects and is perpendicular to both the pin bore axis 52 and the reciprocation axis 70 will be referred to herein as the lateral axis 72. It should be understood that the lateral axis 72 is used herein to indicate that the axis 72 extends laterally relative to the pin bore axis 52 which is considered to be the longitudinal axis of the piston 24. It should be understood that the terms lateral and longitudinal with respect to the axes 52 and 72 are use relative to the piston 24 and are not indicative of the position of these axes 52 and 72 relative to an engine having the pistons 24 and/or to a vehicle having an engine having the pistons 24, although they may correspond under some circumstances. A plane containing the reciprocation axis 70 and the pin bore axis 52 will be referred to herein as the longitudinal plane 74 of the piston 24. A plane containing the reciprocation axis 70 and the lateral axis 72 will be referred to herein as the lateral plane 76 of the piston 24. The portion of the piston 24 disposed between the longitudinal plane 74 and the intake port 56 will be referred to herein as the intake side of the piston 24 (i.e. the portion of the piston 24 to the right of axis 70 and plane 74 in
The crown 66 has a crown outer side 78 and a crown inner side 80. As can be seen in
The skirt 68 defines the above-mentioned windows 54. As can be seen in
As best seen in
The windows 54 and the arches 88 help reduce the weight of the piston 24, but it is contemplated that they could be omitted.
The skirt 68 has a skirt outer side 94 and a skirt inner side 96. An inwardly projecting ring 98 is connected to the skirt inner side 96. The ring 98 is disposed between the windows 54 and the arches 88 in the direction defined by the reciprocation axis 70. The pin bosses 42 are disposed between the ring 98 and the crown 66 in the direction defined by the reciprocation axis 70. Crescent shaped walls 99 are connected to the ring 98 on both sides of the lateral plane 76. The ring 98 and walls 99 provide additional strength to the skirt 68 and also provide elements that can be used to attach the piston 24 to machine features of the piston 24. It is contemplated that the walls 99 and/or the ring 98 could be omitted.
The piston 24 also has a pair of pin boss assemblies 100. Each pin boss assembly 100 includes one of the above-mentioned pin bosses 42, its associated pin bore 44, and other elements described in greater detail below. The pin boss assemblies 100 are disposed on opposite sides of the lateral plane 76 and are spaced apart in the direction defined by the pin bore axis 52. The pin boss assemblies 100 are connected to the crown inner side 80 and the skirt inner side 96 as will be described below.
The crown 66, the skirt 68, the ring 98 and the pin boss assemblies 100 are integrally formed by a metal casting process. In one embodiment, the piston 24 is made by investment casting, also known as lost wax casting. It is contemplated that other casting processes could be used. The piston 24 is made of high grade steel. In one embodiment, the steel used is a high-tensile strength, quenched and tempered alloyed steel, such as, for example, 42CrMo4 high grade steel having a tensile strength of about 1100 N/mm2. Depending on the operating conditions of the piston 24, it is contemplated that other types of steel could be used.
Turning now to
In addition to the pin boss 42, the pin boss assembly 100 has a rib 102, a central strut 104, an intake side strut 106 and an exhaust side strut 108. The rib 102 is connected to the crown inner side 80 and extends toward the pin boss 42. The rib 102 extends from the skirt inner side 96 on the intake side of the piston 24 to the skirt inner side of the piston 24 on the exhaust side of the piston 24 in a direction generally parallel to the lateral axis 72. As can be seen in
The central strut 104 extends between the pin boss 42 and the crown inner side 80 in the direction defined by the reciprocation axis 70, thereby connecting the pin boss to the crown inner side 80. The central strut 104 is centered relative to the pin boss axis 52. The central strut 104 is also connected to the rib 102. The dimension D1 of the central portion of the central strut 104 in the direction defined by the lateral axis 72 is less than 40 percent of the diameter of the pin bore 44.
The intake side strut 106 has one end connected to a side of the pin boss 42 and extends diagonally therefrom such that its other end is connected to a junction of the crown inner side 80 and the skirt inner side 96 on the intake side of the piston 24. The intake side strut 106 is generally parallel to the plane 76. The dimension D2 (
The exhaust side strut 108 is disposed on the side of the plane 74 opposite the one where the intake side strut 106 is located. The exhaust side strut 108 has one end connected to a side of the pin boss 42 and extends diagonally therefrom such that its other end is connected to a junction of the crown inner side 80 and the skirt inner side 96 on the exhaust side of the piston 24. The exhaust side strut 108 is generally parallel to the plane 76. The dimension D4 (
Two ribs 114 are connected to the crown inner side 80 and extend toward the pin boss 42. The ribs 114 are disposed on both sides of the plane 74 and extend from one rib 102 to the other rib 102. Two other ribs 116 are connected to the crown inner side 80 and extend toward the pin boss 42. The plane 74 passes through the ribs 116. Each rib 116 extends from one of the ribs 102 to the skirt inner side 96.
Turning now to
The pin boss assembly 202 consists of all of the same elements as the boss assembly 100 described above with the addition of a lower intake side strut 204 and a lower exhaust side strut 206. The elements of the pin boss assembly 202 that are the same as those of the pin boss assembly 100 will not be described again.
The lower intake side strut 204 is disposed on the same side of the plane 74 as the intake side strut 106. The lower intake side strut 204 has one end connected to a side of the pin boss 42 and extends diagonally therefrom away from the crown 66 and the plane 76 such that its other end is connected to the ring 98 on the intake side of the piston 24. It is contemplated that the lower intake side strut 204 could alternatively be connected directly to the skirt inner side 96. The dimension D8 (
The lower exhaust side strut 206 is disposed on the same side of the plane 74 as the exhaust side strut 108. The lower exhaust side strut 206 has one end connected to a side of the pin boss 42 and extends diagonally therefrom away from the crown 66 and the plane 76 such that its other end is connected to the ring 98 on the exhaust side of the piston 24. It is contemplated that the lower exhaust side strut 206 could alternatively be connected directly to the skirt inner side 96. The dimension D9 (
Modifications and improvements to the above-described embodiments of the present invention may become apparent to those skilled in the art. The foregoing description is intended to be exemplary rather than limiting. The scope of the present invention is therefore intended to be limited solely by the scope of the appended claims.
The present application claims priority to U.S. Provisional Patent Application No. 61/591,427, filed Jan. 27, 2012, the entirety of which is incorporated herein by reference.
Number | Name | Date | Kind |
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1526491 | Cox | Feb 1925 | A |
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2217542 | Flammang et al. | Oct 1940 | A |
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5063893 | Iwaya | Nov 1991 | A |
5150517 | Leites et al. | Sep 1992 | A |
20100147250 | Boczek et al. | Jun 2010 | A1 |
Number | Date | Country |
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505592 | Feb 2009 | AT |
450700 | Jun 1943 | BE |
4016507 | Nov 1990 | DE |
2295777 | Mar 2011 | EP |
417007 | Sep 1934 | GB |
2005002861 | Jan 2005 | JP |
Entry |
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European Search Report of European Application No. 13152720.2, Munich Jun. 21, 2013; Dragos Luta. |
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Number | Date | Country | |
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20130192556 A1 | Aug 2013 | US |
Number | Date | Country | |
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61591427 | Jan 2012 | US |